CN101176254A - Frequency controller for a monolithic clock generator and timing/frequency refrence - Google Patents

Frequency controller for a monolithic clock generator and timing/frequency refrence Download PDF

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Publication number
CN101176254A
CN101176254A CNA2006800170063A CN200680017006A CN101176254A CN 101176254 A CN101176254 A CN 101176254A CN A2006800170063 A CNA2006800170063 A CN A2006800170063A CN 200680017006 A CN200680017006 A CN 200680017006A CN 101176254 A CN101176254 A CN 101176254A
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China
Prior art keywords
frequency
circuit
control
oscillator
coefficient
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CNA2006800170063A
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Chinese (zh)
Inventor
M·S·麦科克代尔
S·M·佩尼亚
S·库贝
J·奥戴
G·卡里切纳
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Mobius Microsystems Inc
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Mobius Microsystems Inc
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Priority claimed from US11/084,962 external-priority patent/US7227423B2/en
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Publication of CN101176254A publication Critical patent/CN101176254A/en
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Abstract

Exemplary embodiments of the invention provide a clock generation apparatus, system, and method, which include power management. The apparatus is couplable to second circuitry which has a clock input terminal and an inverted clock output terminal. An exemplary apparatus comprises a clock generator, a sensor, and a processor. The clock generator provides a clock signal on a first terminal which is couplable to the clock input terminal of the second circuitry. The sensor is coupled to a second terminal which is couplable to the inverted clock output terminal, and detects a power conservation mode and a power resumption mode of the second circuitry. The processor is adapted to reduce power to the clock generator and to provide a first predetermined voltage or a second predetermined voltage to the first and second terminals in response to the detection of the power conservation mode, and to increase power to the clock generator in response to the detection of the power resumption mode.

Description

Discrete clock generator and/or timing/frequency reference
Technical field
Present invention relates in general to vibration or clock control signal and take place, particularly discrete clock-signal generator and timing/frequency reference, its self-excitation, self-reference, accurate and have a low jitter with manufacturing process, voltage and temperature maintenance.
Background technology
Clock generator or timing reference rely on crystal oscillator usually accurately, and as quartz (controlled) oscillator, it provides the mechanical resonant of characteristic frequency.The difficulty of such crystal oscillator is that they can not be manufactured to the part of the same integrated circuit (IC) that will be driven by its clock signal.For example, microprocessor such as Intel Pentium processor require clock IC separately.For this reason, in fact each needs the circuit of accurate clock signal all to need sheet external clock generator.
For so non-integrated solution several results are arranged.For example, connect because described processor must pass through external circuit (as the circuit on the printed circuit board (PCB) (PCB)), power dissipation increases relatively.In relying on power-limited application, as relying on the mobile communication of battery electric power, described extra power dissipation is very harmful.
In addition, non-integrated solution has increased space and area needs because of the extra IC of needs, no matter is on the PCB or has finished in the product, and this also is harmful in mobile environment.In addition, so other assembly has also increased manufacturing and production cost, because other IC must be manufactured and be assembled together with main circuit (as microprocessor).
Be manufactured to that to be integrated in other clock generator of circuit of one enough accurate usually with other circuit, it changes with manufacturing process, voltage and temperature (PVT).For example, annular, tension and relaxation and phaseshift oscillator can provide and be suitable for the clock signal that some low sensitivities are used, but the more needed more high accuracy of complex electronic circuit can not be provided, as the needed accuracy of application of powerful disposal ability of needs or data communication.In addition, these clock generators or oscillator represent suitable frequency displacement usually, shake, have low relatively Q value and distorted by other because of noise and other interference.
For this reason, need to integrate and to change with other circuit such as single IC monolithic ground the clock generator or the timing reference of maintenance pin-point accuracy with PVT.Such clock generator or timing reference are answered self-excitation and self-reference, and not in requisition for locking or with reference to another reference signal.Such clock generator or timing reference should represent minimum frequency displacement and have low relatively shake, and should be suitable for the application of the system clock of requirement pin-point accuracy.Such clock generator or timing reference should also provide plurality of operating modes, comprise clock module, reference model, energy preservation mode and are subjected to the impulse action pattern.At last, such clock generator or timing reference should be able to be controlled output frequency, to provide stable and frequencies that need in response to the variation of environment or junction temperature or other parameter such as the variation of voltage, manufacturing process, frequency and operating period.
Summary of the invention
In different exemplary embodiments, the invention provides the device that produces frequency reference signal.Described device comprises resonator, and it can use one or more inductors and capacitor (as the LC accumulator); Trsanscondutance amplifier; Be used for to low jitter, self-excitation and self-reference clock generator and/or regularly and frequency reference open loop frequency control and frequency controller and the temperature compensator selected are provided, it changes with PVT and operating period (time) and keeps pin-point accuracy and its to integrate with the formation single IC for both with other circuit monolithic ground.Do not need independent reference oscillator, and exemplary embodiment is not locked onto any other frequency reference by phase locking, delay lock or other.But exemplary embodiment can be used as described reference oscillator, and it produces frequency reference signal, and one or more then phase lockings or delay locked loop lock onto described frequency reference signal.Different exemplary embodiment of the present invention comprises the feature that changes the frequency that produces pin-point accuracy with manufacturing process, voltage and temperature (PVT).These features comprise frequency tuning and selection, compensation because the frequency change that temperature and/or voltage fluctuation cause, manufacturing process variations, and because the variation that aging of integrated circuit causes.
The present invention can be provided as providing the discrete IC of clock signal or other frequency reference signal, and it can be the Any user application and combines with other integrated circuit afterwards.Apparatus of the present invention can be configured or programme to carry out frequency selection, signal selection, I/O (I/O) selection, the selection of I/O pin, spread-spectrum selection, to reach other selection.Provide several method to carry out such configuration and programming, comprise that mask programmability, the IC during IC designs and makes makes back manufacturer or retail trader's programmability, reach IC manufacturing back user-programmable.
The present invention also can combine with other integrated circuit to constitute single component, is provided at usually in the single IC shell.For example, for any function or use as different processor, controller, digital signal processor etc., clock generator of the present invention and/or regularly and frequency reference can with any other, the second circuit of any kind of or type combines, think that second circuit provides integrated, free running clock, described second circuit does not need synchronously or locks onto external reference such as crystal oscillator.
For example but not as restriction, clock generator and/or regularly and frequency reference can combine with the processor of any following type: microprocessor, digital signal processor, controller, microcontroller, USB (USB) controller, periphery component interconnection (PCI) controller, periphery component interconnection is (PCI-e) controller fast, the live wire controller, AT annex (ATA) interface controller, integrated driving electronics (IDE) controller, the SCS(Small Computer System Interface) controller, control device of the tv, the Local Area Network controller, ethernet controller, Video Controller, Audio Controller, modem processor, the MPEG controller, multimedia controller, communication controler, the mobile communication controller, IEEE 802.11 controllers, the GSM controller, the GPRS controller, the PCS controller, the AMPS controller, the CDMA controller, the WCDMA controller, the spread-spectrum controller, the WLAN controller, IEEE 802.11 controllers, the DSL controller, t1 controller, the ISDN controller, or cable modem controller.Be used for clock generator of the present invention and/or regularly and the second circuit of integrated countless other types of frequency reference also within the scope of the present invention.
For described exemplary embodiment, clock generator and/or timing and frequency reference provide has first frequency f 0First reference signal.Any way of first reference signal in can be in many ways uses, as: (1) by second circuit directly as clock control or frequency reference signal; (2) offer one or more square-wave generators or frequency dividing circuit, the signal behind gained essence square wave or the frequency division is provided as output (as (as having frequency f at institute's selected frequency 0, f 1, f 2... f K) one or more second reference signals, after wherein arbitrary or a plurality of by second circuit as clock control or frequency reference signal); (3) be used for the locking of lock-in circuit,, or, also (as have frequency f at institute's selected frequency one or more by being used in combination of frequency division and lock-in circuit as one or more phase-locked loops, delay lock loop or injection locking circuit K+1, f K+2... f N) second reference signal offer second circuit as output.
These one or more second reference signals can be converted, multiplexed or directly offer any second circuit, as processor, memory and input/output interface, it is as the clock or the reference signal of institute's selected frequency.Any form of these signals in also can be in a variety of forms provides, and as single-ended, difference, phase shift, quadrature, comprises anti-phase and/or the positive form.
According to selected embodiment, for any frequency (f 0, f 1, f 2... f N) frequency select and can provide in many ways.Frequency selects to can be used as design and the part made occurs, as by selecting clock generator and/or regularly and the inductor that uses in the IC oscillator of frequency reference and the quantity and the size of capacitor.For example, the size of one or more inductors and/or shape can be selected by the shielding of proper metal layer, and capacitor can be adjusted to the size that produces characteristic frequency or frequency range.Frequency is selected also can take place after manufacturing, and it is by using difference calibration and control coefrficient or the signal that describes in detail below.In addition, frequency is selected to pass through the one or more lock-in circuits of configuration and is carried out, and as passing through to select to pass through the frequency dividing ratio of the programmable counter in the phase-locked loop, this can be the part of design and the manufacturing of IC; Or can after manufacturing, programme, equally by using calibration and control coefrficient or signal or being undertaken by frequency divider being converted into or changing out division chain.Other collocation method will describe in detail below.
Additional embodiments also produces a plurality of frequency reference signals, no matter is sine or square-wave signal, as being used as one or more clock signals or reference frequency source.In the exemplary embodiment, clock/frequency reference of the present invention is connected to one or more phase-locked loops (PLL) or delay lock loop (DLL), corresponding a plurality of output reference signals of selected frequency to provide.Different exemplary embodiments can be configured or programmes by control signal or the coefficient of being preserved, as select to regulate the frequency dividing ratio of PLL or DLL for correspondent frequency.
For the application that may require high Q value, low jitter and low phase noise, resonator generally includes one or more inductors and capacitor, thereby forms one or more LC accumulators or LC resonator.In first embodiment, use two balanced differential LC resonator layouts.In other exemplary embodiment, difference or single-ended LC oscillator layout be can use, Bi Zi (Colpitts) LC oscillator (cobasis reaches and collects version altogether), difference Hartley LC oscillator (cobasis reaches and collects version altogether), single-ended Pierre Si (Pierce) LC oscillator, quadrature oscillator (as forming) examined by at least two two balances, difference LC oscillators as the cross-coupled layout of difference n-MOS, the cross-coupled layout of difference p-MOS, the single-ended Bi Zi of examining LC oscillator, single-ended Hartley (Hartley) LC oscillator, difference.In any embodiment of these embodiment, active inductor can be used in LC oscillator or other reactance component.Any layout in these LC layouts can be embodied as balance, interconnection, difference or single-ended layout, and can use the transistor of any kind, as n-MOS, p-MOS or BJT.Other LC oscillator layout no matter be now known or be about to know, all is considered as equivalent arrangements and within the scope of the present invention.
Exemplary embodiment of the present invention also provide several in various degree with the control of type.For example, providing disperses controls in real time with continuous, thereby controls the output frequency of self-excited oscillator according to described variation.In addition, described control is provided as open loop usually, and does not need the feedback connection and do not need to make oscillator to lock another reference signal continuously.
In addition, exemplary embodiment of the present invention provides clock generator with plurality of operating modes and/or regularly and frequency reference, comprises as energy preservation mode, clock module, reference model and is subjected to the impulse action pattern.In addition, different embodiment provide the output signal of a plurality of different frequencies, and low latency and glitch-free conversion are provided between these different signals.
Be worth gazing at ground, different embodiments of the invention produce bigger and quite high frequency, and as hundreds of MHz and GHz scope, afterwards, it is divided into a plurality of lower frequencies.The N (rational, ratio of integers) that removes that each is such causes effective noise reduction, and phase noise reduces N and phase noise power reduces N 2Therefore, different exemplary embodiment of the present invention is compared other and directly or by the oscillator that frequency multiplication produces output is caused much lower relative phase shake.
Different device embodiment comprises resonator, amplifier, reaches frequency controller, and it can comprise different assemblies or module such as temperature compensator, process variation compensator, voltage isolator and/or voltage compensator, operating period (time) variation compensator, frequency divider, reach frequency-selector.Resonator provides first signal with resonance frequency.Temperature compensator is in response to the adjustment resonance frequency, and process variation compensator is regulated resonance frequency in response to manufacturing process variations.In addition, different embodiment can comprise that also first signal that will have resonance frequency is divided into a plurality of frequency dividers with secondary signal of corresponding a plurality of frequencies, and described corresponding a plurality of frequencies are equal to or less than described resonance frequency in fact; And frequency-selector provides output signal from a plurality of secondary signals.Frequency-selector also can comprise discriminator.Output signal can be provided as any form in the various ways, as differential or single-ended, and square wave or sine.
That exemplary embodiment of the present invention is provided for is integrated, the device of the FREQUENCY CONTROL of self-excitation harmonic oscillator, comprises the resonator that is suitable for providing first signal with resonance frequency; Be suitable for providing as control voltage the transducer of secondary signal in response at least one parameter in a plurality of parameters; And being connected to transducer and the frequency controller that can be connected to resonator, frequency controller is suitable for being connected to the reactance component of resonator to revise resonance frequency in response to the secondary signal modification.A plurality of parameters are variable and comprise one of following at least parameter: temperature, manufacturing process, voltage, frequency and operating period (promptly having used the time).
In the exemplary embodiment, frequency controller also is suitable for revising effective reactance or the impedance component that is connected to resonator in response to secondary signal, as the total capacitance of revising resonator in response to secondary signal, will fix or variable capacitance is connected to resonator or disconnect with resonator is connected, by the change varactor or it is transformed into selected control voltage revises the effective reactance of resonator or considerably, revise the inductance or the resistance of resonator in response to secondary signal, as by fixing or variable inductance or resistance is connected to resonator or disconnect with resonator and to be connected.In other embodiments, the reactance of difference weighting or size such as variable capacitor (varactor) can its with resonator between conversion, control between the voltage in itself and a plurality of different selecting and to change or the two exists simultaneously.For example, in selected embodiment, the reactance that is connected to one or more variable capacitors of resonator can change by the selected control voltage that one or more variable capacitors is transformed in a plurality of control voltages, thereby causes the effective reactance of difference or difference weighting to be connected to resonator.
For example, a plurality of fixed capacities (capacity with different, binary weighting or difference weighting) can be connected to resonator so that the FREQUENCY CONTROL of discrete stages to be provided, the varactor that is connected to resonator can be provided to the selected control voltage in a plurality of control voltages, it changes in response to temperature, it can be used for, and holding frequency is constant with described temperature fluctuation, and it provides the FREQUENCY CONTROL of continuous level.In addition, any voltage in the described control voltage or in response to selected parameter such as variations in temperature, or be constant with respect to described parameter.The different weights of employed different reactance can embody in a variety of forms, and as binary weighting, linear weighted function or use the weighting of the scheme of any other hope, all these all are regarded as being equal to fully and within the scope of the invention.
It should be noted that term " fixing " reaches " variable " and uses by mode well known in the art, " fixing " be interpreted as that " variable " means configuration and change with selected parameter usually with respect to the not variation usually of selected parameter configuration.For example, fixed capacitor means its electric capacity usually not with applying change in voltage, and variable capacitor (varactor) will have the electric capacity that becomes with applying voltage.Yet the two all can have and will have the electric capacity that becomes with manufacturing process usually.In addition, for example, fixed capacitor can be formed the varactor that is connected to fixed voltage.Similarly, assembly can directly or indirectly connect mutually, in other words, connects in the operation or connects through the signal transmission.For example, an assembly can be connected to second assembly through the 3rd assembly, as passing through conversion layout, divider, multiplier etc.Those skilled in the art will be familiar with these different situations and environment, reach as shown in the figure as described below, and the implication when using such term.
In the exemplary embodiment, frequency controller also can comprise: the coefficient register that is suitable for preserving more than first coefficient; And have and a plurality ofly be connected to coefficient register and can be connected to first arrays of the switchable capacitive module of resonator, each switchable capacitive module has fixed capacity and variable capacitance, and each switchable capacitive module is transformed into control voltage in response to the coefficient of correspondence in more than first coefficient with conversion between fixed capacity and variable capacitance and with each variable capacitance.A plurality of switchable capacitive module can be by binary weighting.Frequency controller also can comprise having a plurality of switchable resistive module that are connected to coefficient register and second array that also has capacitive module, capacitive module and a plurality of switchable resistive module are also connected to node so that control voltage to be provided, each switchable resistive module in response to the coefficient of correspondence in more than second coefficient of preserving in the coefficient register switchable resistive module is transformed into the control voltage node.In selected embodiment, transducer also comprises the current source in response to temperature, and wherein current source is connected to second array is striden at least one switchable resistive module in a plurality of switchable resistive module with generation control voltage by current mirror.Equally, in selected embodiment, current source has one of the following at least: in contrast to absolute temperature (CTAT) structure, be proportional to absolute temperature (PTAT) structure, be proportional to square (PTAT of absolute temperature 2) combination of structure or these structures.In addition, each switchable resistive module in a plurality of switchable resistive module has different temperature responses to selected electric current.
In other exemplary embodiment, transducer is parameter (temperature, technology, voltage, operating period etc.) transducer and changes secondary signal in response to the variation of selected parameter, for example, transducer can be temperature or voltage sensor and change secondary signal in response to temperature or change in voltage.Selected embodiment also can comprise the analog to digital converter that is connected to transducer providing digital output signal in response to secondary signal, and the control logic piece that digital output signal is converted to more than first coefficient.
In other exemplary embodiment, frequency controller also comprises process variation compensator, and it can be connected to resonator and be suitable for revising resonance frequency in response to the fabrication process parameters in a plurality of parameters.Process variation compensator also can comprise the coefficient register that is suitable for preserving a plurality of coefficients; And have a plurality of binary weighting of coefficient register resonator, arrays of switchable capacitive module of being connected to, each switchable capacitive module has first fixed capacity and second fixed capacity, each switchable capacitive module in response to the coefficient of correspondence in a plurality of coefficients between first fixed capacity and second fixed capacity, to change.In other exemplary embodiment, process variation compensator also can comprise the coefficient register that is suitable for preserving a plurality of coefficients; And have a plurality of arrays that are connected to the switchable variable capacitive module of coefficient register resonator, each switchable variable capacitive module changing, as is transformed into selected control voltage in response to the coefficient of correspondence in a plurality of coefficients between first voltage and second voltage.
In other exemplary embodiment, frequency controller also comprises the coefficient register that is suitable for preserving more than first coefficient; And have a plurality of first arrays that are connected to convertible, the capacitive module of coefficient register and resonator, each switchable capacitive module has variable capacitance, each switchable capacitive module in response to the coefficient of correspondence in more than first coefficient variable capacitance is transformed into the selected control voltage in a plurality of control voltages.In other exemplary embodiment, process variation compensator also can comprise the coefficient register that is suitable for preserving at least one coefficient; And being connected at least one switchable variable capacitive module of coefficient register resonator, it is transformed into selected control voltage in response at least one coefficient.Transducer can comprise the current source in response to temperature, frequency controller also can comprise having a plurality of second arrays that are connected to the resistive module of current source by current mirror, a plurality of resistive module are suitable for other a plurality of control voltages, and each resistive module in wherein a plurality of resistive module has different responses to temperature and the electric current that is suitable in response to current source provides the voltage of the correspondence control in a plurality of control voltages.
In other exemplary embodiment, the device that is used for the FREQUENCY CONTROL of resonator also can be suitable for preserving the coefficient register of more than first coefficient; And have and a plurality ofly be connected to the switchable reactance of coefficient register resonator or first array of impedance module, thereby each switchable reactance module is revised resonance frequency in response to the coefficient of correspondence in more than first coefficient to change corresponding reactance.Corresponding reactance or impedance can be fixing or variable inductance, fixing or variable capacitance, fixing or variable resistor or its any combination.Corresponding reactance can be switched to resonator, maybe can be switched to control voltage, supply voltage or ground potential when being connected to resonator, and control voltage can be determined in response to temperature by current source.For example, Dui Ying reactance is variable and is connected to resonator and the selected control voltage that is transformed in a plurality of control voltages.In selected embodiment, more than first coefficient calculated in response at least one parameter in a plurality of variable elements by transducer or determines described parameter such as temperature, manufacturing process, voltage, frequency and operating period.
In other exemplary embodiment, the device that is used for the FREQUENCY CONTROL of integrated, self-excitation harmonic oscillator comprises: a plurality of resistive module that are suitable for producing a plurality of control voltages; Be connected to a plurality of controlled reactance modules of harmonic oscillator; And being connected to a plurality of switches of a plurality of resistive module and a plurality of controlled reactance modules, a plurality of switching responses are connected to first controlled reactance modules in a plurality of controlled reactance modules to revise the resonance frequency of harmonic oscillator in control signal with the first control voltage of a plurality of control voltages.
As mentioned above, described device also can comprise the current source that is connected to a plurality of resistive module, current source is suitable for the electric current fixed with parameter offered at least one resistive module in a plurality of resistive module to produce at least one control voltage in a plurality of control voltages, and it is decided with parameter.In other embodiments, current source is suitable for and will offers at least one resistive module in a plurality of resistive module to produce at least one control voltage in a plurality of control voltages with the irrelevant electric current of parameter in fact, and it is irrelevant with parameter in fact.According to exemplary embodiment, each switchable resistive module in a plurality of switchable resistive module can have different temperature responses to selected electric current.
Therefore, when parameter was temperature, at least one control voltage in a plurality of control voltages was decided with temperature, and at least one control voltage in a plurality of control voltage is temperature independent in fact.
Exemplary device also can comprise the coefficient register that is connected to a plurality of switches and is suitable for preserving more than first coefficient, and wherein control signal is provided by at least one coefficient in more than first coefficient.A plurality of controlled reactance modules also can comprise the fixed capacity and the variable capacitance of a plurality of difference (as binary system) weighting, and wherein a plurality of switching responses are connected to fixed capacity harmonic oscillator and the control of first in a plurality of control voltages voltage is connected to the variable capacitance that is connected with harmonic oscillator in more than first coefficient.A plurality of resistive module also can comprise a plurality of switchable resistive module and the capacitive module that is connected to coefficient register, capacitive module and a plurality of switchable resistive module are also connected to node so that the first control voltage to be provided, and each switchable resistive module is transformed into the control voltage node in response to the coefficient of correspondence in more than second coefficient of preserving in the coefficient register with switchable resistive module.
In the exemplary embodiment, analog to digital converter can be connected to a plurality of switchable resistive module and provide digital output signal to control voltage in response to first, thereby for example will be converted to number format by fixed electric current (as transducer) with temperature; Reach the control logic piece that digital output signal is converted to more than first coefficient or control signal.
Equally, in the exemplary embodiment, a plurality of controlled reactance modules also comprise: a plurality of switchable capacitive module that are connected to coefficient register and harmonic oscillator, each switchable capacitive module has variable capacitance, and each switchable capacitive module is transformed into selected control voltage in a plurality of control voltages in response to the coefficient of correspondence in more than first coefficient with variable capacitance.According to embodiment, be connected to a plurality of resistive module by current mirror in response to the current source of the parameter in a plurality of variable elements; Each resistive module in wherein a plurality of resistive module has different responses to parameter and is suitable for providing the voltage of the correspondence control in a plurality of control voltages in response to the electric current of current source.According to embodiment, at least one control voltage in a plurality of control voltages is decided with parameter in fact, and at least one control voltage in a plurality of control voltages is irrelevant with parameter in fact.
Equally, in the exemplary embodiment, a plurality of controlled reactance modules also comprise: the switchable capacitive module that is connected to a plurality of difference weightings of coefficient register and harmonic oscillator, each switchable capacitive module has first fixed capacity and second fixed capacity, and each switchable capacitive module is changed between first fixed capacity and second fixed capacity in response to the coefficient of correspondence in a plurality of coefficients.In other embodiments, a plurality of controlled reactance modules also comprise: be connected to a plurality of switchable variable capacitive module of coefficient register and harmonic oscillator, each switchable variable capacitive module is changed between first voltage in a plurality of control voltages and second voltage in response to the coefficient of correspondence in a plurality of coefficients.In other embodiments, a plurality of controlled reactance modules also comprise: a plurality of switchable variable capacitive module that are connected to coefficient register and harmonic oscillator, each variable capacitive module is transformed into the selected control voltage in a plurality of control voltages in response to the coefficient of correspondence in a plurality of coefficients, a plurality of control voltages comprise the voltages of a plurality of different sizes, and wherein selected control voltage varies with temperature and is essentially constant.
Equally, in the exemplary embodiment, described device also can comprise: thus in response to control signal corresponding resistance is transformed into a plurality of switchable resistor that harmonic oscillator is revised resonance frequency.Described device can comprise the voltage divider that is connected to a plurality of controlled reactance modules and is suitable for providing in response to change in voltage selected control voltage.In addition, the operating period variation compensator can be connected to resonator and be suitable for initial value with the currency of the selected parameter in a plurality of parameters and selected parameter and compare and revise resonance frequency in response to the currency of selected parameter and the difference between the initial value.
Numerous other exemplary embodiments are described in detail below, and comprise the other adjuster and the compensator that are used for change in voltage and operating period (IC life-span) variation.
The present invention also can comprise the mode selector that is connected to frequency-selector, wherein mode selector is suitable for providing plurality of operating modes, and it can be selected from the group that comprises following pattern: clock module, timing and frequency reference pattern, energy preservation mode and be subjected to impulse action (or pulse) pattern.
For reference model, the present invention also can comprise the synchronous circuit that is connected to mode selector; And be connected to synchronous circuit and be suitable for providing the controlled oscillator of the 3rd signal; Wherein in timing and reference model, mode selector also is suitable for output signal is connected to timing and the frequency of synchronous circuit to control the 3rd signal.Described synchronous circuit can be delay lock loop, phase-locked loop or injection locking circuit.
These and additional embodiments will discuss in more detail below.Numerous other advantage of the present invention and feature can obviously be found out from the detailed description, claims and drawings of following the present invention and embodiment.
Description of drawings
Target of the present invention, feature and advantage will recognize more easily that wherein same Reference numeral is used for discerning the identical or similar assembly of different accompanying drawings on below in conjunction with the accompanying drawing of a part that constitutes specification and description basis that example carries out, wherein:
Fig. 1 is the block diagram according to example system embodiment of the present invention.
Fig. 2 is the block diagram according to the first exemplary means embodiment of the present invention.
Fig. 3 is the block diagram according to the second exemplary means embodiment of the present invention.
Fig. 4 is senior principle and the block diagram according to of the present invention, examples shown resistant frequency controller, oscillator and frequency calibration embodiment.
The exemplary graph that Fig. 5 A distorts for the oscillator voltage waveform (frequency) that causes owing to the current harmonics component with rectangular window response that injects oscillator.
Fig. 5 B is the temperature-dependent exemplary graph of oscillator voltage waveform (frequency) shown in Fig. 5 A.
Fig. 5 C is the exemplary graph that oscillator frequency becomes with the mutual conductance of keeping amplifier.
Fig. 6 is according to the of the present invention first exemplary negative transconductance amplifier, temperature response current feedback circuit (I (T)), and the circuit diagram of LC oscillator embodiment.
Fig. 7 A is the circuit diagram according to exemplary temperature response CTAT current feedback circuit of the present invention.
Fig. 7 B is the circuit diagram according to exemplary temperature response PTAT current feedback circuit of the present invention.
Fig. 7 C is according to exemplary temperature response PTAT of the present invention 2The circuit diagram of current feedback circuit.
Fig. 7 D is for having selected CTAT, PTAT and a PTAT according to of the present invention 2The circuit diagram of the exemplary optional and scalable temperature response current feedback circuit of structure.
Fig. 8 is according to the of the present invention second exemplary negative transconductance amplifier, temperature response current feedback circuit (I (T)), and the circuit block diagram of LC oscillator embodiment.
Fig. 9 is the circuit diagram according to exemplary first controlled (or controlled) capacitance module that uses in of the present invention, frequency-temperature compensation module.
Figure 10 is the circuit diagram according to exemplary first voltage control module of using in of the present invention, frequency-temperature compensation module.
Figure 11 is the circuit diagram according to exemplary first process variation compensation module of the present invention.
Figure 12 is the circuit diagram according to exemplary second process variation compensation module of the present invention.
Figure 13 is the block diagram according to example frequency calibration module of the present invention.
Figure 14 is the block diagram that suppresses module according to exemplary frequency divider of the present invention, square-wave generator, asynchronous frequency selector and glitch.
Figure 15 is the diagram according to exemplary low latency frequency inverted of the present invention.
Figure 16 is the block diagram according to exemplary frequency divider of the present invention.
Figure 17 is the block diagram according to exemplary power mode selection module of the present invention.
Figure 18 is according to the block diagram that is used for the example synchronization module of second oscillator of the present invention.
Figure 19 is the flow chart according to illustrative methods of the present invention.
Figure 20 is block diagram and circuit diagram according to the exemplary controlled impedance module of using in of the present invention, the compensating module.
Figure 21 is the block diagram according to first example frequency controller of the present invention and device.
Figure 22 is the circuit diagram according to exemplary second controlled capacitance module of using in of the present invention, frequency-temperature compensation module.
Figure 23 is for according to circuit diagram of the present invention, exemplary second voltage control module used in frequency-temperature compensation module.
Figure 24 is the chart according to the example frequency control in response to variations in temperature of the present invention.
Figure 25 is the block diagram according to second example frequency controller of the present invention and device.
Figure 26 is the circuit diagram according to exemplary the 3rd controlled capacitance module of the present invention, that use and exemplary tertiary voltage control module in the parametric compensation module.
Figure 27 is circuit and the block diagram according to exemplary voltage compensating for variations module of the present invention.
Figure 28 is the circuit diagram according to exemplary the 4th voltage control module of the present invention, that use in frequency and technological compensa tion module.
Figure 29 is the circuit diagram according to exemplary resistive control module of the present invention.
Figure 30 is the block diagram according to exemplary operating period variation compensator of the present invention.
Figure 31 is the circuit diagram of spendable the 3rd exemplary L C oscillator according to the present invention.
Figure 32 is the circuit diagram of spendable the 4th exemplary L C oscillator according to the present invention.
Figure 33 is the circuit diagram of spendable the 5th exemplary L C oscillator according to the present invention.
Figure 34 is the circuit diagram of spendable the 6th exemplary L C oscillator according to the present invention.
Figure 35 is the circuit diagram of spendable the 7th exemplary L C oscillator according to the present invention.
Figure 36 is the circuit diagram of spendable the 8th exemplary L C oscillator according to the present invention.
Figure 37 is the circuit diagram of spendable the 9th exemplary L C oscillator according to the present invention.
Figure 38 is the block diagram according to active inductor embodiment of the present invention.
Figure 39 is the block diagram according to the second example system embodiment of the present invention.
Figure 40 is the block diagram according to the 3rd example system embodiment of the present invention.
Figure 41 is the block diagram according to the of the present invention the 3rd exemplary frequency divider embodiment.
Figure 42 is the block diagram according to the of the present invention the 4th exemplary frequency divider embodiment.
Figure 43 is the block diagram according to the 4th example system embodiment of the present invention.
Figure 44 is the block diagram according to the 5th example system embodiment of the present invention.
Figure 45 is the block diagram according to the exemplary first discrete device embodiment of the present invention.
Figure 46 is the block diagram according to the exemplary second discrete device embodiment of the present invention.
Figure 47 is the block diagram according to exemplary the 3rd discrete device embodiment of the present invention.
Figure 48 is the block diagram according to exemplary the 4th discrete device embodiment of the present invention.
Embodiment
When the present invention allows many multi-form embodiment, its specific embodiment has been shown and in this detailed description in the accompanying drawing, should be appreciated that this specification should be regarded as the illustration of the principle of the invention, rather than limit the invention to specific embodiment described here.
As mentioned above, different embodiments of the invention provide dramatic benefit, comprise with pin-point accuracy (with PVT and operating period), low jitter, self-excitation and self-reference clock generator and/or timing and frequency reference and the integrated ability of other circuit, as shown in fig. 1.Fig. 1 is the block diagram according to example system embodiment 150 of the present invention.As shown in fig. 1, system 150 is single IC for both, and clock generator of the present invention and/or timing/frequency reference 100 with other or second circuit 180, integrate together with interface (I/F) (or I/O (I/O) circuit) 120 monolithics.Interface 120 usually will as from power supply (not shown), the earth, and other circuit or bus provide power to clock generator 100, as be used for calibration and frequency selection.As shown in the figure, one or more clock signals provide on bus 125, and it is a plurality of frequencies, as first frequency (f 0), second frequency (f 1), the rest may be inferred, up to (n+1) frequency (f n).In addition, (equally on bus 125) provides energy preservation mode (or low-power mode (LP)).Second circuit 180 (or I/F120) also can provide the input of clock generator 100, as passing through to select signal (S 0, S 1..., S n) and one or more calibrating signal (C 0, C 1..., C n).Perhaps, select signal (S 0, S 1..., S n) and one or more calibrating signal (C 0, C 1..., C n) can directly offer clock generator 100 by interface 120, as on bus 135, together with power (on circuit 140) and ground connection (on circuit 145).
Except low-power mode, clock generator and/or timing/frequency reference 100 also have the other pattern that goes through below.For example, in clock module, device 100 will provide one or more clock signals as output signal to second circuit 180.Second circuit 180 can be the circuit of any kind or kind, can utilize the circuit of one or more clock signals as microprocessor, digital signal processor (DSP), radio circuit or any other.Equally, for example, in timing or frequency reference pattern, can be reference signal from the output signal of installing 100, as be used for the synchronous reference signal of second oscillator.Therefore; term clock generator and/or timing/frequency reference will use interchangeably at this, should be appreciated that clock generator also will provide square-wave signal usually; it can not provide with timing/frequency reference yet, and it can use sinusoidal signal instead in fact.In addition, as detailed below, different embodiments of the invention also provide the pattern that is subjected to impulse action, wherein burst from the output signal of clock generator and/or timing/frequency reference 100 or provide at interval, thereby for example increase instruction process efficient and reduce power consumption.
It should be noted that unlike signal, voltage, fixed current source etc. is called as " in fact " sine or square-wave signal, constant in fact control voltage or fixed voltage or the electric current with parameter in fact with parameter.This will adapt to different fluctuations, noise source and can cause described signal, voltage or electric current other the distortion to differentiate with the better description of in textbook, finding in practice.For example, as detailed below, exemplary " in fact " square-wave signal is shown in Figure 15 A and the 15B, and it has represented multiple distortion, followingly dashes, upper punch, and other variation, and still is regarded as very high-quality square wave in practice.
Several key character of the present invention is in system 150.At first, integrate to form single IC for both (system 150) pin-point accuracy, low jitter, self-excitation and self-reference clock generator 100 and other (second) circuit 180 monolithics.This obviously is different from prior art, in the prior art, reference oscillator is used to provide clock signal such as crystal reference oscillator, and it can not integrate with other circuit and outside sheet, as second and separately device, it must be connected to any other circuit by circuit board.For example, according to the present invention, the system 150 that comprises clock generator 100 can use traditional cmos (complementary metal oxide semiconductors (CMOS)), BJT (bipolar junction transistor), BiCMOS (bipolar and CMOS) or other manufacturing technology of in the modern IC manufacturing, using with other, second circuit makes.
Secondly, do not need independent reference oscillator.But, according to the present invention, clock generator 100 self-references and self-excitation, make its not with reference to or lock another signal, as be synchronized to reference signal in phase-locked loop (PLL), delay lock loop (DLL) or through injection locking, this is very general in the prior art.But exemplary embodiment can be used as the described reference oscillator that produces frequency reference signal, and afterwards, for example, one or more phase lockings or delay lock loop lock onto described frequency reference signal.
The 3rd, clock generator 100 provides a plurality of output frequencies and energy preservation mode, make frequency can low latency and glitch-free manner change.For example, second circuit 180 can be changed into the energy preservation mode, as battery or lower frequency mode, and (by selecting signal) thus the lower clock frequency of request makes the power consumption minimum, or request low power clock signal is to enter sleep pattern.As detailed below, the stand-by period of such frequency inverted can be ignored in fact, because of glitch prevents the stand-by period that causes very low (being proportional to the quantity that glitch prevents level), only use a small amount of clock cycle, rather than change needed thousands of the clock cycle of output frequency from PLL/DLL.
Additional embodiments also produces a plurality of frequency reference signals, no matter is sine or square-wave signal, as being used as one or more clock signals or reference frequency source.In the exemplary embodiment, clock/frequency reference of the present invention is connected to one or more phase-locked loops (PLL) or delay lock loop (DLL), corresponding a plurality of output reference signals of selected frequency to provide.These exemplary embodiments usually can be by control signal or the coefficient of being preserved programming, as select to regulate the frequency dividing ratio of PLL or DLL for correspondent frequency.
In addition, provide the very high available output frequency of following clock generator and/or timing/frequency reference 100, then can obtain new operational mode.For example, in fact or in fact the Clock enable time can be ignored, and makes that clock generator and/or timing/frequency reference 100 will be repeated to start and stop, as turning off fully for the energy preservation or intermittently opening.For example, not to move continuously with clock, but clock generator and/or timing/frequency reference 100 can quite lack, discontinuous interval or burst (promptly being subjected to impulse action), regular or non-periodic operation, to be used for the instruction process of second circuit 180 as processor.As detailed below, because rapid boot-up time, the described operation saving power that is subjected to impulse action is because the instruction that every milliwatt (mW) power consumption is handled more (per second 1,000,000 instruction or MIPS).In addition, except other used, the described pattern of impulse action that is subjected to also can be used for regularly second clock or oscillator synchronously.Therefore, clock generator and/or timing/frequency reference 100 (and following other embodiments) have plurality of operating modes, comprise clock module, timing and/or frequency reference pattern, energy preservation mode and are subjected to the impulse action pattern.
The 4th, as detailed below, clock generator and/or timing/frequency reference 100 comprise the feature that changes the frequency generation that keeps pin-point accuracy with manufacturing process, voltage, temperature (PVT) and operating period.These features comprise frequency tuning and selection, reach the compensation owing to temperature and/or the aging frequency change that causes of voltage fluctuation, manufacturing process variations and IC.
The 5th, clock generator and/or timing/frequency reference 100 produce very big and quite high frequency, and as hundreds of MHz and GHz scope, afterwards, it is divided into a plurality of lower frequencies.Each described N (rational, ratio of integers) that removes causes effective noise reduction, and phase noise reduces N and phase noise power reduces N 2Therefore, clock generator of the present invention directly or by other oscillator that frequency multiplication produces its output causes much lower relative phase shake.
These features are shown specifically in Fig. 2, and it is the block diagram of the first exemplary means embodiment 200, comprise according to frequency controller 215 of the present invention.As shown in Figure 2, device 200 is clock generator and/or timing/frequency reference, and one or more output signals are provided, as has the clock or the reference signal of any frequency in a plurality of frequencies of using frequency-selector 205 selections.Device (or clock generator) 200 comprises oscillator 210 (having resonant element), frequency controller 215, frequency divider 220, mode selector 225, reaches above mentioned frequency-selector 205.According to the present invention, oscillator 210 produces has suitable high-frequency f 0Signal.Because above mentioned PVT or operating period change, frequency controller 215 is used for frequency to be selected or tuned oscillator 210, makes frequency of oscillation f 0Can may frequency of oscillation select from a plurality of, promptly frequency controller 215 provides to have with PVT and operating period variation and still keeps the output signal of frequency accurately.
For example, given these PVT change, and the output frequency of oscillator such as oscillator 210 can change positive and negative 5%.Use for some, as using the application of ring oscillator, such changeable frequency is acceptable.Yet,, need the more clock generator 200 of high accuracy, particularly for sensitiveer or more complicated application, as providing clock signal for integrated microprocessor, microcontroller, digital signal processor, communication controler etc. according to the present invention.Therefore, frequency controller 215 is used for regulating according to these PVT variations, makes that the output frequency of oscillator is selected or desirable frequency f 0, it has little what the variation of quantity as ± 0.25% or littler, and has quite low shake.
According to the present invention, the different exemplary embodiments of frequency controller 215 describe in detail below.For example, with reference to Figure 21, it is the block diagram according to example frequency controller according to the present invention 1415 and device 1400, and oscillator (resonator 310 and keep amplifier 305) provides has resonance frequency f 0First output signal.Example frequency controller 1415 is connected to oscillator and revises resonance frequency f in response to the secondary signal that secondary signal such as one or more transducer 1440 provide 0Exemplary frequency controller 1415 comprises one or more following assemblies: transconductance modulator 1420, variable element adjuster (or controller) 1425 (as one or more following controlled electric capacity or controlled reactance modules), technology (or other parameter) adjuster (or compensator) 1430, voltage compensator 1455, coefficient register 1435, and possible operating period variation compensator 1460.According to selected embodiment, frequency controller 1415 also can comprise one or more transducers 1440, modulus (A/D) transducer (ADC) 1445, reach control logic piece 1450.For example, according to the present invention, the fixed current source I (T) with temperature shown in Fig. 4 (or more generally, yI (x)) generator 415 as temperature sensor, provides the corresponding output current that becomes with ambient temperature or junction temperature effectively.The fixed output current with temperature like this can be converted to digital signal by A/D converter (ADC) 1445, and be used for providing different adjustment device or the compensator 1420,1425,1430,1455 and 1460 corresponding coefficient of using (being kept at register 1435) of frequency controller 1415, with according to different parameters such as variable operation temperature or variable manufacturing process control resonance (or output) frequency f 0In other illustrated embodiment, the described output current fixed with temperature (as secondary signal, not inserting the A/D conversion) directly offers different adjusters, as transconductance modulator 1420 and variable element adjuster (or controller) 1425.These adjusters for example flow through resonator 310 by modification then and keep the electric current of amplifier 305 or resonance frequency f is revised in effective reactance or impedance (as electric capacity, inductance or resistance) that modification is connected to resonator 310 and effectively forms the part of resonator 310 0For example, effective reactance (or impedance) can be by fixing or variable capacitance is connected to resonator 310 or be connected with its disconnection and make amendment, or make amendment by the size that modification is connected to one or more reactance of resonator, as by revising control voltage or other continuous control parameter.
In following different embodiment, transconductance modulator 1420 and variable element adjuster (or controller) 1425 are all implemented usually to use temperature parameter, and feasible variation with operating temperature provides stable in fact resonance frequency f 0It will be appreciated by those skilled in the art that these adjusters can be implemented to provide with other variable element becomes or in response to the stable in fact resonance frequency f of other variable element 0, described variable element is as because the variation that causes of manufacturing process, change in voltage, aging, and other frequency change.
Referring again to Fig. 2 now, be to improve performance and reduce shake (noise) and other disturbs, is not to produce low frequency output and it is multiplied to higher frequency as common use PLL and DLL carry out, and the present invention produces quite high frequency output f 0, use frequency divider 220 to be divided into one or more lower frequency (f after it 1F n).Afterwards, have from the clock signal of the one or more frequencies in a plurality of frequencies of frequency divider 220 and use frequency-selector 205 to select.As mentioned above, described frequency is selected glitch-free and is had low latency, thereby the frequency inverted of quite fast and glitch-free is provided.In addition, use mode selector 225 that plurality of operating modes is provided.
Fig. 3 is the more detailed block diagram according to the second exemplary means embodiment of the present invention, i.e. clock generator and/or timing/frequency reference 300.With reference to figure 3, clock generator and/or timing/frequency reference 300 comprise resonator 310 and keep amplifier 305 (constituting oscillator 395), temperature compensator (or adjuster) 315, process variation compensator (or adjuster) 320, frequency calibration module 325, voltage variation compensator (or adjuster) 380, operating period (time) variation compensator (or adjuster) 365, one or more coefficient registers 340, and, also can comprise transducer 385 according to selected embodiment, analog to digital converter (ADC) 390, frequency divider and square-wave generator 330, voltage isolator 355, resonance frequency selector 360, output frequency selector 335, mode selector 345, and low latency starts module 399.Keep amplifier 305, temperature compensator 315, process variation compensator 320, voltage isolator 355, voltage variation compensator 380, operating period variation compensator 365, resonance frequency selector 360, and frequency calibration module 325 be usually included in the frequency controller, as frequency controller 349 (or 215 or 1415).Perhaps, keep amplifier 305 resonator 310 and can be regarded as comprising oscillator 395, have one or more be included in different controller components in the frequency controller 349 (or 215 or 1415) (as temperature compensator 315, process variation compensator 320, voltage isolator 355, voltage variation compensator 380, operating period variation compensator 365, resonance frequency selector 360, transducer 385, ADC390, and frequency calibration module 325).It shall yet further be noted that (330) square-wave generator regularly or among the frequency reference embodiment is not needing.
Resonator 310 can be a resonator of preserving any kind of energy, as the inductor (L) that connects and capacitor (C) with formation LC accumulator, wherein the LC accumulator has the institute's arrangement in the multiple LC accumulator configuration, or is being equivalent to or is being expressed as in this area usually the inductor that is connected to capacitor on the electricity or on the electromechanics.Such LC resonator is illustrated as resonator 405 in Fig. 4.Except the LC resonator, other resonator all is regarded as equivalence and within the scope of the present invention; For example, resonator 310 can be ceramic resonator, mechanical resonator (as XTAL), micro electronmechanical (MEMS) resonator or thin film bulk acoustic resonator.In other example, different resonators can be expressed as the LC resonator by electricity or electromechanical analogy, and also within the scope of the present invention.In the exemplary embodiment, the LC accumulator has been used as resonator, thinks that fully-integrated solution provides high Q value.
Keeping amplifier 305 provides startup and keeps amplification for resonator 310.315 pairs of resonators 310 of temperature compensator provide FREQUENCY CONTROL, with based on because temperature-induced variations is regulated frequency of oscillation.In selected embodiment, according to control degree desired or that require, temperature compensator 315 can comprise the control to electric current and frequency, following description to selected embodiment.For example, temperature compensator 315 can comprise the transconductance modulator 1420 of Figure 21 and can or comprise the two simultaneously by one of parameter adjuster 1425 that adjuster 1420 and 1425 is all in response to temperature fluctuation.Similarly, 320 pairs of resonators 310 of process variation compensator provide FREQUENCY CONTROL, regulate frequency of oscillation with technique change intrinsic in the based semiconductor manufacturing technology, described technique change comprise technique change given Foundry Works in (as batch or operation changes, variation in the given wafer, reach the variation between the tube core and tube core in the same wafer) and different Foundry Works and Foundry Works's technology between technique change (as 130nm and 90nm technology).Voltage variation compensator 380 can be used for keeping stable output frequency with mains voltage variations and other change in voltage.Operating period variation compensator 365 can be used for keeping stable output frequency with the growth of IC operating period, wherein has corresponding variation in the disappearance circuit element along with the time.Frequency calibration module 325 is used for from a plurality of frequency of oscillation adjustment of resonator 310 appearance and selects required output frequency f 0, promptly from a plurality of available or possibility frequency selection output frequency f 0In selected embodiment, coefficient register 340 is used for preserving different exemplary compensator and calibrates the coefficient value that embodiment uses, and it will be described in greater detail below.
As mentioned above, in selected embodiment, frequency controller 349 also can comprise one or more transducers 385 and analog to digital converter (ADC) 380.In addition, many other compensators of frequency controller and adjuster comprise the assembly as transducer, as the current source fixed with temperature and other voltage variation detectors.Except being used to produce a plurality of the preservation the coefficient that provides control to the different switching element, be about to controlled reactance modules (following) and be transformed into resonator 310 (as the control of discontinuous form) and change the effective reactance amount that reactance that connect or conversion offers resonator 310 (controls of conitnuous forms), different transducers, compensator and adjuster also can be used for the resonance frequency of resonator 310 is provided the continuous control of other form.As described below, export as the control signal in the scope of the invention continuously from the different of transducer, current feedback circuit, control voltage etc.For example, different control voltage, it changes with selected parameter (as temperature) or remains unchanged with respect to selected parameter, with the control signal that acts on the corresponding size of revising the controlled capacitance module of using the variable reactor realization.
Except temperature and technological compensa tion, voltage isolator 355 provides the isolation with change in voltage, as changing from power source voltage, and can implement separately or implement as the part of other assembly, as the part as temperature compensator 315.Except changing because of these PVT and operating period the frequency adjustment of carrying out, resonance frequency also can be selected separately by resonance frequency selector 360, thereby from available frequency range acquisition institute selected frequency.
Take place for clock signal, clock generator 300 uses (in the module 330) frequency divider will export frequency of oscillation f 0Be converted to a plurality of lower frequency (f 1F n) and user's wave producer (also in module 330) will be in fact sinusoidal oscillator signal be converted in fact square-wave signal and use to be used for clock.Afterwards, frequency-selector 335 selects to have one or more in the usable output signal of a plurality of frequencies, and mode selector 345 also can provide operational mode to select, as low-power mode is provided, is subjected to impulse action pattern, reference model etc.Use these assemblies, clock generator 300 provides a plurality of pin-point accuracys (with PVT), low jitter, reaches stable output frequency f 0, f 1F n, it has because of described PVT changes the minimum negligible frequency displacement that causes, thereby provides enough accuracy and stability to aforesaid sensitivity or complicated applications.
Fig. 4 is senior principle and the block diagram according to example frequency controller of the present invention, oscillator and frequency calibration embodiment.As shown in Figure 4, resonator is embodied as resonance LC accumulator 405, and frequency controller is embodied as several elements, current feedback circuit I (T) (or more generally for negative transconductance amplifier 410 (be used for realize keep amplifier), temperature response (or decide with temperature), yI (x), in response to any described parameter x) 415, temperature response (or decide with temperature) frequency (f 0(T)) compensating module 420, process variation compensation module 425, and also can comprise frequency calibration module 430.Different temperature responses or with temperature fixed the module 415 and 420 pairs of temperature fluctuations are responsive or in response to temperature fluctuation, and provide corresponding adjusting, make resonance frequency change and keep stable and accurately with PCT and operating period.
Have the resonance LC accumulator 405 of keeping amplifier and can be described as harmonic oscillator or harmonic wave nuclear with being equal to, and all such variations all within the scope of the present invention.It should be noted that at resonance LC accumulator 405 other circuit layout also is well-known and is equivalent to described structure, as inductance and capacitances in series when to be inductors 435 in parallel with capacitor 440.Another such equivalent arrangements as shown in Figure 8.In addition, as mentioned above, the resonator of other type also can use and be considered as being equivalent to exemplary resonant LC accumulator described herein.In addition, as detailed below, other electric capacity and/or inductance, no matter fix or variable (and more generally referring to impedance or reactance (or reactance component)), be distributed in a part that also constitutes resonance LC accumulator 405 in the different modules effectively, and be used as the part of frequency controller of the present invention.In addition, corresponding resistance (resistive elements of different impedances) R L445 and R C450 are shown separately, but to should be understood to be respectively the essence of inductor 435 and capacitor 440, and it occurs as part of making, rather than the other or independent assembly outside respective inductor 435 and the capacitor 440.On the contrary, described resistance other or essence (parasitism) also can comprise as the part of the compensation that PVT is changed, and is following described with reference to Figure 29.
The inductor 435 of resonance LC accumulator or oscillator 405 and the size of capacitor 440 just in time or approximately provide selected frequency of oscillation f 0Or f 0Near surge frequency range.In addition, the size of inductor 435 and capacitor 440 has or satisfies the requirement of IC layout area, the area that high more frequency requirement is few more.Those skilled in the art will recognize that, f 0 ≈1/2 π LC , But only as first approximation, since as described below, other factors such as impedance R LAnd R C, any other resistor, influence f together with temperature and technique change and other distortion 0, and can be included in second order and three rank approximate in.For example, the big I of inductor 435 and capacitor 440 is created in the resonance frequency in the 1-5GHz scope; In other embodiments, may need higher or lower frequency, all such frequencies all within the scope of the present invention.In addition, inductor 435 and capacitor 440 can use any semiconductor or other circuitry process technology manufacturing, and can with the CMOS compatibility, with the bipolar junction transistor compatibility, in other embodiments simultaneously, inductor 435 and capacitor 440 can use silicon-on-insulator (SOI), metal-insulator-metal type (MiM), polycrystalline silicon-on-insulator-polysilicon (PiP), GaAs, strained silicon, heterojunction semiconductor technology or based on the technology manufacturing of MEMS (micro electronmechanical), are as an example and unrestricted equally.Should be appreciated that all such embodiment all within the scope of the present invention.In addition, except resonance LC accumulator 405 or replace it, other resonator and/or oscillator embodiment also can use and also within the scope of the present invention.As used herein, " LC accumulator " will mean can provide any of vibration and all inductors and capacitor circuit Butut, structure or layout.The ability that it should be noted that the oscillator 405 that will use traditional handicraft such as the manufacturing of CMOS technology make clock generator can with other circuit such as second circuit 180 integrated and monolithic ground manufacturings, and provide distinct advantages of the present invention.
In addition, the electric capacity 440 shown in Fig. 4 only is the resonance of resonance LC accumulator 405 and the part that frequency is determined related whole electric capacity, and is fixed capacity.In selected embodiment, this fixed capacity can be represented about 10%-90% of the final total capacitance of using in the oscillator.Perhaps, if desired, electric capacity 440 also can be embodied as variable capacitance.As detailed below, all electric capacity all is assigned with, make other fixing and variable capacitance be included in selectively in clock generator and/or the timing/frequency reference 300, and for example provide described assembly such as temperature-response frequency (f by the assembly of frequency controller (215,1415) 0(T)) compensating module 420 and process variation compensation module 425 are with the selective resonance frequency f 0And make resonance frequency f 0Can be independent of temperature and technique change in fact.
In selected embodiment, inductance 435 has been fixed, but also can variable mode implement, or is embodied as the combination of fixing and variable inductance.Therefore, those skilled in the art will recognize that independent for frequency tuning and temperature and technology, the going through of fixing and variable capacitance is fit to inductance similarly and selects.For example, different inductance can be in oscillator or outside conversion to provide tuning similarly.In addition, the inductance of single inductor also can be conditioned.Thus, inductance that all are such and capacitance variations and are illustrated as convertible, variable and/or the constant reactance element or the assembly of the controlled reactance modules 1805 of the exemplary controlled impedance module 1305 of Figure 20 and Figure 25-27 all within the scope of the present invention.
Equally as shown in Figure 4, resonance LC accumulator 405 reaches and is differential signal and common mode inhibition is provided in gained output signal node or circuit 470 and 475 places, that be called first (output) signal.Other structure comprises non-difference or other single-ended configuration also within the scope of the present invention.For example, in single-ended configuration, have only the illustration of a disparate modules (as 485,460) to be required, rather than use two to realize balanced structure as shown in the figure.Similarly, following other assembly and feature such as frequency divider also should have single-ended rather than differential configuration.Except the difference LC oscillator shown in Fig. 6 and 8, other exemplary L C oscillator comprises difference and single-ended LC oscillator, will be described with reference to figure 31-37 below.In addition, shown different embodiment use the mosfet transistor (mos field effect transistor) of multi-form (as CMOS, accumulation type MOSFET (AMOS), transoid MOSFET (IMOS) etc.); But other implement also can, as using bipolar junction transistor (BJT), BiCMOS etc.All such embodiment all are considered as equivalence also within the scope of the present invention.
Select negative transconductance amplifier 410 with by mutual conductance (g m) regulate and the conducting resistance of resistor provides temperature-compensating.Mutual conductance (g m) regulate also and can when frequency is selected, independently use.The selection that another significant advantage of the present invention is a negative transconductance amplifier 410 is to provide startup and to keep amplification, influenced because amplitude of oscillation and frequency keep the mutual conductance of amplifier, thereby except that temperature-compensating is provided, also provide amplitude to regulate and frequency finishing (or tuning).Negative transconductance amplifier 410 injects resonance LC accumulator 405 (and being infused in especially on the capacitor 440) in response to the voltage v that strides resonance LC accumulator 405 (as shown in the figure, striding node 470 and 475) with electric current.This electric current injects and will change (with making distortion) voltage waveform (because voltage is the integration of electric current) then, thereby causes frequency shift or variation, and it is inversely proportional to mutual conductance g usually mSize, as shown in Fig. 5 A.It should be noted that this mutual conductance is a negative value, because provide gain to eliminate the loss essence of resonant element.Therefore, no matter when use " trsanscondutance amplifier ", be to be understood that the simplification that it meant and only be " negative transconductance amplifier " at this.Mutual conductance also becomes with bias current, (approximately) is proportional to the square root (for MOSFET) of the electric current (yI (x)) by amplifier 410 in fact, and (approximately) is proportional to electric current (yI (x)) (for BJT) by amplifier in fact, it is decided with temperature, thereby cause with temperature and bias current and fixed wave distortion, as shown in Fig. 5 B.In addition, as shown in Fig. 5 C, frequency of oscillation is also relevant with the mutual conductance of keeping negative transconductance amplifier 410 and become with it, thereby provides frequency of oscillation to select.In addition, except temperature correlation (being I (T)), electric current also can become (therefore more generally being called electric current I (x)) with other parameter or variable, and described parameter or variable such as voltage or outside tuning, electric current also can be exaggerated as passing through factor y (as described below); Therefore electric current is called as yI (x).
As mentioned above, more generally, described variable current yI (x) can be used as the part of transducer or transducer, as the one or more transducers 1440 of Figure 21 or the transducer 1815 of transconductance modulator 1420 or Figure 25.For example, when described variable current is provided by I (T) generator 415, make the electric current that is provided become (parameter or variable x=temperature parameter T) with temperature, thereby I (T) generator 415 is as temperature sensor, and can regulate resonance frequency f as being used in response to temperature fluctuation similarly with in the exemplary embodiment by frequency controller (215,349,1415) 0For example, the transconductance modulator 1420 of Figure 21 can comprise such temperature (or other parameter) responsive current source 415 (it is also as transducer 1440), thereby provides electric current to keeping amplifier 305.
Invention of great significance breakthrough of the present invention comprises advantageously uses these possibility distortions, at the selected f that produces oscillator 0Carry out the adjusting of frequency compensation and the mutual conductance by keeping amplifier during value and carry out frequency adjustment.Therefore, as detailed below, at first, mutual conductance can be frequency and selects to make amendment or change, secondly, can be to because temperature, voltage, manufacturing process or the aging frequency change that causes compensate, it is undertaken by revising electric current yI (x) usually in real time or almost in real time.According to the present invention, selected frequency f 0And can be by suitably selecting mutual conductance g with respect to the stability of variations in temperature mDetermine with selection I (T).In other words, according to the present invention, bias current is caught and temperature correlation, and it is I (T) (or more generally, being yI (x)), and it influences mutual conductance g then m, influence frequency of oscillation f then 0This method also can be used for other variable, as voltage fluctuation, technique change or aging the variation.
Fig. 6 is according to exemplary negative transconductance amplifier of the present invention (410), temperature-response current generator (I (T) 415), and the circuit diagram of LC accumulator resonator (405) embodiment.As shown in Figure 6, resonance LC accumulator 500 is connected to and is embodied as the negative transconductance amplifier 505 (comprising transistor M1, M2, M3 and M4) that complementary chiasma connects pair amplifier, and it is connected to temperature-response current generator (I (x)) 515 by voltage isolator 510 (being embodied as current mirror (transistor 525A and 525B) and interchangeable at this) then.Current mirror 510 (voltage isolator) also is embodied as cobasis cascode layout (520A and 520B), thereby the stability of raising is provided and makes oscillator and isolated from power (voltage isolation) with power source change.But temperature-response current generator 515 operation techniques are as the CTAT shown in Fig. 7 A, 7B and 7C (in contrast to absolute temperature), PTAT (being proportional to absolute temperature) or PTAT respectively 2(be proportional to absolute temperature square) and CTAT, PTAT and PTAT shown in Fig. 7 D 2Combination implement.In each situation, inject the electric current I (T) (or yI (x)) and the temperature correlation of negative transconductance amplifier (complementary chiasma connection pair amplifier) 505, as shown in the figure, increase electric current (PTAT and PTAT with temperature 2) or reduce electric current (CTAT).One or more combinations of these temperature-response current generator also can be embodied as shown in Fig. 7 D, and are in parallel with PTAT as CTAT.
Specified temp-response or with temperature the selection of fixed current feedback circuit also becomes with the manufacturing process of using; For example, CTAT can be used for Taiwan semiconductor (TSMC) manufacturing process.More generally, because different producers uses different materials, as aluminium or copper, R LUsually change, this causes different temperatures coefficient, and it changes the temperature coefficient of oscillator then, thereby needs I (T) equalizing differences.CTAT, PTAT and the PTAT that correspondingly, may need different proportion 2So that temperature-dependent effective flat frequency response to be provided.Do not illustrate separately, the different temperatures shown in Fig. 7 A, 7B, 7C and the 7D-response current generator can comprise start-up circuit.In addition, for shown in exemplary layout, comprise that the transistor of selected temperature-response current generator architecture can be by biasing differently, as for CTAT (M7 and M8) and PTAT 2(M13 and M14) adds the strong inversion bias voltage, for PTAT (M9 and M10 and PTAT 2(M11 and M12) is by the subthreshold value biasing.
Fig. 8 (I (T or I (x)), reaches circuit and the block diagram of LC accumulator oscillator embodiment according to other exemplary negative transconductance amplifier of the present invention, temperature-response (or decide with temperature) current feedback circuit.As shown in Figure 8, resonance LC accumulator 550 has the layout shown in being different from before, be embodied as the negative transconductance amplifier 505 (transistor M1, M2, M3 and M4) that complementary chiasma connects pair amplifier but also be connected to, it is connected to temperature-response (or decide with temperature) current feedback circuit (I (T or I (x)) 515 by a plurality of current mirrors 510 (or 520) and 530 then.As shown in the figure, a plurality of current mirrors are used for providing in succession gain and increase the electric current I (T) that enters negative transconductance amplifier 505 and resonance LC accumulator 550.Usually, provide the end device in the current mirror (as the transistor M6 among Fig. 6) that the electric current that enters node B and its drive negative transconductance amplifier to be selected as the PMOS device, thereby may need what reflection (as shown in the figure) so that the input of PMOS current mirror is offered g mAmplifier.Usually select PMOS, well-known because in modern CMOS technology, the PMOS device is generally the buried channel device, it is compared nmos device equally big or small and similar bias voltage and represents littler flicker noise.The reduction of flicker noise causes the phase noise of oscillator and the reduction of shake in the device of end, because flicker noise increases conversion frequently by the non-linear active parts in the circuit near frequency of oscillation.
As mentioned above, the part that current mirror 510 or 520 (or other circuit) acquisition enters the electric current of negative transconductance amplifier 505 should have high impedance to reduce the power supply frequency displacement in its output, use long crystal pipe geometry and cobasis common-emitter configuration to increase output resistance as passing through, and provide good stability at node B.In addition, thus shunt capacitor 570 also may be utilized and reduces flicker noise from different ends device with filtering.
According to selected application, the use with negative transconductance amplifier 505 of its I (T) (or yI (x)) bias voltage can provide enough frequency stabilities, makes other frequency controller assembly must or not need in this application.Yet, in other embodiments, can use the one or more assemblies that describe in detail below that other accuracy and frequency displacement still less are provided.
Except the electric current yI (x) (or I (T)) fixed with temperature was provided, each among different transistor M1, M2, M3 and the M4 all had the resistance that is associated between conduction period, and it also is tending towards causing frequency distortion and frequency displacement in the duration of oscillation.In every half cycle, or M1 and M4 or M2 and M3 connection and conduction.Described resistance is also decided with temperature.Therefore, transistor M1, M2, M3 and M4 size (width and length) should be conditioned so that described frequency effect is compensated.Should note, the electric current that injects resonance LC accumulator 405 must be enough to keep vibration (as shown in Fig. 5 C), thereby will have minimum value, it can limit degree or the ability that reaches the FREQUENCY CONTROL of current feedback circuit 415 (or 515) enforcement fixed with temperature easily by negative transconductance amplifier 410 (or 505).Therefore, I (T) and transistor (M1, M2, M3 and M4) size should be selected with the startup of vibrating jointly, adapt to the maximum current of power consumption restraint conditions and be assembled to selected IC zone and layout.For example, can select mutual conductance g mThereby, enough electric currents guarantee to start and keep vibration so that approximately being provided, it has with temperature increases the frequecy characteristic that frequency reduces, afterwards the size of transistor M1, M2, M3 and M4 is adjusted to enough big so that frequency is independent of temperature or increases with temperature, used suitable I (T) to select fine setting frequency-temperature relation afterwards.In the embodiment of selected model, this caused with PVT change frequency accuracy approximately ± 0.25%-0.5%, this far exceeds required accuracy for many application.
Refer again to Fig. 4, other compensating module also as the part of frequency controller (215,349,1415) with to resonance frequency f 0Bigger control and accuracy is provided, as be used for need bigger accuracy and the application of littler variation (or frequency displacement), or wherein technology does not allow previous technology to change the application of the accuracy that provides enough with PVT or operating period, and making provides approximately ± 0.25% or better frequency accuracy.In these cases, can use (or temperature-response) frequency (f fixed with temperature 0(T)) compensating module 420, as exemplary temperature-response frequency (f 0(T)) compensating module 420.For example, this module can use controlled (or controlled) capacitance module 485 to realize that each capacitance module is connected to the respective side or the main line (circuit 470 and 475) of resonance LC accumulator 405, and each capacitance module is all at more than first (w) conversion coefficient (p 0P (w-1)) under (register 495) centralized control of providing, and voltage controller provides by more than second (x) conversion coefficient (q 0Q (x-1)) (register 455) definite control voltage, the representative instance as shown in Fig. 9 and 10.(term " controlled " reaches " controlled " and uses interchangeably at this).Other exemplary embodiment is shown in Figure 20, and it illustrates the exemplary controlled impedance module of using in frequency-temperature compensation module 1300, as replacing controlled (or controlled) capacitance module 485 or the module of conduct except that it in the module 420; In Figure 22, its show controlled capacitance module 485 another change because controlled capacitance module 1500 have a plurality of with temperature fixed or with other parameter fixed control voltage (press generation shown in Figure 23 or 26); In Figure 25, it shows a plurality of controlled reactance modules 1805, these module responds are switched on or switched off (be connected to resonator or be connected with its disconnection) in the control signal from control logic 1810 and transducer 1815, and described control signal comprises the feedback from oscillator; In Figure 26, show a plurality of controlled reactance modules 1805, these module responds are switched on or switched off and/or are transformed into control voltage in control signal (continuously) or coefficient (dispersing); And in Figure 27, showing a plurality of controlled reactance modules 1805, these module responds are changed in control signal, thereby are used for compensating for changes in voltage.Several dissimilar available conversions are arranged, as reactance or impedance are connected to resonator or be connected with its disconnection, maybe with the reactance that connects or impedance transformation to selected control voltage or other control signal.
Fig. 9 is the circuit diagram according to exemplary first controllable capacitance module 635 of the present invention, and it can be used as controlled (or controlled) capacitance module 485 in frequency-temperature compensation module 420 (and link resonance LC accumulator 405 each side (node or circuit 470 and 475)).As shown in the figure, controlled (or controlled) capacitance module 635 comprises the fixed capacitor (C of one group of a plurality of (w) binary weighting f) 620 and variable capacitor (the variable reactor) (C of binary system or other difference weighting v) 615 switchable capacitive module 640.The fixed capacitor 620 of any kind and variable capacitor (variable reactor) 615 all can use; In selected embodiment, variable reactor 615 is AMOS (accumulation type MOSFET), IMOS (transoid MOSFET) and/or junction type/diode variable reactor.Each switchable capacitive module 640 has the same circuit layout, and each capacitance module differentiates switchable capacitive module 640 by the electric capacity of binary weighting 0Electric capacity with 1 unit, switchable capacitive module 640 1Have the electric capacity of 2 units, the rest may be inferred, switchable capacitive module 640 (w-1)Have 2 (w-1)The electric capacity of unit, per unit are represented specific capacitor size or value (being generally millimicrofarad (fF) or picofarad (pF)).As mentioned above, other difference weighting scheme also can be used with being equal to, as linearity or binary system, and also can comprise by reactance being transformed into selected control voltage described difference weighting is provided, thereby increase or reduce its effective reactance.
In each switchable module 640, each is fixing and variable capacitance is initially equal, and variable capacitance is allowed in response to the control change in voltage that provides at node 625.This control voltage changes with the selected variable element of temperature or another then, thus cause that controlled capacitance module 635 provides all or all electric capacity also become with temperature (or other parameter), this is used to change resonance frequency f then 0In other selected embodiment, any control voltage in a plurality of control voltages all can use, and comprises static control voltage, to carry out the compensation of other type as described below.Equally, in each switchable capacitive module 640, by using conversion coefficient p 0P (w-1), or fixed capacity C fOr variable capacitance C vBe switched into circuit, but not the two exists simultaneously.For example, in selected embodiment, for given or selected module 640, when its corresponding p coefficient is logic high (or high voltage), corresponding fixed capacity C fBe switched into circuit, and corresponding variable capacitance C vBe converted out circuit and (and be connected to electrical mains voltage V DDOr ground connection (GND), depend on that device is AMOS or IMOS, to avoid unsteady node and to make the electric capacity minimum of presenting to accumulator), when its corresponding p coefficient is logic low (or low-voltage), corresponding fixed capacity C fBe converted out circuit, and corresponding variable capacitance C vBe switched into circuit and the control voltage that provides on node 625 is provided.
In the exemplary embodiment, whole 8 switchable capacitive module 640 (and corresponding 8 conversion coefficients) all have been implemented so that 256 kinds of combinations of fixing and variable capacitance to be provided.Therefore, provide the temperature-dependent effective control of frequency of oscillation.
It should be noted that in this exemplary embodiment, provide fixed capacity C fOr variable capacitance C vBe converted into or change out, fix the amount or the degree that correspondingly change the temperature response of controllable capacitance module 635 with variable ratio.For example, along with variable capacitance C vAmount increase, controllable capacitance module 635 provides bigger changeability in response to temperature (or other parameter), thereby regulates the frequency response of accumulator or other oscillator.
Figure 10 is for providing control voltage V according to of the present invention being used in (frequency-temperature compensation module 420) controllable capacitance module 635 CTRLThe circuit diagram of the exemplary fixed voltage control module 650 of 480 (Fig. 4) with temperature.As shown in the figure, voltage control module 650 is used current feedback circuit 655 as discussed previously, is used PTAT, PTAT 2And/or one or more combination results of CTAT current feedback circuit electric current I (T) fixed with temperature (or more generally, electric current I (x)), and can share employed I (T) generators 415 with negative transconductance amplifier 410, rather than independent generator 655 is provided.The electric current I (T) (or I (x)) fixed with temperature reflexes to a plurality of switchable resistive module or branch road 675 and fixed capacity module or branch road 680 by current mirror 670, all structures all in parallel.In other exemplary embodiment, change according to parameter compensation, also can use other following control voltage generator.
In other combination, according to PTAT, PTAT 2And/or the selection of CTAT current feedback circuit and weighting, the electric current fixed with temperature also can be produced.For example, PTAT generator and CTAT generator have equal size but opposite slope, can be combined together to produce the current feedback circuit that constant current is provided with temperature fluctuation.For example, such current feedback circuit is used in the aging variation compensator shown in Figure 30 constant current source is provided.Those skilled in the art will recognize that other current source also can use,, and can be used as the correspondent voltage transducer as current source with mains voltage variations.
Resistor 685 can be any kind or dissimilar combinations, as diffused resistor (p or n), polysilicon, metal resistor, self aligned polycide or non-self aligned polycide resistor or trap resistor (p or n trap).According to the type or the type combination of selected resistor, resistor 685 also will have corresponding temperature correlation (or response) usually, thereby for the given electric current by selected resistor 685, striding selected resistor 685 provides temperature-dependent relevant voltage to change.For example, diffused resistor will have high-temperature coefficient (providing bigger change in voltage with temperature) usually, and polyresistor will have low-temperature coefficient (providing littler change in voltage with temperature) usually, and for selected module 675, the series hybrid of a plurality of these different resistor types will be provided at the respective response between these height and the low-response level.Perhaps, resistor 685 can be sized or weighted to provides the different voltage levvls that become as the electric current fixed with temperature (as I (T)) with given electric current, thereby provides corresponding temperature-dependent change in voltage for described temperature variant electric current.
Each switchable resistive module 675 is by more than second (x) conversion coefficient q 0Q (x-1)In corresponding q coefficient be converted into or change out voltage control module 650.When switchable resistive module 675 is switched into circuit (as when its corresponding coefficient is logic high or high voltage), owing to the electric current I (T) fixed with temperature, the voltage of striding its respective resistors 685 of gained is also decided with temperature.In selected embodiment, use three variable resistor modules 675,8 kinds of branch combinations are provided.Therefore, the control voltage that offers node 625 becomes with temperature (or other parameter), thereby provides temperature or other parameter correlation or sensitivity to the variable capacitor in the controllable capacitance module 635 615.More generally decide with parameter or with temperature fixed other resistive module will be below respectively in conjunction with Figure 23 and 26 and Figure 28 be described.
More than first conversion coefficient p 0P (w-1)And more than second conversion coefficient q 0Q (x-1)Can have the typical IC of clock generator of the present invention and after manufacturing, determine by test.For given manufacturing process (describing), in case resonance frequency f below in conjunction with Figure 11 and 12 0Selected and/or calibration, the temperature of oscillator (or other parameter) response promptly is determined and regulates, and provides constant in fact selected resonance frequency f with the described variation for environment or operating temperature (or other variable element) 0In the exemplary embodiment, more than first conversion coefficient p 0P (w-1)At first determined by the various combination of test coefficient, so that elementary adjusting to be provided, thereby cause with change that ambient temperature becomes in fact or general flat frequency response.As shown in Figure 24, more or less fixed capacity C fOr variable capacitance C vBe switched into or change out oscillator.For example, when oscillator is represented by line 1705 or 1710 the not compensating frequency response of variations in temperature, other variable capacitance C vCan be switched into, thereby the frequency response of oscillator tentatively is adjusted to line 1715.On the contrary, when oscillator is represented by line 1725 or 1730 the not compensating frequency response of variations in temperature, other fixed capacity C fCan be switched into, thereby the frequency response of oscillator tentatively is adjusted to line 1720.
Afterwards, more than second conversion coefficient determined by the various combination of test coefficient equally, so that the adjusting of outstanding level to be provided, thereby cause with changing the response of flat frequency in fact that ambient temperature becomes, as shown in Figure 24, the frequency response (line 1715 or 1720) of part compensation is adjusted to the smooth in fact response of line 1700, and it is undertaken by the temperature response of selecting different resistors 685.Afterwards, more than first and second coefficient is written in the corresponding registers 495 and 455 among all IC that make in the selected processing round (or batch).Handle according to making, under other situation, for higher accuracy, each IC can be calibrated separately.Therefore, pull together with the temperature-compensating that negative transconductance amplifier 410 and I (T) generator 415 provide, whole frequency responses of clock generator are independent of temperature fluctuation in fact.
In other exemplary embodiment, more than first conversion coefficient p 0P (w-1)With more than second conversion coefficient q 0Q (x-1)Also can dynamically determine and change at the oscillator run duration, as transducer 1440 and the A/D converter 1445 by as shown in Figure 21, or transducer 1815 and control logic (or control ring) 1810 by as shown in Figure 25.In these alternatives, more than first and second coefficient of being preserved can be deleted or be walked around, as shown in Fig. 9 and 10, correspondent voltage directly imposes on corresponding transition components (and similarly, expanding other following a plurality of coefficients to) as control signal.
For example, as shown in Figure 26, as detailed below, any current source in a plurality of current sources 1955 all can different combinations offer a plurality of resistive module, producing a plurality of control voltages in response to selected parameter P, it can any combination be transformed into each module in a plurality of controlled reactance modules 1805, for example, described module is presented as controlled capacitance module 1505 (Figure 22), with the effective reactance of control resonator.In addition, any voltage in the control voltage of a plurality of constant (being independent of temperature) also can be produced, as shown in Figure 28.In addition, also can use other or the other current source of type, or produce control voltage or provide transducer 385,1440 abilities, as with supply voltage V DDThe current source that changes or be independent of the current source of supply voltage, temperature and other parameter.Except discrete control, any control voltage in these control voltages all can be used for the parameter variation is carried out real-time continuous control as variations in temperature.
Thus, all electric capacity that offer resonance LC accumulator 405 are assigned to the combination of fixing and variable part, and the variable part response provides temperature-compensating, therefore controls resonance frequency f 0Be converted into the variable capacitance C of circuit (controlled capacitors module 635) vMany more, big more to the frequency response of environmental temperature fluctuation.As mentioned above, fixing and variable capacitor all can use the variable capacitor (variable reactor) that connects respectively or be transformed into constant in fact or variable voltage to implement.
Except temperature-compensating is provided, it should be noted that conversion or controlled (or controlled) capacitance module 635 also can be used for selecting or tuning resonance frequency f 0Those skilled in the art be it is apparent that conversion or controlled capacitance module 635 also can be used for providing frequency response to other parameter variation, as manufacturing process variations, frequency and voltage fluctuation.In addition, following described in conjunction with Figure 20 and 25-27, electric capacity, inductance, resistance or any other reactance or impedance component all can use in these different exemplary embodiments, thereby provide controlled reactance or impedance module to provide selected frequency response to any parameter in a plurality of variable elements such as temperature, voltage, manufacturing process or the frequency.
Figure 22 is according to of the present invention, frequency-temperature compensation module 420 or more generally, (together with the module 1600 of Figure 23) in the frequency controller 215,349,1415 (replace module 485 and 480 or except that it) circuit diagram of the exemplary second controlled capacitors module 1500 of use.1500 operations of second controlled capacitance module are similar to first controlled capacitance module 635, but use variable capacitance to replace fixing and the variable capacitance combination, and use a plurality of different control voltages to replace single control voltage.In addition, described variable capacitance is not connected to resonator or is connected (being connected to resonator always get final product the power transformation appearance) with its disconnection, and is switched to the frequency response that different control voltage becomes with selected parameter such as temperature with control.In addition, selected embodiment can use a module, and the difference weighting can realize by the selected control voltage that is transformed in a plurality of control voltages.
With reference to Figure 22, at least one that the second controlled capacitors module 1500 is used in a plurality of (g) switchable capacitive module 1505, each switchable capacitive module comprises variable capacitance (C v) 1515 A01515 B (g-1)(to diagram, be connected to node 475 or 470 corresponding to symmetry with A and B, and diagram having binary weighting), it can be (by a plurality of transistors or other switch 1520 01520 (g-1)) be transformed into a plurality of control voltage V 0, V 1(x) ... V (k-1)(x) the selected control voltage in is wherein controlled voltage V 0Constant in fact (in fact not in response to selected parameter x, as temperature), and all the other control voltage V 1(x) ... V (k-1)(x) usually in response to selected parameter x such as temperature or to its sensitivity.As shown in the figure, each corresponding variable capacitor is connected (short circuit together) mutually to the back plate of 1515 (A and B), is connected to selected control voltage through switch afterwards.Each described variable capacitance can (be illustrated as more than the 4th coefficient d by corresponding coefficient to 1515 0, d 1... d (k-1)H 0, h 1... h (k-1)Conversion makes that each module 1505 can be by separately and be independent of a plurality of control voltage V 0, V 1(x) ... V (k-1)(x) any control voltage transitions in.Therefore, these switchable module can keep and will be connected to resonator by the effective impedance (as reactance) that is transformed into one or more control voltages changes.
Figure 23 is the circuit diagram according to exemplary second voltage control module of using in frequency-temperature compensation module of the present invention 1600.As shown in Figure 23, the current source 655 of or response sensitive to parameter is (as before in conjunction with the described different CTAT of Fig. 7 A-7D, PTAT and PTAT 2Any current source in responsive to temperature current source and the combination thereof) (by one or more current mirrors (as 670,510,520)) array of offering k-1 resistive module 1605 (is illustrated as module 1605 0, 1605 1... 1605 (k-1)), each described module provides separately or independently controls voltage V 1(x), V 2(x) ... V (k-1)(x), described voltage offers module 1505 (Figure 22).Different respective resistors 1620 0, 1620 1... 1620 (k-1)Can be before in conjunction with the described any kind of Figure 10, size or weight, to provide any selected voltage response to selected parameter such as temperature.As shown in the figure, quiet control voltage V 0Usually use and be connected voltage supply main line V DDAnd any voltage divider between the ground, select corresponding resistance sizes or be worth 1605 0With 1605 ySo that required electrostatic pressure level to be provided.In addition, the generation of a plurality of differences quiet or constant (promptly being independent of temperature) voltage as shown in Figure 28, its by will having differing formed electric current in response to temperature (or another parameter) different current sources and have complementation or the different resistor combinations fixed of opposite temperature response with temperature, thereby cause having different sizes and vary with temperature a plurality of control voltages that remain unchanged in fact.Any voltage in these different voltages all can use as required and be any control voltage in the difference control voltage.
In the exemplary embodiment, the described control voltage difference of in a plurality of control voltages each, so that a plurality of control voltages to be provided, the different responses of each control voltage or be shaped (the difference response (response curve) that becomes with selected parameter such as variations in temperature promptly is provided), and can and remain unchanged in fact with respect to selected parameter in response to different parameters.According to selected embodiment, the array of resistive module 1605 can ((be illustrated as transistor 1610 by corresponding crystal pipe 1610 0, 1610 1... 1610 (k-1))) conversion, thereby be converted into or change out array 1600, or can be comprised (fixedly connected 1615, in Figure 23, be illustrated as dotted line) control voltage V statically with automatic generation predetermined quantity 0, V 1(x) ... V (k-1)(x).According to resistor 1620 (and/or transistor 1610, selection if any), different control voltage V 0, V 1(x) ... V (k-1)(x) each the control voltage in provides different responses such as different temperature responses with difference and to selected parameter or variable.
Similarly, Figure 26 be according to of the present invention, can be used for the circuit diagram that any module in disparate modules provides the exemplary tertiary voltage control module 1900 of control voltage.As shown in Figure 26, the current source 1955 of or response sensitive to parameter is (as before in conjunction with the described different CTAT of Fig. 7 A-7D, PTAT and PTAT 2Any current source in responsive to temperature current source and the combination thereof) (by one or more current mirrors (as 670,510,520)) array of offering n-1 resistive module 1905 (is illustrated as module 1905 0, 1905 1... 1905 (n-1)), each resistive module 1905 provides separately or independently controls voltage V 0(P), V 1(P), V 2(P) ... V (n-1)(P), thereby produce a plurality of control voltages, and it offers controlled reactance modules 1805, controlled capacitance module 1505 (Figure 22) or any other and uses the module of one or more control voltages in response to selected parameter P or according to selected parameter P.Different respective resistors 1920 0, 1920 1... 1920 (n-1)Can be previous described any kind, size or weight, selected parameter is provided any selected voltage response.The selection of current source (or combination of current source) and resistor size and type enable the response of any desired control voltage of shaping to selected parameter.In addition, any voltage in a plurality of different quiet or constant (promptly the being independent of temperature) voltage shown in Figure 28 also can use any control voltage for the difference control voltage that is used for described any module as required.
According to selected embodiment, the array of resistive module 1905 can ((be illustrated as transistor 1915 by corresponding crystal pipe 1915 0, 1915 1... 1915 (n-1))) conversion, thereby dynamically or statically be converted into or change out array, with a plurality of control voltage of automatic generation V 0(P), V 1(P), V 2(P) ... V (n-1)(P).Afterwards, each control voltage in these different control voltages (uses switch 1930 with any assembled static ground or dynamically under the conversion and control of control signal and/or coefficient 1950, as full crossbar switch) be transformed into controlled reactance modules 1805, it can be connected to resonator or also convertiblely go into or change out accumulator.Therefore, any voltage in these control voltages can be used for controlling the effective reactance of resonator (oscillator), thereby provides discrete and continuous control to the resonance frequency of gained.For example, these control voltage Vs fixed with parameter 0(P), V 1(P), V 2(P) ... V (n-1)(P) any voltage in, or any parameter control voltage (Figure 28) that is independent of in fact, can be provided for controlled impedance module 1305 or controlled capacitance module 1505 or 1805 and offer the effective capacitance of resonator, thereby provide FREQUENCY CONTROL with the variation of any parameter in a plurality of parameters with change.
Refer again to Figure 22, as these different control voltage V 0, V 1(x) ... V (k-1)(x) or more generally V 0(P), V 1(P), V 2(P) ... V (n-1)(P) each voltage in, and any constant in fact control voltage all can obtain and by more than the 4th coefficient d 0, d 1... d (k-1)H 0, h 1... h (k-1)Be transformed into the variable capacitance C in the switchable capacitive module 1505 v1515, to the high flexible of selected parameter (as temperature), accurate adjustment, and highly controlled frequency response be provided for resonator 405, enable resonance frequency f 0Carry out the FREQUENCY CONTROL of pin-point accuracy.For example, module 1505 (g-1)In variable capacitance 1515 A (g-1)With 1515 B (g-1)Can be by being made as logic high or high-tension parameter h 1(or the voltage that applies of corresponding dynamic is as control signal) is transformed into control voltage V 1(x), all the other the h parameters in more than the 4th parameter are made as logic low or low-voltage, thereby the first frequency that becomes with temperature or another selected parameter response, module 1505 simultaneously are provided 0In variable capacitance 1515 A0With 1515 B0Can be by being made as logic high or high-tension parameter d (k-1)(or the voltage that applies of corresponding dynamic is as control signal) is transformed into control voltage V (k-1)(x), all the other the d parameters in more than the 4th parameter are made as logic low or low-voltage, thereby the second frequency that becomes with temperature or another selected parameter response is provided, and the rest may be inferred.As mentioned above, more than the 4th coefficient d 0, d 1... d (k-1)H 0, h 1... h (k-1)Also can after manufacturing, determine by the one or more IC of test, or also can dynamically determine and change at the oscillator run duration, as transducer 1440 and the A/D converter 1445 by as shown in Figure 21, or transducer 1815 and control logic (or control ring) 1810 by as shown in Figure 25.More generally, described by or the control of coefficient or control signal as shown in Figure 26, and can be used for the discrete or cline frequency control or the discrete and cline frequency control that become with any selected parameter such as temperature, voltage, manufacturing process, operating period or frequency.
In addition, the coefficient of preserving instead of first, second or more than the 4th coefficient, particularly when corresponding value will dynamically be determined, as mentioned above, correspondent voltage can directly be imposed on different switch (as the conversioning transistor of transistor 1520 or module 640 and 650) as control signal.
Refer again to Fig. 4, other compensating module also is used for resonance frequency f 0Provide bigger control and accuracy, as be used for need bigger accuracy and the application of littler variation (or frequency displacement), making provides approximately ± 0.25% or better frequency accuracy with PVT.In these cases, can use process variation compensation module 425, to be independent of manufacturing process variations to resonance frequency f 0Control the example modules as shown in Figure 11 and 12.As mentioned above, any module in the disparate modules can comprise any impedance, reactance or resistance and be caught in response to any selected parameter such as temperature, technique change, change in voltage, and frequency change.
Figure 11 is the circuit diagram according to exemplary first process variation compensation module 760 of the present invention.First process variation compensation module 760 can be used as the technological compensa tion module 460 among Fig. 4, and each module is linked main line or next door (circuit or the node 470 and 475) of resonance LC accumulator 405.In addition, each in first process variation compensation module 760 is by being kept at (y) conversion coefficient r of more than the 3rd in the register 465 0R (y-1)Control.First process variation compensation module 760 provides has switchable capacitive module array difference weighting (as binary weighting), first fixed capacity 750, by corresponding a plurality of conversioning transistors 740 (by corresponding r coefficient control) a plurality of fixed capacities 750 is converted into or changes out and regulate and the selective resonance frequency f 0Again, along with each capacitive branch is switched into or changes out described array or circuit 760, corresponding first fixed capacity is increased or deducts from the total capacitance that can be used for the vibration of resonance LC accumulator, thereby changes effective reactance and regulate resonance frequency.More than the 3rd conversion coefficient r 0R (y-1)Also can after manufacturing, determine, be generally and definite the same iterative process of a plurality of conversion coefficients of first and second (or four) by test I C.But this calibration frequency of utilization calibration module (325 or 430) and known reference oscillator with preset frequency are realized.Be kept at after the r coefficient of determining in the corresponding registers 465 of IC of this production or process batch.Perhaps, each IC can be calibrated separately.
Except described calibration steps, more than the 3rd conversion coefficient r 0R (y-1)Also can use other method to determine, as described below, as use the parameter or the variable of different voltage and current sensor measurement reflection fabrication process parameters, the absolute current level that produces as the value or the different current source of transistor threshold voltage, resistance sizes or accumulator.Afterwards, the described value that records can be used for providing corresponding coefficient (more than the 3rd conversion coefficient r 0R (y-1)Thereby) and/or control signal be used for correspondent frequency and regulate.For example, described record or the value of sensing can be exchanged into digital value, its indexed then look-up table in memory afterwards, provides the value of preservation based on given value or other calibration or modeling.
For avoiding other frequency distortion, several additional features can be implemented together with this first process variation compensation module 760.At first, for avoiding other frequency distortion, the connection resistance of MOS transistor 740 should be very little, and therefore transistorized width/height is than big.Secondly, big electric capacity can be split as two branch roads, has two respective transistor 740 by identical r coefficient control.The 3rd, for making resonance LC accumulator have similar load under all conditions, when first fixed capacity 750 was switched into or changes out circuit 760, circuit is correspondingly changed out or be converted into to corresponding second fixed capacity 720 as " illusory " capacitor (minimal size with design rule permission of much smaller electric capacity or manufacturing process) based on the inverse of corresponding r coefficient.Thus, always exist about or identical in fact transistor 740 to connect resistance, have only electric capacitance change.
As another selection of using " illusory " electric capacity, metal fuse can be used for replacing transistor 740.Metal fuse remains untouched maintenance comprising corresponding fixed capacity 750, and can " fuse " (open circuit) to eliminate corresponding fixed capacity 750 from resonance LC accumulator 405.
Figure 12 is the circuit diagram according to exemplary second process variation compensation module 860 of the present invention.Second process variation compensation module 860 can be used as the technological compensa tion module 460 among Fig. 4, and each module is linked main line or next door (circuit or the node 470 and 475) of resonance LC accumulator 405, thereby replaces module 760.More generally, second process variation compensation module 860 is as the part of frequency controller (215,349 or 1415), as technology (or other parameter) adjuster or compensator 1430 (Figure 21).In addition, each in second process variation compensation module 860 is by more than the 3rd the conversion coefficient r that is kept in the register 465 0R (y-1)Control.Yet (, since the circuit difference that adopts in each illustrative processes compensating for variations module 760 or 860, corresponding more than the 3rd conversion coefficient r 0R (y-1)Certainly also different mutually.) in addition, described conversion can be controlled by using any control signal, as mentioned above.
It should be noted that Figure 12 provides is different from employed variable reactor diagram in other accompanying drawing, and wherein variable reactor 850 is represented by MOS transistor, rather than has arrow and pass its capacitor.Those skilled in the art will recognize that variable reactor is generally AMOS or IMOS transistor, or more generally, be MOS transistor, transistor as shown in Figure 12, and be configured by transistorized source electrode of short circuit and drain electrode.Therefore, as possible embodiment, the variable reactor shown in other can be regarded as comprising AMOS or the IMOS transistor as being disposed among Figure 12.In addition, variable reactor 850 also can carry out binary weighting mutually relatively, maybe can use another difference weighting scheme.
Second process variation compensation module 860 has similar structuring concept, but with first process variation compensation module 760 other remarkable difference is arranged.Second process variation compensation module 860 provides the array of a plurality of MOS of not having switches/transistorized switchable variable capacitive module 865, has therefore eliminated loss or loading by MOS transistor.But load shows as low loss capacitance; Described low-loss also means the oscillator starting energy still less.In second process variation compensation module 860, MOS variable reactor 850 is switched to Vin, it can be any control voltage in above-mentioned different a plurality of control voltages, to provide corresponding electric capacity level to resonance LC accumulator 405, maybe can be switched to ground or feeder cable (voltage V DD), thereby based on variable reactor 850 geometries or minimum capacity is provided or maximum capacitor is provided.For AMOS, be transformed into voltage V DDMinimum capacity will be provided, and will provide maximum capacitor with being transformed into, then just in time opposite for IMOS.Again, second process variation compensation module 860 is made up of the array as the variable capacitance of variable reactor 850, its by corresponding r coefficient or by use control signal corresponding selected variable reactor 850 is connected or be transformed into any control voltage in a plurality of control voltages (Vin), or V DDRegulate and the selective resonance frequency f as conversion between first voltage and second voltage 0In another alternative, replace a plurality of or array, only use a variable reactor 850, its effective reactance offers by the voltage-controlled accumulator of selected control.
Along with each capacitive branch be switched to control corresponding voltage, or V DD, corresponding variable capacitance is added to or is not included in the total capacitance that can be used for the vibration of resonance LC accumulator, thereby changes its effective reactance and regulate resonance frequency.More specifically, for AMOS embodiment, be connected to V DD(as V In) littler electric capacity is provided, be connected to ground (V In=0) provide bigger electric capacity, and just in time opposite to IMOS embodiment, wherein be connected to V DD(as V In) bigger electric capacity is provided and is connected to ground (V In=0) provides littler electric capacity, suppose that wherein voltage on the LC accumulator main line (node of Fig. 4 or circuit 470 and 475) is at 0 volt and voltage V DDBetween, obviously or in fact away from arbitrary voltage levvl.Be connected to V DDAnd the many voltages in voltage between the ground such as the difference control voltage will provide the electric capacity of corresponding by-level to accumulator as Vin.More than the 3rd conversion coefficient r 0R (y-1)Also after manufacturing, determine by test I C, and usually also for determining more than first and second iterative process that conversion coefficient is such.Afterwards, determined r coefficient is kept in the corresponding registers 465 of IC of this production or process batch.Again, each IC also can calibrate separately and test.In addition, the module 850 of any selected quantity can dynamically be controlled to provide continuous FREQUENCY CONTROL at the oscillator run duration.
As mentioned above, according to the type (AMOS or IMOS) of variable reactor, any switchable capacitive module 865 is transformed into V as first and second voltage levvls DDOr ground will cause corresponding maximum capacitor or zero (insignificant) electric capacity to be included as the effective capacitance of resonator (LC accumulator).Yet, as mentioned above, also can produce electric capacity level between the described minimum and maximum electric capacity by switchable capacitive module 865 being transformed into control corresponding voltage.A plurality of control voltages that use has different sizes will cause the corresponding capacitance of switchable capacitive module 865 to be added to LC accumulator (or deduct from it), thereby change its effective reactance and regulate resonance frequency.
Figure 28 is the circuit diagram according to exemplary the 4th voltage control module of using in of the present invention, frequency, technology or other parametric compensation module 2050.With reference to Figure 28, a plurality of constant in fact voltage modules 2060 (are illustrated as 2060 A, 2060 B, 2060 C2060 K) being used to produce corresponding a plurality of control voltage, it remains unchanged in fact with respect to selected parameter such as temperature, and it has corresponding a plurality of different sizes, thereby produces a plurality of control voltage V with different sizes A, V B, V CV KAs shown in the figure, a plurality of different, quiet or constant in fact (promptly being independent of temperature) voltage is by (being illustrated as current source 2055 in conjunction with different current source 2055 A, 2055 B, 2055 C2055 K) produce, each current source has different response (in response to the differing formed electric current of temperature (or another parameter)) to temperature or another parameter, and has corresponding a plurality of resistor 2040 and (be illustrated as corresponding resistor 2040 A, 2040 B, 2040 C2040 K), each resistor has the fixed response with temperature or other parameter, and this response is opposite or complementary with the response of the respective current sources 2055 of particular module 2060.Select each corresponding current source 2055 and resistor 2040 having described opposite or complementary responses mutually, thereby offset the response of the other side effectively selected parameter.For example, current source 2055 is selected as PTAT of a size suitable, CTAT or CTAT 2The particular combinations of current source, resistor 2040 is selected based on size, type etc., makes gained voltage change with parameter and remains unchanged in fact as variations in temperature.Any voltage in these different voltages can be as required as any control voltages in the different control voltages, providing corresponding Vin, thereby regulate the effective capacitance (reactance) and the gained resonance frequency of resonator to the switchable capacitive module shown in Figure 12 865.
It shall yet further be noted that illustrated module embodiment, temperature compensator 315 as shown in Fig. 6-12 (or 410,415 and/or 420) and process variation compensator 320 (or 425 and 460) all can be used for other purpose.For example, the different illustrated embodiments of compensator 315 (or 410,415 and/or 420) can be caught to decide with technique change, rather than temperature.Similarly, the different illustrated embodiments of compensator 320 (or 425 and 460) can be caught to decide with temperature, rather than technique change.Therefore, exemplary circuit and the structure shown in the embodiment of these and other module should not be considered as being limited to, because those skilled in the art will recognize that other and equivalent circuit and application, all these are all within the scope of the present invention.
As mentioned above, different shown in controlled capacitance module (485,635,460,760,860,1501) can be generalized to any reactance or impedance component, no matter be the combination of electric capacity, inductance, resistance or electric capacity, inductance or resistance.A plurality of (a) like this are convertible, the array 1300 of controlled impedance (or reactance) module 1305 as shown in Figure 20, and can be used in the frequency controller of the present invention (215,349,1400), it is as different adjusters or compensator (315,320,355,1420,1425,1430) arbitrary in.Each different weights, controlled reactance or impedance module 1305 (be illustrated as 1305 0, 1305 1... 1305 (a-1)) comprise one or more constant reactance Z f1315, variable reactance Z v1310 or " illusory " reactance 1320, these reactance can be in response to more than the 5th coefficient (s 0, s 1... s (a-1)) in corresponding coefficient s conversion.As mentioned above, in any embodiment of different embodiment, the array of controlled reactance or impedance module 1305 is embodied as usually with respect to any module operation in the different controlled capacitance module.More than the 5th coefficient can be with as above determining after manufacturing like that or dynamically determine about other coefficient set is described.In addition, according to embodiment, different reactance or impedance can be switched into or change out array 1300 or be transformed into different control voltage or ground, as indicated previously, and can be used for providing the selected frequency response of oscillator in response to any parameter in a plurality of parameters such as variations in temperature, voltage fluctuation, manufacturing process or the frequency.
Similarly, with reference to Figure 25, n array convertible, controlled reactance modules 1805 is illustrated (controlled reactance modules 1805 01805 (n-1)), and also can be used as different adjusters or compensator (315,320,355,1420,1425,1430) is used in the frequency controller of the present invention (215,1415).These controlled reactance modules 1805 also can be by binary system, linearity or different weightings, and are converted into or change out different circuit, are transformed into one or more control voltages or its any combination, and collection can be in response to any selected parameter.As mentioned above, in any embodiment of different embodiment, the array of controlled reactance modules 1805 is embodied as usually with respect to any module operation in the different controlled capacitance module.In this exemplary embodiment, not to be transformed into oscillator by a plurality of coefficients, controlled reactance modules 1805 but the voltage or the electric current dynamic translation that directly provide by transducer 1815 and control logic 1810, has feedback (circuit or node 1820), and it can be by like that well known in the art or implement as mentioned above, and all such variations all are considered as within the scope of the present invention.In addition, reactance module is considered as impedance module widelyer, has resistance and/or reactance feature simultaneously, as using the different resistors as shown in Figure 29.
For example, any method of the described variation in the selected parameter in can previous described several different methods determine, as by thermally sensitive current source, other temperature sensor or in response to the transducer of any other type of selected parameter.For example, transducer can comprise the voltage of transdiode, and the voltage output in response to temperature is provided.With reference to Figure 21, the output of such transducer 1440 can offer A/D converter 1445, it provides the numeral output indication of the level of institute's sensor parameter, afterwards, described indication can be used as corresponding coefficient (any coefficients in above-mentioned a plurality of coefficients) or is used for the different controlled reactance of dynamic translation or any module of the impedance module (as 1305,1805) or different second controlled capacitance module.Similarly, the output of transducer 1815 can offer control logic 1810, its also can or static or dynamically regulate different reactance, have or not from the feedback of resonator.
Figure 27 is circuit and the block diagram according to exemplary voltage compensating for variations module 2000 of the present invention, and can be used as the voltage variation compensator 380,1455 shown in Fig. 3 and 21.With reference to Figure 27, switchable resistive module 1650 constitutes voltage divider, uses resistor 1620 0With 1620 y, voltage V is provided 0At supply voltage V DDUnder the situation of (feeder cable) fluctuation, voltage V 0Correspondingly change.Because voltage can be converted (switch 1930) (as mentioned above) to any controlled reactance modules 1805 under the control of control signal or coefficient 1950, the effective capacitance of accumulator is also changed, thereby regulates resonance frequency.Thus, but with described voltage fluctuation resonance frequency Be Controlled.Other is implemented will be apparent based on other illustrated embodiment, and also within the scope of the present invention.
As mentioned above, except the intrinsic of Fig. 4 or dead resistance R L445 and R COutside 450, the resonance frequency of accumulator also can be made amendment by the resistance that changes accumulator.Figure 29 is according to circuit diagram of the present invention, that can be used as a part of exemplary resistive control module 2100 of different frequency control module and different frequency controller or its.Described resistance control module 2100 can be inserted into the node Q in the resonator 405 of Fig. 4, with inductor 435 and R L445 the series connection, or with capacitor 440 and R C450 series connection, or the two carries out simultaneously.Each switchable resistive module 2115 (is illustrated as a plurality of switchable resistive module 2115 M, 2115 N, 2115 O2115 U) (as binary weighting) resistor 2105 with different weights (is illustrated as corresponding resistor 2105 M, 2105 N, 2105 O2105 U), and can under the control of control signal and/or coefficient 1950, (be illustrated as transistor 2110 by corresponding crystal pipe or switch 2110 M, 2110 N, 2110 O2110 U) be converted into or change out array or module 2100.As mentioned above, described conversion also provides another control or regulates the mechanism of the resonance frequency of resonator 405, and can become with any selected parameter, maybe can be independent of parameter, selects thereby be used for resonance frequency.
Figure 30 is the block diagram according to exemplary operating period variation compensator 2200 of the present invention.As shown in Figure 30, different transducers is used to measure relevant parameter, it is changed with the IC life-span by time path influence or its, measures the one or more resistance sizes of transistorized threshold voltage, electric resistance sensor 2210 measurement accumulators or the absolute current level of value and/or the different current sources generations of current sensor measurement as voltage sensor 2205.Preset time put selected measurement (through multiplexer 2220) thus offering ADC2225 is converted to digital value, this value is kept in register or other nonvolatile memory 2230.When IC powers or during initialization, initial measurement is kept at the comparison basis to be provided for measuring subsequently in the register 2230 for the first time.Subsequently, can carry out other measurement, income value saves as the respective electrical flow valuve in the register 2230, is illustrated as the initial value of electric current and voltage, resistance and electric current.For given parameter, as voltage, electric current and initial value can be read and compare, and afterwards, comparator 2235 provides the corresponding operating period compensating signal that is proportional to two any differences between the value.The described difference that is provided by the operating period compensating signal can be used for corresponding coefficient then and/or control signal is regulated to carry out correspondent frequency.For example, described operating period compensating signal can indexed look-up table in memory 2240, it provides the value of being preserved based on other calibration or the modeling of given value or operating period influence then, and uses above-mentioned any different adjustment device and compensator to carry out correspondent frequency and regulate.
As mentioned above, clock generator of the present invention and timing/frequency reference (100,200,300) can use the oscillator of wide range.In the exemplary embodiment, resonance LC oscillator is used to provide the output signal as first reference signal, and it has the phase noise of much higher Q, low jitter and reduction.The first and second exemplary difference LC oscillators are described with reference to figure 4,6 and 8 in the above.In addition the resonant oscillator of type also within the scope of the present invention, and exemplary LC oscillator will be below with reference to figure 31-37 description, have the active inductor shown in Figure 38.Exemplary L C oscillator that these are other and inductor type (passive or active) all can be used in previous described LC oscillator equivalently, and be their equivalence operation of diagram, be compensating module 420 and 425 diagrams also together with the previous example frequency controller assemblies shown in Fig. 4 of addressing.Should be appreciated that the assembly that specifically illustrates except Figure 31-37, any other controller reactance module, control voltage generator, FREQUENCY CONTROL, calibration, frequency selection, frequency division, and other assembly also can use equivalently.
It shall yet further be noted that any passive inductors shown in arbitrary layout among the exemplary active inductor shown in Figure 38 or any other active inductor alternative Fig. 1-37.Similarly, different layouts is used n-MOS or p-MOS transistor diagram, but the transistor of any kind all can use equivalently.Thereby, use any transistor passive or active inductor or any kind all to be regarded as equivalence also within the scope of the present invention.
Below shown in Different L C oscillator difference or single-ended first reference signal can be provided.Different compensating modules 420 and 425, it can aforesaid multiple mode be embodied as controlled reactance modules, can be in many ways and different oscillator combinations.At first, controlled reactance modules (being illustrated as compensating module 420 and 425) can with one or more shown in any capacitor in the capacitor be connected in parallel.In many cases, LC oscillator shown in a plurality of illustrations of controlled reactance modules can be connected to.Thus, the corresponding node that is used to connect is marked as node A and node B, is connected to the corresponding node of given LC oscillator layout with indication, and other illustration can be used for being illustrated as corresponding node A ' and B ' node and/or corresponding A ' ' node and B ' ' node.Secondly, in different Figure 31-37, do not illustrate separately, controlled reactance modules (being illustrated as compensating module 420 and 425) can be used for replacing one or more shown in any capacitor in the capacitor.Those skilled in the art will recognize that countless other variations, all these variations all are considered as equivalence also within the scope of the present invention.
Figure 31 is the circuit diagram of the 3rd exemplary L C oscillator 2260 spendable according to the present invention, that implement with the cross-coupled layout of difference n-MOS, and it is the variation of the LC oscillator shown in Fig. 8.As shown in the figure, device 2250 comprises the 3rd exemplary L C oscillator 2260 with difference n-MOS interconnection layout and frequency controller and the frequency calibration module of before describing (compensating module 420 and 425) in two balanced structures of Fig. 4.Output frequency f 0At node 470 AWith 475 ABetween obtain, described node is equivalent to previous described node 470 and 475, and all references in alternative accompanying drawing and this specification.
Cross-coupled n-MOS transistor 2251 and 2251 is connected to bias current by current mirror 530A (or 530B), as uses (x) generator 515 of the electric current I in response to parameter (or 415) same as discussed previously or use another to fix or variable current source.Frequency controller module (480,485, have coefficient register 455 and 495) and frequency calibration module (460, have coefficient register 465) strides node A as shown in the figure and B is connected to oscillator, and same such operation as discussed previously.Inductor 2253 and 2254 (inductance shown in having) can (centre cap be connected to V by centre cap inductor 2257 DD) replace equivalently also being inserted in as shown in the figure between node A and the B, and can be fixing or variable inductor.In addition, as discussed previously equally, different electric capacity can be implemented as fixing or variable capacitance, and is illustrated as and has fixing and variable capacitor simultaneously.In the exemplary embodiment, resistance also can be fixing or variable resistor.
Those skilled in the art will find out obviously that the similar interconnection n-MOS version of oscillator shown in Fig. 6 can be implemented (by removing interconnection p-MOS transistor M1 and the M2 shown in (replacing with short circuit)) similarly.
Figure 32 is the circuit diagram of the 4th exemplary L C oscillator 2280 spendable according to the present invention, that implement with the cross-coupled layout of difference p-MOS, and it is the variation of the LC oscillator shown in Fig. 8.As shown in the figure, device 2270 comprises the 4th exemplary L C oscillator 2280 with difference p-MOS interconnection layout and frequency controller and the frequency calibration module of before describing (compensating module 420 and 425) in two balanced structures of Fig. 4.Output frequency f 0At node 470 BWith 475 BBetween obtain, described node is equivalent to previous described node 470 and 475, and all references in alternative accompanying drawing and this specification.
Cross-coupled p- MOS transistor 2271 and 2271 is connected to bias current by current mirror 510 (or 520), as uses (x) generator 515 of the electric current I in response to parameter (or 415) same as discussed previously or use another to fix or variable current source.Frequency controller module (480,485, have coefficient register 455 and 495) and frequency calibration module (460, have coefficient register 465) strides node A as shown in the figure and B is connected to oscillator, and same such operation as discussed previously.Inductor 2273 and 2274 (inductance shown in having) can be replaced equivalently also being inserted in as shown in the figure between node A and the B by centre cap inductor 2277 (centre cap is connected to ground), and can be fixing or variable inductor.In addition, as discussed previously equally, different electric capacity can be implemented as fixing or variable capacitance, and is illustrated as and has fixing and variable capacitor simultaneously.In the exemplary embodiment, resistance also can be fixing or variable resistor.
Equally, those skilled in the art will find out obviously that the similar interconnection p-MOS version of oscillator shown in Fig. 6 can be implemented (by removing interconnection n-MOS transistor M3 and the M4 shown in (replacing with short circuit)) similarly.
Figure 33 for spendable according to the present invention, have a single-ended circuit diagram of examining the 5th exemplary L C oscillator 2305 of complete minor structure (or layout).As shown in the figure, device 2300 comprises having single-ended the 5th exemplary L C oscillator 2305 of complete minor structure (or layout) and the part of previous described frequency controller and frequency calibration module (compensating module 420 and 425 single-ended version) examined.Frequency controller and frequency calibration module (485,460) are striden node A and B as shown in the figure and are parallel-connected to capacitor 2310 or stride node A ' and B ' is parallel-connected to capacitor 2315, or are connected to described two capacitors (stride respectively node A and B and capacitor 2310 in parallel and stride node A ' and B ' is in parallel with capacitor 2315) simultaneously.Output frequency f 0At node 470 CWith 475 CBetween obtain, described node is equivalent to previous described node 470 and 475, and all references in alternative accompanying drawing and this specification.
Transistor 2325 is connected to fixing or changes bias voltage, or is connected to another circuit node (not illustrating separately).In addition, provide bias current equally, as use (x) generator 515 of the electric current I in response to parameter same as discussed previously or use another to fix or variable current source.Same such operation the as discussed previously of frequency controller module (480,485, have coefficient register 455 and 495) and frequency calibration module (460, have coefficient register 465).In addition, as discussed previously equally, different reactance (inductor 2320, capacitor 2310 and 2315) can be implemented as fixing or variable reactance.In the exemplary embodiment, resistance 2330 also can be fixing or variable resistor.
Figure 34 for spendable according to the present invention, have a circuit diagram that difference, cobasis are examined the 6th exemplary L C oscillator of complete minor structure (or layout).As shown in the figure, device 2400 comprise have difference, cobasis is examined complete minor structure (or layout) the 6th exemplary L C oscillator 2405 and previous in frequency controller and the frequency calibration module described in two balanced structures of Fig. 4.Output frequency f 0At node 470 DWith 475 DBetween obtain, described node is equivalent to previous described node 470 and 475, and all references in alternative accompanying drawing and this specification.
Transistor 2425 and 2426 can be connected to fixing or change bias voltage.Use the transistorized while of n-MOS in diagram, the example that transistor 2425 and 2426 also provides the equivalence of bipolar junction transistor among the present invention to use.In addition, provide one or more bias currents equally, as use (x) generator 515 of the electric current I in response to parameter same as discussed previously or use one or more other to fix or variable current source.Frequency controller module (480,485, have coefficient register 455 and 495) and frequency calibration module (460, have coefficient register 465) to stride node A and B and capacitor 2415 as shown in the figure in parallel or to stride node A ' and B ' and capacitor 2410 in parallel or stride node A ' ' and B ' ' is in parallel with capacitor 2430, or any combination of these three kinds of structures, and same such operation as discussed previously.In addition, as discussed previously equally, different reactance (inductor 2420, capacitor 2410,2415 and 2430) can be implemented as fixing or variable reactance.
Figure 35 for spendable according to the present invention, have difference, altogether collection is examined the circuit diagram of the 7th exemplary L C oscillator 2505 of complete minor structure (or layout).As shown in the figure, device 2500 comprise have difference, altogether collection is examined the 7th exemplary L C oscillator 2505 of complete minor structure (or layout) and previous in frequency controller and the frequency calibration module described in two balanced structures of Fig. 4.Output frequency f 0At node 470 EWith 475 EBetween obtain, described node is equivalent to previous described node 470 and 475, and all references in alternative accompanying drawing and this specification.
One or more bias currents are provided, as use (x) generator 515 of the electric current I in response to parameter same as discussed previously or use one or more other to fix or variable current source.Frequency controller module (480,485, have coefficient register 455 and 495) and frequency calibration module (460, have coefficient register 465) to stride node A and B and capacitor 2515 as shown in the figure in parallel or to stride node A ' and B ' and capacitor 2510 in parallel or stride node A ' ' and B ' ' is in parallel with capacitor 2530, or any combination of these three kinds of structures, and same such operation as discussed previously.In addition, as discussed previously equally, different reactance (inductor 2520, capacitor 2510,2515 and 2530) can be implemented as fixing or variable reactance.
Figure 36 is the circuit diagram of the 8th spendable according to the present invention, as to have single-ended Hartley structure (or layout) exemplary L C oscillator 2605.As shown in the figure, device 2600 comprises the 8th exemplary L C oscillator 2605 with single-ended Hartley structure (or layout) and the part of previous described frequency controller and frequency calibration module.Equally, because oscillator 2605 is single-ended but not difference, frequency controller and frequency calibration module (485,460) only are connected to a main line (node 470 F), rather than have two balanced structures of Fig. 4.As shown in the figure, output frequency f 0At node 470 FWith 475 FBetween obtain, described node is equivalent to previous described node 470 and 475, and all references in alternative accompanying drawing and this specification.(in addition, when frequency controller and frequency calibration module (485,460) were shown between the earth potential on node and the node 475F, frequency controller and frequency calibration module (485,460) also were regarded as striding node 470 FAnd V DDBetween capacitor 2610 parallel connections, be equivalent to AC ground connection.)
Transistor 2625 can be connected to fixing or change bias voltage.In addition, also provide bias current, as use (x) generator 515 of the electric current I in response to parameter same as discussed previously or use another to fix or variable current source.Same such operation the as discussed previously of frequency controller module (480,485, have coefficient register 455 and 495) and frequency calibration module (460, have coefficient register 465).In addition, as discussed previously equally, different reactance (inductor 2615 and 2620, capacitor 2610) can be implemented as fixing or variable reactance.In the exemplary embodiment, resistance 2630 also can be fixing or changes in resistance.
Compare Figure 33 and 36, clearly, the Hartley structure can be by being derived from the Clopitts structure to the inductor changeover condenser and to capacitor conversion inductor.Therefore, refer again to Figure 34 and 35, those skilled in the art will obviously find out, no matter difference Hartley oscillator structure is cobasis or common collection type, all can examine capacitor and the inductor finished in the minor structure by difference shown in the conversion and form.Thereby difference Hartley oscillator structure does not illustrate separately.
Figure 37 is the circuit diagram of the 9th spendable according to the present invention, as to have single-ended Pierce structure (or layout) exemplary L C oscillator.As shown in the figure, device 2700 comprises the 9th exemplary L C oscillator 2705 with single-ended Pierce structure (or layout) and the part of previous described frequency controller and frequency calibration module.Equally, because oscillator 2705 is single-ended but not difference, frequency controller and frequency calibration module (485,460) only are connected to a main line (node 470 G), rather than have two balanced structures of Fig. 4.As shown in the figure, output frequency f 0At node 470 GWith 475 GBetween obtain, described node is equivalent to previous described node 470 and 475, and all references in alternative accompanying drawing and this specification.In addition, frequency controller and frequency calibration module (485,460) are striden node A and B and capacitor 2710 as shown in the figure and are connected in parallel, or stride node A ' and B ' and be connected in parallel, or be connected in parallel with the two simultaneously (stride respectively node A and B and capacitor 2710 in parallel and stride node A ' and B ' is in parallel with capacitor 2715) with capacitor 2715.
Oscillator 2705 comprises inductive load 2720, and for example, it can be inductor or the inductor (present total inductance) in parallel with capacitor, and equally as previously mentioned, it can be embodied as fixing or variable load.Inductive load 2705 is in parallel with phase inverter 2725 and resistance 2730.Same such operation the as discussed previously of frequency controller module (480,485, have coefficient register 455 and 495) and frequency calibration module (460, have coefficient register 465).In addition, as discussed previously equally, different electric capacity 2710 and 2715 can be implemented as fixing or variable capacitance.In the exemplary embodiment, resistance 2730 also can be fixing or changes in resistance.
It should be noted that any layout in the Different L C oscillator layout can be implemented so that orthohormbic structure (or layout) to be provided, it can use with frequency compensation according to the present invention (changing for temperature, technique change and other parameter).For example, two LC oscillator interconnections mutually (and are used frequency controller module (480,485, have coefficient register 455 and 495) and frequency calibration module (460, have coefficient register 465) structure suitably, so that have 90 ° of phase relations a plurality of first reference signals of (0 °, 90 °, 180 ° and/or 270 °) to be provided).
Figure 38 is the circuit diagram of spendable exemplary active inductor 2910 structures according to the present invention.Use the illustrated while of bipolar junction transistor at active inductor 2910, equivalent electric circuit can use the CMOS transistor of any kind to obtain.Active inductor 2910 can be used for any inductor or the inductive load of any LC oscillator described herein or its equivalent, and the saving of IC area can be provided.Shown in active inductor 2910 be connected to the other parts of oscillator usually at node D.Bias current also is provided, as uses same foregoing electric current I (x) generator 515 or use another to fix or variable current source in response to parameter.In addition, active inductor 2910 illustrates as an example and unrestricted one other active inductor circuit also can use equivalently, comprises transistor and circuit structure with other type.
Those skilled in the art will recognize that, can carry out numerous variations above-mentioned different exemplary L C oscillator embodiment.For example, different amplifiers can be implemented in many ways, as only having the p channel transistor, only having a combination of n channel transistor or p as shown in the figure and n channel transistor.In addition, different amplifiers can have different circuit positions and structure with current mirror with respect to different resonators.Single or multiple inductor or capacitor change and can use equivalently.Different layouts can be symmetrical or asymmetric, complementation or incomplementarity or interconnection or non-interconnection layout.All such variations all are considered as equivalence also within the scope of the present invention.
Refer again to Figure 21, frequency controller 215,349,1415 of the present invention can comprise one or more following assemblies: (1) transconductance modulator 1410 (as 410,415 and Fig. 6-8 as shown in embodiment), in the exemplary embodiment, it also can and can or be connected to and keeps amplifier 305; (2) the variable element adjuster 1425, with in response to any selected parameter such as temperature, manufacturing process variations, change in voltage or frequency adjustment resonance frequency f 0, as different controlled capacitance module 485,635,1505 or controlled reactance modules 1305,1805; (3) technology (or other parameter) adjuster or compensator 1430 are as process variation compensator 425,760,860 or controlled reactance modules 1305,1805; (4) voltage variation compensator 380,1455; And/or (5) operating period (time) variation compensator (or adjuster) 365,1460.Those skilled in the art will recognize that, difference division between mutual conductance module 1410, variable element adjuster 1425 or technology (or other parameter) adjuster or compensator 1430 or other compensator and the adjuster is arbitrarily and does not limit the scope of the invention, because wherein each all can make in response to above-mentioned any parameter, and each (for example all can be used for above-mentioned any purpose, variable element module 1425 can be used for compensating manufacturing process variations etc., rather than variations in temperature).In addition, according to selected enforcement, one or more coefficient registers 1435 (as 455,465,495) can be used for preserving any coefficient in above-mentioned a plurality of coefficient.In alternative, described coefficient may not need, changing voltage or electric current or static or dynamically directly be applied for control signal.
Equally in the exemplary embodiment, these different assemblies can comprise transducer 1440,1815 (as yI (x) (or I (T)) generator 415,515), and perhaps transducer can be provided as independent assembly, as is connected to the current source of diode, as mentioned above.Equally, according to selected embodiment, can comprise that also A/D converter 1445 and control logic 1450,1810 are to provide selected FREQUENCY CONTROL.
In a word, exemplary embodiment of the present invention is provided for the device of the FREQUENCY CONTROL of resonator, and resonator is suitable for providing first signal with resonance frequency.Described device comprise be suitable in response at least one parameter in a plurality of parameters provide secondary signal as control voltage transducer (1440,1815); And being connected to transducer and the frequency controller (215,1415) that can be connected to resonator, frequency controller is suitable for revising resonance frequency in response to secondary signal.A plurality of parameters are variable and comprise in the following parameter at least one: temperature, manufacturing process, voltage, frequency and operating period.
In the exemplary embodiment, frequency controller also is suitable for revising reactance or the impedance component that is connected to resonator in response to secondary signal, as revise the total capacitance (Fig. 9) of resonator in response to secondary signal, will fix or variable capacitance (635) is connected to resonator or is connected with its disconnection; By variable reactor being transformed into the effective reactance that selected control voltage modifications is connected to the variable reactor of resonator, or equivalently, revise the inductance of resonator in response to secondary signal, as by fixing or variable inductance is connected to resonator or is connected with its disconnection; Or revise the resistance (or other impedance) of resonator in response to secondary signal, as by resistance being connected to resonator or being connected with its disconnection.
In the exemplary embodiment, frequency controller also can comprise: the coefficient register that is suitable for preserving more than first coefficient; And has first array (635) that is connected to coefficient register and can be connected to a plurality of switchable capacitive module of resonator, each switchable capacitive module has fixed capacity 615 and variable capacitance 620, and each switchable capacitive module is transformed into control voltage in response to the corresponding coefficient in more than first coefficient with conversion between fixed capacity and variable capacitance and with each variable capacitance.A plurality of switchable capacitive module can be the modules of binary weighting.Frequency controller also can comprise second array 650 that has a plurality of switchable resistive module that are connected to coefficient register and also have capacitance module, capacitance module and a plurality of switchable resistive module are also connected to node 625 so that control voltage to be provided, and each switchable resistive module is controlled voltage node 625 in response to the corresponding coefficient in more than second coefficient of preserving in the coefficient register so that switchable resistive module is transformed into.In selected embodiment, transducer also comprises the current source 655 in response to temperature, and wherein current source is connected to second array is striden at least one switchable resistive module in a plurality of switchable resistive module with generation control voltage by current mirror 670.Equally, in selected embodiment, current source has at least one CTAT, PTAT or PTAT 2Structure (Fig. 7 A-7D).In addition, each switchable resistive module in a plurality of switchable resistive module has different temperature responses to selected electric current.
In other exemplary embodiment, transducer is temperature sensor and changes secondary signal in response to variations in temperature.Selected embodiment also can comprise the analog to digital converter 1445 that is connected to temperature sensor providing digital output signal in response to secondary signal, and comprises that control logic piece 1450 is to be converted to digital output signal more than first coefficient.
In other exemplary embodiment, frequency controller also comprises process variation compensator 320,425,760 or 860, and process variation compensator can be connected to resonator and be suitable for revising resonance frequency in response to the fabrication process parameters in a plurality of parameters.Process variation compensator also can comprise the coefficient register that is suitable for preserving a plurality of coefficients; And array 760 with a plurality of switchable capacitive module that are connected to the coefficient register resonator, each switchable capacitive module has first fixed capacity 750 and second fixed capacity 720, each switchable capacitive module in response to the corresponding coefficient in a plurality of coefficients between first fixed capacity and second fixed capacity, to change.In other exemplary embodiment, process variation compensator also can comprise the coefficient register that is suitable for preserving a plurality of coefficients; And the array 860 with switchable variable capacitive module 865 of a plurality of binary weightings that are connected to the coefficient register resonator, each switchable variable capacitive module in response to the corresponding coefficient in a plurality of coefficients between first voltage and second voltage, to change.
In other exemplary embodiment, frequency controller also comprises the coefficient register that is suitable for preserving more than first coefficient; And has first array 1500 of the capacitance module 1505 of a plurality of convertible, the binary weighting that is connected to coefficient register and can be connected to resonator, each switchable capacitive module has variable capacitance 1515, each switchable capacitive module in response to the corresponding coefficient in more than first coefficient with the selected control voltage of variable capacitance conversion (1520) in a plurality of control voltages.Transducer can comprise the current source in response to temperature, frequency controller also can comprise having by current mirror (670,510,520) be connected to second array 1600 of a plurality of resistive module 1605 of current source (655), a plurality of resistive module are suitable for providing a plurality of control voltages, and each resistive module in wherein a plurality of resistive module has different responses to temperature and is suitable for electric current in response to current source corresponding control voltage in a plurality of control voltages is provided.
In other exemplary embodiment, the device that is used for the FREQUENCY CONTROL of resonator comprises the coefficient register that is suitable for preserving more than first coefficient; And first array (1300,1800) with a plurality of switchable reactance module (1305,1805) that are connected to the coefficient register resonator, each switchable resistive module is transformed into resonator to revise resonance frequency in response to the corresponding coefficient in more than first coefficient with corresponding reactance.Corresponding reactance can be fixing or variable inductance, fixing or variable capacitance or its any combination.Corresponding reactance can be changed between resonator and control voltage or earth potential, and control voltage can be determined in response to temperature by current source.For example, corresponding reactance is to change between variable reactance and the selected control voltage in resonator and a plurality of control voltage.In selected embodiment, more than first coefficient by transducer in response at least one parametric calibration in a plurality of variable elements such as temperature, manufacturing process, voltage and the frequency or determine.
In the exemplary embodiment, a plurality of switchable reactance module also can comprise the switchable capacitive module 640 of a plurality of (635) binary weighting, each switchable capacitive module has fixed capacity and variable capacitance, and each switchable capacitive module is changed between fixed capacity and variable capacitance in response to the corresponding coefficient in more than first coefficient and each variable capacitance is transformed into control voltage.Described device also can comprise the current source 655 in response to temperature; And has second array that is connected to coefficient register and can be connected to a plurality of switchable resistive module 675 of current source selectively, second array also has capacitance module 680, capacitance module and a plurality of switchable resistive module are also connected to node 625 so that control voltage to be provided, each switchable resistive module is transformed into the control voltage node in response to the corresponding coefficient in more than second coefficient of preserving in the coefficient register with switchable resistive module, and each switchable resistive module in wherein a plurality of switchable resistive module has different temperature responses to the selected electric current of current source.
In other exemplary embodiment, a plurality of switchable reactance module also comprise the switchable capacitive module 1505 of a plurality of 1500 binary weightings, each switchable capacitive module has variable capacitance 1515, each switchable capacitive module in response to the corresponding coefficient in more than first coefficient with the selected control voltage of variable capacitance conversion (1520) in a plurality of control voltages.Described device also can comprise the current source 655 in response to temperature; And have by current mirror (670,510,520) be connected to second array of a plurality of resistive module 1605 of current source, a plurality of resistive module are suitable for providing a plurality of control voltages, and each resistive module in wherein a plurality of resistive module has different responses to temperature and is suitable for electric current in response to current source corresponding control voltage in a plurality of control voltages is provided.
In other exemplary embodiment, a plurality of switchable reactance module also can comprise a plurality of 760 binary weightings of being connected to the coefficient register resonator, switchable capacitive module, each switchable capacitive module has first fixed capacity 750 and second fixed capacity 720, and each switchable capacitive module is changed between first fixed capacity and second fixed capacity in response to the corresponding coefficient in a plurality of coefficients.In other exemplary embodiment, a plurality of switchable reactance module also can comprise the switchable variable capacitive module 865 of a plurality of 860 binary weightings that are connected to the coefficient register resonator, each switchable variable capacitive module in response to the corresponding coefficient in a plurality of coefficients between first voltage and second voltage, to change.
In the exemplary embodiment, according to the inventive system comprises the resonator 310,405 that is suitable for providing first signal with resonance frequency; And be connected to resonator and be suitable for revising the temperature compensator 315 of resonance frequency in response to variations in temperature.Resonator is at least one in the following resonator: LC accumulator resonator, ceramic resonator, mechanical resonator, micro-electro-mechanical resonator or thin film bulk acoustic resonator that inductor (L) and capacitor (C) are configured to.Described device also can comprise the negative transconductance amplifier 410 that is connected to resonator and temperature compensator, and wherein temperature compensator also is suitable for revising electric current in response to variations in temperature by negative transconductance amplifier.Temperature compensator also can comprise the current source 415,515,655 in response to variations in temperature.
In other exemplary embodiment, temperature compensator also comprises: be suitable for providing the current source 415,515,655 in response to the electric current of variations in temperature; Be suitable for preserving the coefficient register of more than first coefficient; Be connected to a plurality of resistive module 675,1605 of resonator and current source, at least one resistive module in a plurality of resistive module is suitable for providing control voltage or a plurality of control voltage; And a plurality of switchable reactance module (1305,1805,635,1505), be connected to resonator and current source and can be connected at least one resistive module in a plurality of resistive module selectively.
In other exemplary embodiment, the invention provides the frequency controller of the FREQUENCY CONTROL that is used for resonator, comprising: the coefficient register that is suitable for preserving more than first coefficient and more than second coefficient; Be suitable for providing current source 415,515,655 corresponding to the electric current of temperature; Have a plurality of switchable resistive module 675,1605 that are connected to coefficient register and first array that also has capacitance module, first array also is connected to current source by current mirror and strides at least one control voltage of at least one switchable resistive module in a plurality of switchable resistive module with generation, each switchable resistive module in response to the conversion of the coefficient of correspondence in more than second coefficient switchable resistive module to provide control voltage to the control voltage node; And second array with switchable capacitive module 640 of a plurality of binary weightings that are connected to the coefficient register resonator, each switchable capacitive module has fixed capacity and variable capacitance, and each switchable capacitive module is changed between fixed capacity and variable capacitance in response to the coefficient of correspondence in more than first coefficient and each variable capacitance is transformed into the control voltage node.
Refer again to Fig. 3 and 4, clock generator and/or timing/frequency reference (100,200 or 300) also can comprise frequency calibration module (325 or 430).This frequency calibration module is the theme of other patent application, but its Premium Features are briefly described below.Figure 13 is according to the example frequency calibration module 900 of the present invention high level block diagram of (it can be used as module 325 or 430).Frequency calibration module 900 comprises digital frequency divider 910, the frequency detector 915 based on counter, digit pulse counter 905, reaches calibration register 930 (it also can be used as register 465).Use test IC, from the output signal of clock generator (100,200 or 300) by frequency division (910) and with frequency detector 915 in known reference frequency 920 relatively.Is soon or slow according to clock generator (100,200 or 300) with respect to described reference, descends or the rising pulse is provided for pulse counter 905.Based on these results, more than the 3rd conversion coefficient r 0R (y-1)Be determined, and clock generator (100,200 or 300) is calibrated to selected reference frequency.Again, each IC also can calibrate separately and test.
Refer again to Fig. 2,3 and 4, one of skill in the art will appreciate that with PVT change to keep the oscillator of pin-point accuracy, low jitter, self-excitation and self-reference to be described, thus provide can node 470 and 475 that obtain, have optional and adjustable resonance frequency f 0Difference, sinusoidal signal in fact.For many application, this signal is enough and can directly use (and can be on the bus 125 or 135 of Fig. 1, on the line 250 of Fig. 2 or on the line 350 of Fig. 3 or the main line of Fig. 4 or the output between circuit 470 and 475).For example, this signal can be used as regularly or reference frequency.According to the present invention, can there be other application, comprise that clock (square wave in fact), frequency division, low latency frequency inverted takes place, reaches model selection, as described below.
Figure 14 is according to exemplary frequency divider of the present invention and square-wave generator 1000 and has the block diagram that exemplary glitch suppresses the exemplary asynchronous frequency selector 1050 of module 1080.As mentioned above, frequency divider and square-wave generator 1000 can be included in module 220 and/or 330 or comprise module 220 and/or 330, and frequency-selector 1050 (have or do not have glitch suppress module 1080) can be included in module 205 and/or 335 or comprises module 205 and/or 335.
With reference to Figure 14, the output signal of oscillator promptly has resonance frequency f 0Difference and sinusoidal signal in fact, as on the line 250 of Fig. 2 or on the line 350 of Fig. 3 or the main line of Fig. 4 or the output between circuit 470 and 475, be transfused to frequency divider and square-wave generator 1000.The frequency of this essence sinusoidal signal is divided into m different frequency by arbitrary or a plurality of arbitrary value N and (comprises f 0, suitable place), and be converted to the essence square-wave signal, thus cause having a plurality of essence square-wave signals of m+1 different usable frequencies, i.e. output frequency f on circuit or the bus 1020 0, f 1, f 2... f mAny signal that has in these essence square-wave signals of m+1 different usable frequencies can be selected asynchronously by exemplary asynchronous frequency selector 1050, and as shown in the figure, described frequency-selector can be embodied in multiplexer.Selection with any signal in these essence square-wave signals of m+1 different usable frequencies can be by a plurality of selection circuit (S mS 0) 1055 finish, thereby provide essence square-wave signal, i.e. output on the circuit 1060 with institute's selected frequency.
As the part that asynchronous frequencies is selected, glitch suppresses also to suppress module 1080 by glitch to be provided, and it can be specialized in many ways, comprises by using the one or more exemplary d type flip flop (DFF) shown in Figure 14.Glitch can appear in the asynchronous frequencies transition, wherein or low state or high state be not held time enough and can in the circuit that drives by clock signal, cause metastability.For example, it is the high state of second frequency that the asynchronous frequencies transition can cause the low state transition of first frequency, causes voltage spike or glitch when the second frequency high state is about to become low state again.For avoiding possible glitch to be provided as the part of clock signal, selected essence square-wave signal (having institute's selected frequency) offers the DFF1065 that hold mode is provided on circuit 1060; If glitch occurs, it will be held till clock edge triggers DFF.For avoiding glitch to appear at clock edge, DFF can be lower than maximum usable frequency and carry out clock control, maybe can use one or more other DFF (as DFF1070), because during waiting for another clock signal, the Q of DFF1065 output will stabilize to first state (high or low) or second state (low or high), as or electric power or ground connection main line.The inventor has shown that 2 DFF are promptly enough, and other DFF can increase as required, will cause changing the stand-by period increase but have other DFF.In the illustrated while of usage example DFF, other trigger or counter also can use, and those skilled in the art will recognize that and will realize countless other equivalent execution modes of this result, and all these change all within the scope of the present invention.
Exemplary low latency frequency inverted according to the present invention as shown in Figure 15.Figure 15 still is the explanation of " essence " of the present invention square wave, and it represents rational variation for the typical case of the actual square wave that uses in the different layouts, under its corresponding high and low state towards and upper punch (and not being the perfection " straight " of textbook example).A among Figure 15 partly shows the asynchronous glitch-free conversion from 1MHz to 33MHz, B partly show record from 4MHz to 8MHz, then to 16MHz, afterwards to the glitch-free conversion of 33MHz.
Refer again to Figure 14, frequency divider and square-wave generator 1000 can countless ways be implemented, and as difference or single-ended, illustrated frequency divider only is exemplary.Because the output of the oscillator shown in Fig. 4 is difference output (striding line or trunk 470 and 475), first frequency divider 1005 also is differential divider and complementary output is provided, give oscillator and keep phase alignment to present constant in fact load, and be that quick frequency divider is to support the frequency of high frequency such as GHz scope.In addition, any tension and relaxation mode oscillation of refusing first frequency divider 1005 may be necessary or suitable.Second frequency divider 1010 is differential divider and any any frequency division (removing with M) is provided also, as divided by integer, 2 multiple, rational or any other amount or number.The layout or the structure of described frequency divider are well known in the art, and any described frequency divider all can use.For example but unrestricted, described frequency divider can be a succession of (multistage) counter or trigger 1075, those triggers as shown in Figure 16, as second differential divider 1074, its power or multiple by 2 provides frequency division, the output of each section provides different frequencies, and also is provided for the clock signal of next section and feeds back to its oneself input, as shown in the figure.As shown in the figure, afterwards, a plurality of frequencies can be used for the output on circuit or the bus 1020, as f 0/ 2, f 0/ 4, the rest may be inferred, up to f 0/ 2 NIn addition, as shown in the figure, also can use buffer 1085 from oscillator to first frequency divider 1005, so that the voltage that is enough to drive first frequency divider 1005 to be provided, and between second frequency divider, 1010 multistages, use buffer, can influence also that signal rises and the load variations that becomes with state of fall time to isolate.
It shall yet further be noted that and use different triggers that the essence square wave also is provided that because any essence sinusoidal signal has been provided to the clock control trigger, its output is pulled to high or low voltage then.Also can use other square-wave generator, square-wave generator as known in the art.In the embodiment shown, for keeping phase alignment, differential signal is held by last division.In the end after the frequency division, (as 50: the 50) duty ratio of in fact evenly dividing to provide is provided a plurality of signals (each signal has different frequency) (in module 1015), and the time that makes signal be in first (height) attitude equals the time that this signal is in second (low) attitude in fact.
Figure 17 is a block diagram of selecting module according to exemplary patterns of the present invention.The high performance reference of pin-point accuracy such as clock generator of the present invention (100,200 or 300) are unnecessary under some situation, as under low-power, standby mode.Under these situations, according to the present invention, perhaps do not provide clock output, clock 1105 outputs of low-power, reduction performance perhaps are provided.For example, under quite low frequency, suitable, low power capabilities that the low performance ring oscillator can provide.As shown in Figure 17, for these conditions, the output of low-power oscillator 1105 can selected (by multiplexer 1100) and as clock output offers other circuit.Yet in higher frequency, described low performance oscillator consumes much more power, usually obviously more than oscillator of the present invention." break even " point that becomes with frequency is arranged usually, and clock generator (100,200 or 300) provides higher performance and lower power consumption thereafter, and can selected (by multiplexer 1100) and as clock output offers other circuit.Therefore, clock generator (100,200 or 300) also can be used for providing low-power mode.
In addition, use mode selector 1110, also can select other pattern, as no power mode, rather than only low frequency or sleep pattern, clock generator under this pattern (100,200 or 300) can be restarted quite apace, or is subjected to the pattern of impulse action, and wherein clock generator (100,200 or 300) can regularly or irregularly be burst repeatedly or stop with interval and restart.Different reference models is as described below.
Than prior art, this that uses clock generator of the present invention and/or timing/frequency reference (100,200 or 300) is subjected to the impulse action clock control that power save is provided.During specific bursting, consume in more power, because clock has quite high frequency, more instruction is handled in this interval, during non-pulse or interruption intervals, do not have or have only limited power dissipation afterwards, thereby cause higher MIPS/mW than the clock of continuous operation.On the contrary, because quite long start-up time and the locking of prior art clock, the described clock control that is subjected to impulse action causes the prior art power consumption more and efficient is lower.
Figure 18 is the block diagram that is used for the example synchronization module 1200 of second oscillator according to of the present invention.As mentioned above, clock generator and/or timing/frequency reference (100,200 or 300) can provide reference model with synchronous other oscillator or clock, and it can not be a low-power yet, as second oscillator 1210 (as annular, tension and relaxation or phaseshift oscillator).The output signal of clock generator and/or timing/frequency reference (100,200 or 300) is also by frequency division is to form a plurality of available reference frequencies as required, and a certain reference frequency is selected from this a plurality of frequencies.This can use above-mentioned module to realize, as by use existing frequency divider (220,330,1000, for example), provide reference signal from frequency-selector 1050 (or 205 or 335) then.For example, with reference to figure 3, mode selector 345 can be selected reference model and provide the output reference signal to second oscillator (having synchronization module) 375 from frequency-selector 335.Afterwards, synchronization module such as PLL or DLL1205 are used for the reference signal that is provided by clock generator and/or timing/frequency reference (100,200 or 300) is provided the output signal from second oscillator 1210.Except the continuous synchronization pattern, also can provide be subjected to impulse action synchronously, wherein clock generator and/or timing/frequency reference (100,200 or 300) provide the output that is subjected to impulse action, and during the interval that occurs in these pulses synchronously is sync interval.
Figure 19 is the flow chart according to illustrative methods of the present invention, and provides the summary of usefulness.Method is with the beginning of beginning step 1220, as starting by clock generator and/or timing/frequency reference (100,200 or 300).It should be noted that in Figure 19, to be illustrated as in the consecutive steps that these steps can any order occur, and can occur simultaneously with clock generator and/or timing/frequency reference (100,200 or 300) operation usually.With reference to Figure 19, the resonance signal with resonance frequency produces in step 1225, as passing through LC accumulator 405 or resonator 310.In step 1230, resonant frequency response is regulated in temperature, and as passing through temperature compensator 315, it regulates electric current and frequency.In step 1235, resonant frequency response is regulated in manufacturing process variations, as passing through process variation compensator 320.As mentioned above, step 1235 can be performed as first calibration steps, is the adjustment of step 1230 afterwards.In step 1240, the resonance signal with resonance frequency is divided into a plurality of secondary signals with corresponding a plurality of frequencies, and as passing through frequency divider 330 or 1000, wherein a plurality of frequencies are equal to or less than resonance frequency in fact.In step 1245, output signal is selected from a plurality of secondary signals, as passing through frequency-selector 335 or 1050.According to selected embodiment or pattern, selected output signal can directly be provided as reference signal.
In other embodiments, when being difference rather than single-ended signal when output signal, and when resonance signal is the essence sinusoidal signal, in step 1250, thereby being converted to difference, essence sinusoidal signal as required, described method continuation has height and the single-ended essence square-wave signal of low duty ratio, feasible use module 330 or the 1000 generation clock output signals that equate in fact.In step 1255, operational mode is also selected from plurality of operating modes, and as by using mode selector 225 or 345, wherein plurality of operating modes can be selected from down group: clock module, timing and frequency reference pattern, power save mode and be subjected to the impulse action pattern.When select in step 1255 be reference model the time, in step 1260, described method proceeds to step 1265, with in response to synchronous the 3rd signal of output signal (as from second oscillator), as shown in Figure 18.After step 1260 or 1265, described method finishes or repeats (continuation) (continuing operation as clock generator and/or timing/frequency reference (100,200 or 300)), returns step 1270.
Figure 39 is the block diagram according to the second example system embodiment 1195 of the present invention.As shown in the figure, second example system 1195 comprises aforesaid clock generator (regularly/frequency reference) (100,200,300) and is used for any kind of any function, application or purpose or the second circuit 180 of kind, for example reaches the processor 1275 as giving a definition as shown in the figure.Second circuit 180 also can comprise memory 1280, be used for the interface 1285 of input and output (I/O) and be used for other circuit unit of any selected application or function.Second example system 1195 is presented as single IC for both usually, one or more first reference signals as one or more system clocks or reference are provided, and itself and other assembly integrates and it is without any need for external reference or clock such as crystal oscillator reference.For example, clock/reference (100,200,300) self-excitation and be not locked to any reference clock or signal, and provide reference clock or signal give other, second circuit 180.
Second example system 1195 also can be embodied as a plurality of integrated circuits that connect by the bonding wire in the same IC shell.For example, clock generator (regularly/frequency reference) (100,200,300) can be embodied on the IC, second circuit 180 is embodied on the 2nd IC, the two interconnects by one or more bonding wire, the one IC (clock) will offer the 2nd IC (second circuit 180) as one or more first reference signals of one or more system clocks or reference, thereby with clock or with reference to a part that is provided as single package assembling, and without any need for external reference or clock such as crystal oscillator reference.
As shown in Figure 39, except clock generator (regularly/frequency reference) (100,200,300), second example system 1195 also comprises the second circuit of one or more types, as one or more processors 1275, and may also comprise I/O interface (or other I/O device) 1285 and memory 1280.In these assemblies each receives one or more first reference signals, usually as one or more clock control signals.In second example system 1195, I/O interface 1285 can be embodied as interface known in the art or that be about to know, between processor 1275, memory 1280 and any passage, bus, input and output device, mechanism described herein and medium (not illustrating separately), to provide data communication, comprise wireless, optics or wire communication, it uses any available standards, technology or medium, without any restriction.For example, when second example system 1195 during as computer processor, I/O interface 1285 is suitable for providing data communication between itself and one or more bus such as pci bus, PCI high-speed bus, USB (USB1 or USB2) etc.In addition, I/O interface 1285 can be provided to the interface of any CD or disc driver, or to the interface of the communication port that is used for communicating through network, thereby provide communication with any type of medium or communicator, as ethernet port is provided.Equally, for example, I/O interface 1285 can provide all signalings and physical interface function, for example but unrestricted, export as input of the data between impedance matching, the PERCOM peripheral communication circuit that is connected to network or passage (as Ethernet, T1 or isdn line) and internal server or the computer communication bus (as one of different PCI or usb bus) and data.In addition, according to selected embodiment, I/O interface 1285 (or processor 1275) also can be used for providing data link layer and medium access controlled function.
According to selected embodiment, memory 1280 can any amount of form embody, be included in any computer or other the machine-readable data storage medium, be used for information such as computer-readable instruction, data structure, the storage of program module or other data or the storage arrangement of communication or other storage or communicator, no matter be current known or be about to available, include but not limited to disc driver, optical drive, disk or tape drive, hard disk drive, other machine-readable storage or memory medium such as floppy disk, CDROM, CD-RW, digital versatile disc (DVD) or other optical drive, memory integrated circuit (IC), or the memory portion of integrated circuit (as residing in the interior memory of processor IC), no matter volatibility or nonvolatile memory, no matter can delete or the unsuppressible-suppression memory, include but not limited to RAM, FLASH, DRAM, SDRAM, SRAM, MRAM, FRAM, ROM, EPROM or E 2The memory of PROM or any other type, storage medium or data storage device or circuit, it can be known or be about to know.In addition, described computer-readable media comprises any type of communication medium, it is with in computer-readable instruction, data structure, program module or present data-signal of other data volume or the conditioning signal, as electromagnetism or optical carrier or other transmission mechanism, comprise any information medium of making a copy for, it can be coded in data or out of Memory in the wired or wireless signal, comprises electromagnetism, optics, sound wave, RF or infrared signal etc.
Second example system 1195 also comprises the treatment circuit of one or more types, and as one or more processors 1275, it can be monokaryon or multinuclear, universal or special processor and the function that is suitable for carrying out any kind.As term " processor " this uses and defines, processor 1275 can be the circuit of any kind, be suitable for carrying out the function of any kind or kind, use or other purpose, and can comprise the use of single IC for both (IC), maybe can comprise a plurality of integrated circuits or other connection, arrange or be grouped in the use of assembly together, as microprocessor, digital signal processor (DSP), controller or microcontroller, parallel processor, polycaryon processor, conventional IC, application-specific integrated circuit (ASIC) (ASIC), but field programmable gate array (FPGA), self adaptation is calculated IC, associated memory is (as RAM, DRAM and ROM), and other IC and assembly.Therefore, as used herein, term processor means with should be understood to be equal to and comprises that single IC or conventional IC layout, ASIC, processor, microprocessor, controller, FPGA, self adaptation calculate IC or carry out other integrated circuit grouping of any proper function, and the memory that is associated such as microprocessor memory or other RAM, DRAM, SDRAM, SRAM, MRAM, ROM, FLASH, EPROM or E 2PROM.Processor (as processor 1275) and relational storage can be suitable for or (through programming, microcode, FPGA interconnection or hardwired) is configured to carry out the relevant any function of any selected application as described below and second example system 1195 (or the 3rd, the 4th or the 5th example system as described below).For example, any function or method can be used as batch processing instruction or other code (or equivalent or other program) and programme and be kept in processor 1275 and relational storage (and/or memory 1280) and other equivalent elements, carry out when the processor operation (promptly switch on and turn round) being used for subsequently.Be equal to ground, when processor 1275 can be embodied as FPGA, conventional IC and/or ASIC in whole or in part, FPGA, conventional IC or ASIC also can be designed, configuration and/or hardwired to be to implement any selected function or method.For example, processor 1275 can be embodied as the arrangement of microprocessor, DSP and/or ASIC, is referred to as " processor ", and selected function is programmed, designs, revises or be configured to implement to these assemblies respectively, as communication function, data processing function etc.
For example but unrestricted, processor 1275 can be embodied as microprocessor, digital signal processor, controller, microcontroller, USB (USB) controller, periphery component interconnection (PCI) controller, periphery component interconnection (PCI-e) controller, live wire controller, AT annex (ATA) interface controller, integrated driving electronics (IDE) controller, SCS(Small Computer System Interface) controller fast.In other embodiments, processor 1275 can be implemented to the controlled function that other form is provided, as control device of the tv, Local Area Network or ethernet controller, Video Controller, Audio Controller, modem processor or controller, cable modem controller or processor, multimedia controller, MPEG controller such as MPEG-1 (CD-Video, MP3), MPEG-2 (Digital Television, DVD), MPEG-4 (be used for fixing and multimedia that the mobile network uses), MPEG-7 (description of audio frequency and content viewable and search), MPEG-21 (multimedia framework).In other embodiments, when clock/reference has been implemented to the frequency accuracy that provides effective and stable, processor 1275 can be implemented to provides communication function, as is used for the one or more communication controlers of mobile communication (mobile communication controller, IEEE 802.11 controllers, the GSM controller, the GPRS controller, the PCS controller, the AMPS controller, the CDMA controller, the WCDMA controller, the spread-spectrum controller, the WLAN controller, multi-form IEEE 802.11 controllers etc.) or the one or more communication controlers that are used for non-moving communication (as the DSL controller, t1 controller, the ISDN controller) or other multimedia or other communication controler.
Example above continuing to use, institute's selected frequency can comprise 12,30,48 or the 480MHz that is used for USB controller (USB1 or USB2); Be used for 33 or 66MHz of pci controller or be used for the 6MHz of PCI-e controller, live wire controller, ATA controller or scsi controller; The 10.7MHz that is used for control device of the tv; The 50MHz that is used for Local Area Network or ethernet controller; The 27MHz or the 54MHz that are used for Video Controller; The 24.576MHz that is used for Audio Controller; The 56.448MHz that is used for modem processor; It is suitable for other frequency of above-mentioned different MPEG controller or communication controler.Other frequency also can be selected based on application, as when processor 1275 is used in the computer, selects suitable GHz frequency.
Any way of aforesaid different frequency in can be in many ways determine, no matter directly is provided as the first frequency f of first reference signal by clock generator (regularly/frequency reference) (100,200,300) 0Or one or more second frequencies (through one or more frequency dividers (1000,1010,1074,1218,1219) or lock-in circuit 1204 and other following assembly) of one or more second reference signals.For example, different frequencies can be used as the part of design and manufacturing to be determined, or determines (as by calibration and programming) after manufacturing, or the two exists simultaneously.More specifically, frequency selects to can be used as design and the part made takes place, as the inductor that uses in the LC oscillator by selection clock/reference (100,200,300) and the quantity and the size of capacitor.For example, the size of one or more inductors (as 445) and/or shape can be selected by the proper metal layer mask.As mentioned above, frequency is selected also can take place after manufacturing, and it is undertaken by using aforesaid different calibration and control coefrficient or signal.In addition, as described below, frequency is selected and can be undertaken by disposing one or more lock-in circuits 1204 or frequency divider, as passing through the frequency dividing ratio of selection by programmable counter, the part that it designs and make for IC, or can after manufacturing, programme, equally by using calibration or control coefrficient or signal or being undertaken by frequency divider being converted into or changing out division chain.
Except shown in one or more processors 1275, I/O interface 1285 and the memory 1280, one of skill in the art will appreciate that different example system also can comprise other or different assemblies, and usually will be with selected application change.For example, different application can require other circuit, as except described to I/O interface 1285, also needs different physical layers to implement.
Figure 40 is the block diagram according to the 3rd example system embodiment 1201 of the present invention.As shown in Figure 40, has first frequency (f 0) first reference signal or directly offer processor 1275 (the same) with the example of second circuit 180, or offer the other phase inverter 1196, frequency divider (1000,1074,1218 and/or 1219 (as described below)), lock-in circuit 1204 of being illustrated as and (be illustrated as lock-in circuit 1204 1, lock-in circuit 1204 2..., lock-in circuit 1204 N), and the combination of described frequency divider, lock-in circuit etc. or the second circuit of displacement.This other second circuit is suitable for receiving first reference signal with first frequency and selected frequency f is provided 1, f 2... f NAnd has one or more corresponding second reference signal of any selected phase relation (as paraphase, 90 degree, quadrature etc.).
The 3rd example system 1201 (and following a plurality of other exemplary embodiments) produces a plurality of reference signals, and no matter sine or square-wave signal are as one or more clock signals or frequency reference.Clock/frequency reference (100,200,300) provides first reference signal (to have first frequency f 0) and be connected to one or more lock-in circuits 1204 and (be illustrated as lock-in circuit 1204 as phase-locked loop, delay lock loop, injection locking circuit 1, lock-in circuit 1204 2..., lock-in circuit 1204 N), so that selected frequency f to be provided K+1, f K+2... f NCorresponding a plurality of output signals.Each lock-in circuit in a plurality of lock-in circuits 1204 has the corresponding frequency dividing ratio in a plurality of different frequency dividing ratios.Be in operation, each lock-in circuit 1204 is suitable for phase place, delay or other locks onto first reference signal that clock/frequency reference (100,200,300) provides, and provides second reference signal with output frequency of determining from first frequency and corresponding frequency dividing ratio as output.Each lock-in circuit such as PLL or DLL can implement by well known in the art, reach following PLL 1204 as shown in Figure 43 A
In the exemplary embodiment, the frequency of second reference signal can be a fixed frequency, as fixing by hardwired or configuration frequency divider or frequency dividing ratio during fabrication, it also can be variable frequency, as coefficient (1215) (piece 1215 by control circuit (or logic) or preservation, it can be other circuit of preserving the register of coefficient or control signal being provided) thus the frequency dividing ratio of selecting after manufacturing or programming and regulate lock-in circuit 1204 for the correspondent frequency selection will be further described below.Any coefficient of preserving (1215) also can be the different frequency calibration of preservation in aforesaid register 455,465 and 495 and the part of FREQUENCY CONTROL coefficient.As selection, user's input can not provide by user interface (illustrating separately) as the input that is used for the frequency selection yet.
As above described in conjunction with Figure 14 (frequency divider 1000,1010) and Figure 16 (differential signal frequency divider 1074), as the output signal of the oscillator first reference signal, that come self-clock/frequency reference (100,200,300) of common first frequency also can by frequency division with provide have one or more selected second frequencies one or more second with reference to (or clock) signals.Figure 41 is the block diagram according to the 3rd exemplary frequency divider embodiment 1218 of the present invention, as to be used for asynchronous frequency division.Figure 42 is the block diagram that is used for the 4th exemplary frequency divider embodiment 1219 of synchronization frequency division according to of the present invention.As previously mentioned, for these embodiment, each trigger (or counter) 1214 (is illustrated as trigger 1214 0, 1214 1... 1214 5) frequency division of factor 2 is provided, maybe when being embodied as counter, provide frequency division of whatsoever maximum (the ultimate or limit) number that counter is suitable for counting.Figure 41 shows the structure of the trigger (or counter) 1 214 that asynchronous frequency division is provided.Figure 42 shows the structure of the trigger (or counter) 1214 with other gate logic (AND gate) 1217, and it provides synchronization frequency division.Except shown in the gate logic (AND gate) 1217, it is selected synchronous that the combinational logic circuit of any structure can be used for providing, gate logic (AND gate) 1217 is to be used for an example that removes 8 circuit shown in Figure 42, and all these change all within the scope of the present invention.
Frequency divider as the 3rd exemplary frequency divider 1218 and the 4th exemplary frequency divider 1219, can be connected to the oscillator of different clocks generator (regularly/frequency reference) (100,200,300) embodiment, has the f of being illustrated as thereby provide 2, f 3... f KOne or more second reference signals of corresponding a plurality of second frequencies.Perhaps, frequency divider, as the 3rd exemplary frequency divider 1218 and the 4th exemplary frequency divider 1219, can be the part of lock-in circuit 1204 (as one or more phase-locked loops (PLL), delay lock loop (DLL) or injection locking circuit) that is connected to the oscillator of different clocks generator (regularly/frequency reference) embodiment (100,200,300).Exemplary locking circuit diagram is shown the PLL 1205 among Figure 18.Described lock-in circuit embodiment describes in conjunction with Figure 43 and 44 below.In addition, different frequency divider (1000,1010,1074,1218,1219) also can be connected to one or more lock-in circuits 1204, as shown in Figure 40.
Be used to provide the asynchronous frequency division of one or more output signals and synchronization frequency division all within the scope of the present invention with institute's selected frequency.In addition, frequency division can be in division chain (trigger (or counter) 1214 that promptly connects one by one as shown in the figure) anyly changes between asynchronous or synchronization frequency division.Described frequency division can be any amount of frequency division.Frequency division can be single-ended or differential clocks or reference signal (for example, as shown in Figure 14,16,41 and 42).Countless other circuit layouts that are used for frequency division are clearly to those skilled in the art, and are regarded as equivalence, and all these change all within the scope of the present invention.
Continuation is with reference to Figure 40, the 3rd example system 1201 can comprise clock generator (regularly/frequency reference) (100,200,300) and arbitrary or a plurality of shown in second circuit, as phase inverter 1196, square-wave generator 1015, frequency divider (1000,1010,1074,1218,1219), lock-in circuit 1204 or previously mentioned other type of difference second circuit in any circuit, as one or more processors 1275, memory 1280 or I/O interface 1285.For example, the 3rd example system 1201 can be embodied as and comprise that (on circuit 1197) will have first frequency (f 0) first reference signal directly offer other second circuit 1198 as processor 1275, one or more frequency dividers (1000,1010,1074,1218,1219) are suitable for more low-frequency a plurality of second reference signal, as are used for power save.Equally, for example, the 3rd example system 1201 can be embodied as the one or more frequency dividers (1000 that comprise one or more lock-in circuits 1204 and/or be connected to lock-in circuit 1204,1010,1074,1218,1219) for example (to provide first frequency f based on corresponding frequency dividing ratio 0Any reasonable multiple) a plurality of second reference signals of any corresponding frequencies are provided.
Figure 43 is the block diagram according to the 4th example system embodiment 1202 of the present invention.Clock/frequency reference (100,200,300) provides (has first frequency f 0) first reference signal, and be connected at least one lock-in circuit 1204 as phase-locked loop (PLL), delay lock loop (DLL) or injection locking circuit, so that corresponding second reference signal to be provided, the clock output signal as institute's selected frequency is illustrated as frequency f N(the 5th system embodiment with a plurality of lock-in circuits 1204 is described in conjunction with Figure 44 below.) be in operation, each lock-in circuit (as PLL or DLL) 1204 is suitable for phase place, delay or other locks onto first reference signal that clock/frequency reference (100,200,300) provides, and provides the output signal (second reference signal) with second frequency of determining from first frequency and corresponding frequency dividing ratio as output.Be illustrated as that phase-locked loop embodiment is used for the purpose of example and unrestricted, phase-locked loop 1204 A(as the type of lock-in circuit 1204) comprises first frequency divider (or multiplier) 1206 (as ÷ N) and second frequency divider (or multiplier) 1207 (as ÷ M), thereby forms corresponding frequency dividing ratio so that second frequency to be provided, and it is first frequency f 0. reasonable multiple (M/N).In the embodiment shown, second frequency divider 1207 is used as multiplier effectively (with output frequency f NBe divided into lower frequency with f 0/ N coupling and phase locking).According to selected embodiment, the output frequency of second reference signal is (as f N) can be first frequency f 0Any reasonable multiple, no matter be higher or lower.
Lock-in circuit 1204 is when being embodied as phase-locked loop 1204 AThe time also comprise phase detectors 1208, charge pump 1209, optionally filter 1211, and voltage-controlled oscillator (VCO) 1212 (second oscillator 1210 as shown in Figure 18).VCO1212 provides has second frequency f NSecond reference signal, its by processor 1275, memory 1280 and I/O interface 1285 among the integrated tertiary system system embodiment 1202 as clock or other reference.
Clock/reference (100,200,300) is suitable for providing and has first frequency f 0First reference signal as output, or provide together with frequency divider or lock-in circuit 1204 and to be illustrated as frequency f among Figure 43 NSecond reference signal of second frequency, or provide with a plurality of lock-in circuits 1204 or frequency divider and to have illustrated corresponding frequencies f among Figure 44 1, f 2F NCorresponding a plurality of second reference signals as output.As mentioned above, frequency selects to can be used as design and the part made takes place, as the inductor that uses in the LC oscillator by selection clock/reference (100,200,300) and the quantity and the size of capacitor.For example, the size of one or more inductors (as 445) and/or shape can be selected by the proper metal layer mask.Frequency is selected also can take place after manufacturing, and it is undertaken by using aforesaid different calibration and control coefrficient or signal.In addition, frequency is selected and can be undertaken by the one or more lock-in circuits 1204 of configuration (PLL or DLL), as passing through the frequency dividing ratio of selection by programmable counter, the part that it designs and make for IC, or can after manufacturing, programme, equally by using calibration or control coefrficient or signal or being undertaken by frequency divider being converted into or changing out division chain.
Figure 44 is the block diagram according to the 5th example system 1203 of the present invention.The 5th example system 1203 comprises before the Quaternary system 1202 described assemblies of uniting, i.e. the coefficient (1215) of clock/frequency reference (100,200,300), control logic or preservation, one or more processor 1275, I/O interface (or other I/O device) 1285, and memory 1280.The 5th example system 1203 also comprises a plurality of lock-in circuits 1204 and frequency divider (1000,1010,1074,1218,1219), respectively as phase-locked loop or delay lock loop (or injection locking circuit) and synchronous or asynchronous frequency divider, so that corresponding a plurality of second reference signals with corresponding a plurality of second frequencies (clock or other reference signal) to be provided, (single-ended, difference, square wave, sine, the spread-spectrum) signal that comprises any kind or shape is illustrated as and has corresponding second frequency f 1, f 2, f 3, f K... f NA plurality of second reference signals.Has corresponding frequencies f 1, f 2, f 3, f K... f NA plurality of second reference signals may and have first frequency f 0First reference signal all offer change-over circuit 1290, be used to select to offer one or more second reference signals of one or more processors 1275, I/O interface 1285 and memory 1280.
Change-over circuit 1290 can be by frequency selection and control logic circuit 1295 and/or control logic or register (1215) (above-mentioned) control of preserving coefficient.For example, control logic circuit 1295 can provide one or more control signals to change-over circuit 1290, and it is suitable in response to one or more control signals selected second reference signal in a plurality of second reference signals being transformed into processor 1275 and other assembly then.Similarly, the coefficient of one or more preservations (as being kept in the coefficient register 1215) can be used for being transformed into processor 1275 and other assembly by selected second reference signal that the grid voltage of control transformation or transmission transistor is controlled in a plurality of second reference signals.In addition, frequency is selected and control logic circuit 1295 also can be used for controlling a plurality of lock-in circuits 1204, as passing through the corresponding frequency dividing ratio of programming.In the exemplary embodiment, change-over circuit 1290 is embodied as provides the conversion of glitch-free in fact, and can transformational structure or matrix by any kind implement, as by one or more multiplexers, transmission transistor, cross bar switch or other conversion or configurable circuit.Perhaps, change-over circuit 1290 can be omitted, and a plurality of clocks or reference signal with different frequency or phase relation, type or shape (as single-ended, difference, square wave, sine, spread-spectrum) directly offer one or more processors 1275, I/O interface 1285 and memory 1280.In addition, change-over circuit 1290 can be by not reconfigurable circuit enforcement, as connecting or other disposable configurable connection by programmable connection on different fuses or other electricity, ROM.Numerous variations to the control of the selection of one or more second reference signals of offering second treatment circuit such as processor 1275, memory 1280, I/O interface 1285 in a plurality of second reference signals it will be apparent to those skilled in the art, these change and all are considered as equivalence and within the scope of the present invention.For example, the 5th example system 1203 can be used for providing a plurality of single-ended or difference and square wave or sinusoidal clock or reference signals with any institute's selected frequency and/or phase relation.Continue to use this example, at first, but when the enough power time spent, for high-performance, much higher frequency signal can be provided for one or more processors 1275, I/O interface 1285 and memory 1280.Secondly, when power supply is limited, for the performance of saving power, as when power supply is battery in order to reduce power, much lower frequency signal can be provided for one or more processors 1275, I/O interface 1285 and memory 1280.The 3rd, for the more power saving as for the sleep or hibernate mode, much lower frequency signal can be provided for one or more processors 1275, I/O interface 1285 and memory 1280.Except determining the frequency by the inductor that uses in the LC oscillator of selecting clock/reference (100,200,300) and the quantity and the size of capacitor, the coefficient (1215) of frequency selection and control logic circuit 1295 and/or control logic or preservation can be programmed or calibrate to provide with control transformation circuit 1290 has frequency f 1, f 2... f NAny described corresponding clock or other second reference signal.
Four exemplary discrete device embodiment are shown in Figure 45-48.Be similar to other illustrated embodiment, these discrete devices embodiment also is suitable for moving being not locked under the situation of external reference signal, as is not locked to crystal (XTAL) reference of any kind.In addition, any device among these discrete devices embodiment can be provided as form configurable or able to programme, as being provided, one or more second reference signals can select frequency and output pin, or be provided as configurable or not non-programmable form, as one or more second reference signals being provided predetermined or fixed frequency and output pin.For example, discrete device embodiment can be provided as providing " standard " IC of one or more clock signals of preset frequency, maybe can be provided as being selected by the user configurable I C of output frequency, signal type, signal level etc.As detailed below, described configuration and/or selection can be used as design and the part made takes place, and as by reactance size, quantity and interconnection being carried out the mask programming, or take place after manufacturing, as by configuration and discretionary interconnections, reactance conversion, frequency dividing ratio etc.In addition, described configuration can combine with above-mentioned exemplary integrated embodiment.
Figure 45 is the block diagram according to the exemplary first discrete device embodiment 3000 of the present invention, is embodied as discrete (promptly single) integrated circuit usually.As shown in Figure 45, first discrete device 3000 comprises clock/frequency reference (100,200,300), one or more frequency divider (1000 of operation as discussed previously, 1010,1074,1218, or 1219) and/or one or more lock-in circuit 1204, also comprise one or more I/O (I/O) interface circuit 3010.In addition, as selection, first discrete device 3000 also can comprise control logic and/or preserve the detector (1215) and the user interface 3025 of coefficient.Do not illustrate separately, first discrete device 3000 generally includes the input unit of power and control signal, and also can comprise voltage regulator.
As mentioned above, one or more lock-in circuits 1204 can be phase-locked loop or delay lock loop (or injection locking circuit), one or more frequency dividers (1000,1010,1074,1218,1219) (comprising any frequency divider in the lock-in circuit 1204) can be synchronous or asynchronous, independent or differential divider.Lock-in circuit 1204 and/or frequency divider (1000,1010,1074,1218,1219) also can be embodied as configurable or can not Configuration Type.In this exemplary first discrete device 3000 and following other exemplary discrete embodiment, one or more frequency dividers (1000,1010,1074,1218, or 1219) and/or one or more lock-in circuit 1204 corresponding a plurality of second reference signals with corresponding a plurality of second frequencies (clock or other reference signal) are provided, comprise any kind or shape (single-ended, difference, square wave, sine, spread-spectrum etc.), be illustrated as and have corresponding second frequency f 1, f 2... f NA plurality of second reference signals.Has corresponding frequencies f 1, f 2... f NA plurality of second reference signals may and have first frequency f 0First reference signal all be provided directly to corresponding a plurality of I/0 interface 3010.(in addition, according to the frequency divider of " link " and/or the quantity of lock-in circuit in succession, as shown in Figure 45 and 48, wherein one or more second reference signals appear in succession between the circuit, and gained output (from frequency divider or the lock-in circuit in succession last) can be described as has corresponding a plurality of the 3rd frequency f 1, f 2... f NA plurality of the 3rd reference signals).
Be similar to I/O interface 1285, I/O interface 3010 can be by known in the art or implementing of being about to know, to provide (output) from clock/frequency reference (100,200,300) with different frequency dividers (1000,1010,1074,1218,1219) with lock-in circuit 1204 in the communicating by letter of arbitrary first and/or second reference signal of taking office its device what or structure (as the outer device of sheet), for example but unrestricted, other device or structure such as one or more IC I/O pin, or passage, bus, the input and output device, other circuit, other I/O PAD, mechanism described herein and medium, described communication comprises wireless, optics or wired mode and use any available standards, technology or medium.For example, when first discrete device 3000 is used to computer or communication system that clock control IC is provided, I/O interface 3010 is suitable for reference signal communication is offered one or more lead, one or more bus such as pci bus, PCI high-speed bus, the USB (USB1 or USB2) on (and may receive from the it) printed circuit board (PCB) (PCB), or offer one or more other IC, as when when the IC bonding wire is connected to another IC.In addition, I/O interface 3010 can be provided to the interface of previous described any other device or structure.
For purpose of the present invention, when being called I/O interface 3010, I/O interface 3010 only needs to provide the output of different first and/or second reference signals.According to selected embodiment, I/O interface 3010 also can be embodied as accepts dissimilar inputs.Similarly, in the exemplary embodiment of using convertible or configurable connection (following), I/O interface 3010 can be implemented as and not only be used for output function but also be used for input function, and input signal correspondingly changes or be sent to the other parts of IC as the part of I/O pin configuration.
I/O interface 3010 is used to provide any and/or all signalings and physical interface function, as impedance matching.Take office the what signal transmission of its device or any other communication function that any selected application was exported and be suitable for to other data from first discrete device 3000.In the exemplary embodiment, I/O interface 3010 can be implemented as configurable or programmable type, as be used to select level output signal (arriving the part voltage rail to full voltage main line or part voltage rail), selection output signal type (as single-ended or difference), and be used to change or mate the load that will drive as the full voltage main line.In other exemplary embodiment, I/O interface 3010 also can be embodied as can not Configuration Type, as one or more second reference signals of fixing or predeterminated level, type and load are provided.
Described configurability or programmability also can be used for other the configurable or programmable component of discrete embodiment shown in other, and described configurability and/or programmability can provide by control circuit or logic and/or the register (1215) of preservation coefficient and one or two in the user interface 3025, and as the part enforcement that designs and make, or after manufacturing, implement by manufacturer, retail trader or terminal use.(register (1215) by control circuit or logic and/or preservation coefficient implements to use the dotted line among Figure 45 to illustrate.) in addition, described configurability and/or programmability can use selection configurable, able to programme, conversion or the routing circuit of any kind to implement, following configurable conversion or routing circuit 3040 in conjunction with Figure 46-48 is described in detail such.For example, described configuration and/or programming can be used enforcements such as switch, fuse, laser reconditioning, transmission transistor, multiplexer, demultiplexer, FPGA, other configurable logic.Different configurations or program can be disposable configurations, as when the static coefficient that connects by fuse, preserve among mask programming or the ROM is implemented; Maybe can be the restructural type, as being used to control corresponding switch or multiplexer among nonvolatile memory such as FLASH or the EPROM by variable coefficient is kept at.
In addition, configurability or programmability can be used as the design of different embodiment and the part of manufacturing provides.For example, as mentioned above, different a plurality of coefficients or control signal determine that after manufacturing it is used for by being calibrated to another reference frequency signal such as foreign frequency with reference to the first frequency of selecting first reference signal.The size (and/or quantity) that first frequency also can be by selecting reactance (inductor and/or capacitor), a plurality of connections by selecting a plurality of convertible controlled reactance modules and/or interconnection are with the different reactance that connect the control first frequency or make it disconnect a plurality of sizes of connecting or selecting a plurality of convertible controlled reactance modules, carry out mask by the type (as single-ended or difference) of selecting signal programmes.The a plurality of connections that first frequency also can be by selecting a plurality of convertible controlled reactance modules or the interconnection of interconnection and other different assemblies and after manufacturing, dispose.
But part configuration or selection that other disposes also mask programming or can be used as the IC manufacturing process.For example, the difference between the assembly connect with interconnection in any be connected and interconnection may be programmed in any conducting shell mask.For example, the selection of the outgoing position of one or more second reference signals can appear at any point in frequency division or the sway chain, and can select by the interconnection that provides in the corresponding selection conduction mask layer.Continue to use this example, for design and manufacturing configurability, I/O interface 3010 can by provide with a plurality of drivers or amplifier in selected driver or the different interconnection (by the conducting shell mask) of amplifier be configured, so that corresponding signal level to be provided, or by being welded to selected electromotive force or floating potential.In addition, any parameter in different technical parameters and the size and size also can be revised because of programmability and/or configurability, as the use by any, the doping in the different etchings, ion injection, deposition, layer thickness, conduction selection (as the metal pair polysilicon), pressurized or strain substrate such as strained silicon etc.Other method of configurability and programmability and type will be apparent to those skilled in the art, and these methods and type all are regarded as equivalence and within the scope of the present invention.
Continuation is with reference to Figure 45, and according to the present invention, spread-spectrum is functional also can be implemented.For example but unrestricted, spread-spectrum is functional to be may be implemented in clock/frequency reference (100,200,300) to change the first frequency that changes first reference signal in time, or be implemented in different frequency divider (1000,1010,1074,1218,1219) or in lock-in circuit 1204 arbitrary to change any second frequency that changes corresponding second reference signal in time.For example, the control circuit of (register (1215) of control logic and/or preservation coefficient) can be connected to a plurality of convertible controlled reactance modules, and is suitable for providing the time-varying conversion of a plurality of convertible controlled reactance modules to have spread-spectrum first reference signal of a plurality of different first frequencies to revise first frequency and to provide to change in time.Equally, for example, the control circuit of (register (1215) of control logic and/or preservation coefficient) can be connected to one or more lock-in circuits 1204, and described control circuit is suitable for providing the time-varying variation of frequency dividing ratio to have spread-spectrum second reference signal of a plurality of different second frequencies to provide to change in time.Continue to use this example, first and second frequency dividers (1206 and 1207) that (lock-in circuit 1204) is different or any other frequency dividing circuit (1000,1010,1074,1218,1219) can be embodied as counter, described control circuit is suitable for revising ultimate or limit count, counter provides output signal based on it, thereby provides in time to change and have spread-spectrum second reference signal of a plurality of different second frequencies to change one or more second reference signals.
Different calibrations and configuration can provide by user interface 3025 after manufacturing.Described user interface 3025 can be embodied as provide input to dissimilar control circuit (as 3015,1810) and/or coefficient register (as 455,465,495,1215,1950,3020) thus import any selection or configuration.For example, user interface 3025 can be connected to test table or other computer interface, thereby import described selection and configuration automatically, as known in the art or be about to know like that, for example be connected to dissimilar work stations or other equipment of be used to programme FPGA, nonvolatile memory or other configurable logic.
Figure 46 is the block diagram according to exemplary second discrete device 3030 of the present invention.Figure 47 is the block diagram according to exemplary the 3rd discrete device 3050 of the present invention.Figure 48 is the block diagram according to exemplary the 4th discrete device 3070 of the present invention.Second discrete device 3030 uses one or more frequency dividers (1000,1010,1074,1218,1219) to implement as configurable counter.The 3rd discrete device 3050 uses one or more lock-in circuits 1204 (have configurable frequency dividing ratio, first and second frequency dividing circuits that also configurable counter are used to be integrated are implemented usually) to implement.The 4th discrete device 3070 uses one or more frequency dividers (1000,1010,1074,1218,1219) to implement as configurable counter and one or more lock-in circuit 1204 (also having configurable frequency dividing ratio).In addition, the control circuit 3015 and the coefficient register 3020 of the register (1215) of control circuit or logic and/or preservation coefficient are illustrated separately.
Replacement directly offers corresponding I/O interface 3010 in a plurality of I/O interfaces 3010 with the first different reference signals and/or a plurality of second reference signal, for these exemplary second, third and the 4th discrete device embodiment, first reference signal and a plurality of second reference signal are provided for configurable conversion (or routing) circuit 3040.More specifically, one or more frequency dividers (1000,1010,1074,1218, or 1219) and/or one or more lock-in circuit 1204 corresponding a plurality of second (or 3rd) reference signal (clock or other reference signal) that will have corresponding a plurality of second (or 3rd) frequency offer configurable conversion (or routing) circuit 3040, described reference signal comprises that the signal (single-ended, difference, square wave, sine, spread-spectrum) of any kind or shape (is illustrated as and has the corresponding second or the 3rd frequency f 1, f 2... f NThe a plurality of second or the 3rd reference signal), first reference signal has first frequency f 0Afterwards, configurable conversion (or routing) circuit 3040 is selectively with the conversion of first reference signal and a plurality of second reference signal or be sent to selected I/O interface 3010 in a plurality of I/O interfaces 3010.Described selectable conversion or routing also can be by 3020 controls of (control circuit/coefficient register 1215) control circuit 3015 and/or coefficient register, and are configured or programme by user interface 3025.
Configurable conversion (or routing) circuit 3040 can use configurable, able to programme, the conversion of any kind or routing circuit to implement.For example, described configuration and/or programming can be used enforcements such as the configurable logic of multiplexer, demultiplexer, switch, fuse, laser reconditioning, transmission transistor, FPGA or any other type or conversion.Different configurations or program can provide the disposable configuration of the direct transmission (direct interconnection) of signal, as when connect by mask, fuse connects or ROM in the fixed coefficient preserved when implementing; Maybe can be the restructural type, as by variable coefficient being kept in the nonvolatile memory, being used to control corresponding switch or multiplexer by the state machine of implementing in control circuit and other type control circuit.The part that selected conversion that is provided by configurable conversion (or routing) circuit 3040 or routing can be used as above-mentioned manufacturing process is programmed or is disposed, as connection by mask-programmable, or can after manufacturing, determine, as register (1215) and user interface 3025 by control circuit or logic and/or preservation coefficient.
For example, comprise different exemplary embodiments general, flexibly and/or the self adaptation integrated circuit can be designed (and manufacturing) for supporting first and second frequencies of wide region, as mentioned above, but as by the mask programmatic.After manufacturing, usually by user interface 3025 or previous described other mechanism, institute screening device (IC) can be calibrated having first reference signal of one or more first frequencies, as the different coefficients by (and being kept in one of coefficient register register as discussed previously or the coefficient register 3020) as described in determining before.In addition, according to selected embodiment, described calibration can provide one or more control signals.
Continue to use this example, by user interface 3025, for providing special output frequency and signal type from general or flexible IC, any frequency in the second and/or the 3rd different frequencies all can be selected together with its outgoing position, level and type equally.Equally after manufacturing, above-mentioned difference configuration or programming can be implemented, and be used to change or send the first and second different reference signals by using control signal (from control circuit 3015) or coefficient (as conversion or control coefrficient) (being kept in the coefficient register 3020).In addition, by user interface 3025, manufacturer, the also configurable conversion of retail trader or terminal use (or routing) circuit 3040 and previous described other parameter, as variable locking circuit 1204 or frequency divider (1000,1010,1074,1218,1219) different frequency dividing ratios or ultimate (limit) that is used for the frequency selection of one or more second (or 3rd) reference signal counted, and institute's arrangement of I/O interface 3010 is (as signal level, signal type) and configurable conversion (or routing) circuit 3040 can will have any selected first or second reference signal conversion of corresponding selected (and configurable) frequency or send to any I/O interface in a plurality of I/O interfaces 3010.For example, these supplementary features can be used for the programming of customization IC pin, to provide one or more selected clock signals at selected IC pin.
In a word, the invention provides integrated circuit, it comprises: comprise the oscillator of inductor and capacitor, oscillator is suitable for providing first reference signal with first frequency, and oscillator also is suitable for moving being not locked under the situation of external reference signal; Also comprise: the voltage controller that is suitable for providing a plurality of voltage control signals; Be connected to a plurality of convertible controlled reactance modules of oscillator and voltage controller, thereby each reactance module in a plurality of reactance module is suitable for providing selected reactance to revise first frequency in response to the relevant voltage control signal in a plurality of voltage control signals; And be suitable for being provided for the output circuit of the interface of external signal communication.
Exemplary integrated circuit also can comprise the divider circuit that is connected to oscillator, and divider circuit is suitable for providing second reference signal of second frequency.Lock-in circuit can be connected to divider circuit and be suitable for locking onto second reference signal and the 3rd reference signal with the 3rd frequency is provided, and the 3rd frequency is determined from the frequency dividing ratio of second frequency and lock-in circuit.In addition, control circuit can be connected to lock-in circuit, and described control circuit is suitable for providing time-varying frequency dividing ratio to change spread-spectrum the 3rd reference signal with a plurality of different the 3rd frequencies in time to provide.Perhaps, control circuit can be connected to a plurality of convertible controlled reactance modules, described control circuit is suitable for providing the time-varying conversion of a plurality of convertible controlled reactance modules, has spread-spectrum first reference signal of a plurality of different first frequencies thereby provide to change in time.
Output circuit is configurable to be used for selecting the signal type of a plurality of signal types of second reference signal, and a plurality of signal types comprise at least one in the following signal type: difference, single-ended, full voltage main line to full voltage main line or part voltage rail to the part voltage rail.
Example integrated circuit also can comprise a plurality of lock-in circuits that are connected to divider circuit, a plurality of lock-in circuits are suitable for locking onto second reference signal and corresponding a plurality of the 3rd reference signals with a plurality of corresponding the 3rd frequencies are provided, and the frequency dividing ratio of the corresponding lock-in circuit of each the 3rd frequency from second frequency and a plurality of lock-in circuit in a plurality of corresponding the 3rd frequencies is determined.Each lock-in circuit in a plurality of lock-in circuits can be one of following lock-in circuit: phase-locked loop, delay lock loop or injection locking circuit.In addition, each lock-in circuit in a plurality of lock-in circuits is configurable aspect the selection frequency dividing ratio.
Exemplary integrated circuit also can comprise a plurality of output circuits of the corresponding a plurality of output interfaces that are suitable for being provided for signal communication; And being connected to first change-over circuit of a plurality of lock-in circuits and a plurality of output circuits, first change-over circuit is suitable for selectively selected the 3rd reference signal in a plurality of the 3rd reference signals being transformed into the selected output circuit in a plurality of output circuits.Thereby can being connected to a plurality of output circuits and being suitable for that control signal is offered selected output circuit in a plurality of output circuits, control circuit selects signal type in a plurality of signal types of corresponding the 3rd reference signal.Control circuit can be connected to first change-over circuit and be suitable for control signal is offered first change-over circuit so that selected the 3rd reference signal is transformed into selected output circuit.
Similarly, coefficient register can be connected to first change-over circuit and be suitable for first control coefrficient in more than first control coefrficient is offered first change-over circuit so that selected the 3rd reference signal is transformed into selected output circuit.Coefficient register also can be connected to a plurality of convertible controlled reactance modules, and coefficient register is suitable for preserving more than second coefficient and provides more than second corresponding coefficient in the coefficient to control the conversion of corresponding controlled reactance modules to oscillator.More than second coefficient can provide the external signal of reference frequency to determine by being calibrated to after manufacturing.Exemplary integrated circuit also can comprise the user interface that is connected to coefficient register, and it is suitable in response to user input the coefficient in more than first coefficient or more than second coefficient being offered coefficient register.
For example, first change-over circuit can comprise a plurality of multiplexers and demultiplexer, or a plurality of transmission transistor or cross bar switch.
But first frequency mask programming, its size by selecting inductor or a plurality of connections by selecting a plurality of convertible controlled reactance modules or undertaken by a plurality of sizes of selecting a plurality of convertible controlled reactance modules.First frequency can dispose after manufacturing by a plurality of connections of selecting a plurality of convertible controlled reactance modules.
Another example integrated circuit embodiment can comprise: comprise the harmonic oscillator of inductor and capacitor, harmonic oscillator is suitable for providing first reference signal with first frequency; Be connected to a plurality of controlled reactance modules of harmonic oscillator, each reactance module in a plurality of reactance module is suitable for providing selected reactance to revise first frequency in response to the control voltage in a plurality of control voltages; Be suitable for preserving first coefficient register of more than first conversion coefficient; Be connected to more than first switch of a plurality of controlled reactance modules, the corresponding conversion coefficient of each switching response in more than first conversion coefficient in more than first switch is connected to corresponding controlled reactance modules with the selected control voltage in a plurality of control voltages; Be connected to first frequency divider of harmonic oscillator, first frequency divider is suitable for providing second reference signal of second frequency; And be connected to a plurality of lock-in circuits of first frequency divider, a plurality of lock-in circuits are suitable for locking onto second reference signal and corresponding a plurality of the 3rd reference signals with a plurality of corresponding the 3rd frequencies are provided, and the frequency dividing ratio of the corresponding lock-in circuit of each the 3rd frequency from second frequency and a plurality of lock-in circuit in a plurality of corresponding the 3rd frequencies is determined.Harmonic oscillator also can be suitable for moving being not locked under the situation of external reference signal.
Equally, in a word, another exemplary configurable integrated circuit embodiment can comprise: the oscillator that comprises inductor, capacitor and trsanscondutance amplifier, oscillator is suitable for providing first reference signal with first frequency, oscillator also is suitable for moving being not locked under the situation of external reference signal, and trsanscondutance amplifier also comprises the variable current source that is suitable for providing in response to operating temperature corresponding electric current; Be suitable for providing the voltage controller of a plurality of voltage control signals; Be connected to a plurality of convertible controlled reactance modules of oscillator and voltage controller, thereby each reactance module in a plurality of reactance module is suitable for providing selected reactance to revise first frequency in response to the relevant voltage control signal in a plurality of voltage control signals; Be connected to first frequency divider of oscillator, first frequency divider is suitable for providing second reference signal of second frequency; And be connected to a plurality of configurable lock-in circuit of first frequency divider, a plurality of lock-in circuits are suitable for locking onto second reference signal and corresponding a plurality of the 3rd reference signals with a plurality of corresponding the 3rd frequencies are provided, and the configurable frequency dividing ratio of the corresponding lock-in circuit of each the 3rd frequency from second frequency and a plurality of lock-in circuit in a plurality of corresponding the 3rd frequencies is determined.
Equally in a word, the invention provides integrated circuit, comprising: comprise the resonator of inductor and capacitor, resonator is suitable for providing first reference signal with first frequency; Be suitable for providing the voltage controller of a plurality of voltage control signals; Be connected to a plurality of convertible controlled reactance modules of resonator and voltage controller, thereby each reactance module in a plurality of reactance module is suitable for providing selected reactance to revise first frequency in response to the relevant voltage control signal in a plurality of voltage control signals; And be connected to the processor of resonator.IC also can comprise the lock-in circuit that is connected to resonator, and lock-in circuit is suitable for locking onto first reference signal and second reference signal with second frequency is provided, and wherein second frequency is the reasonable multiple of first frequency; And wherein processor is connected to resonator by lock-in circuit, and be suitable for receiving second reference signal.
For example, first or second reference signal can be the square wave clock signal.Processor can be any kind circuit that is suitable for carrying out function, for example processor of arbitrary following type: microprocessor, digital signal processor, controller, microcontroller, USB (USB) controller, periphery component interconnection (PCI) controller, periphery component interconnection is (PCI-e) controller fast, the live wire controller, AT annex (ATA) interface controller, integrated driving electronics (IDE) controller, the SCS(Small Computer System Interface) controller, control device of the tv, the Local Area Network controller, ethernet controller, Video Controller, Audio Controller, modem processor, the MPEG controller, multimedia controller, communication controler, the mobile communication controller, IEEE 802.11 controllers, the GSM controller, the GPRS controller, the PCS controller, the AMPS controller, the CDMA controller, the WCDMA controller, the spread-spectrum controller, the WLAN controller, IEEE 802.11 controllers, the DSL controller, t1 controller, the ISDN controller, or cable modem controller.Integrated circuit also can comprise: be connected to processor and further be connected to lock-in circuit to receive the memory of second reference signal; And be connected to processor and further be connected to lock-in circuit to receive the input/output interface of second reference signal.Lock-in circuit can be one of following lock-in circuit: phase-locked loop, delay lock loop or injection locking circuit.
In other exemplary embodiment, integrated circuit also comprises a plurality of lock-in circuits that are connected to resonator, and a plurality of lock-in circuits are suitable for locking onto first reference signal and corresponding a plurality of second reference signals with a plurality of corresponding frequencies are provided; And also can comprise the change-over circuit that is connected to a plurality of lock-in circuits and processor, change-over circuit is suitable for by selected second reference signal in corresponding a plurality of second reference signals is transformed into processor and selectively processor is connected to a plurality of lock-in circuits.Integrated circuit also can comprise: be connected to the control circuit of change-over circuit, control circuit be suitable for providing control signal to change-over circuit so that selected second reference signal is transformed into processor; And/or be connected to the coefficient register of change-over circuit, coefficient register be suitable for providing control coefrficient to change-over circuit so that selected second reference signal is transformed into processor.Each lock-in circuit in a plurality of lock-in circuits also can comprise a plurality of asynchronous or synchronous frequency divider circuit, and a plurality of correspondent frequency is determined by the corresponding frequency dividing ratio of a plurality of divider circuits.Integrated circuit also can comprise the spread-spectrum generator that is connected to resonator or lock-in circuit, and the spread-spectrum generator is suitable for providing the time dependent adjusting of first reference signal or second reference signal.
In other exemplary embodiment, integrated circuit can comprise: comprise the harmonic oscillator of inductor and capacitor, harmonic oscillator is suitable for providing first reference signal with first frequency; Be suitable for producing a plurality of resistive module of a plurality of voltage control signals; Be connected to a plurality of controlled reactance modules of harmonic oscillator and a plurality of resistive module, each reactance module in a plurality of reactance module is suitable for providing selected reactance to revise first frequency in response to the relevant voltage control signal in a plurality of voltage control signals; Be connected to first coefficient register of a plurality of switches, first coefficient register is suitable for preserving more than first conversion coefficient; Be connected to more than first switch of a plurality of resistive module and a plurality of controlled reactance modules, the corresponding conversion coefficient of each switching response in more than first conversion coefficient in more than first switch is connected to corresponding controlled reactance modules with the selected control voltage in a plurality of control voltages; Be connected to the lock-in circuit of harmonic oscillator in the running, lock-in circuit is suitable for locking onto first reference signal and second reference signal with second frequency being provided; And be connected to lock-in circuit to receive the processor of second reference signal in the running.
This integrated circuit also can comprise: be connected to a plurality of lock-in circuits of harmonic oscillator in the running, a plurality of lock-in circuits are suitable for locking onto first reference signal and corresponding a plurality of second reference signals with a plurality of corresponding frequencies are provided; And being connected to more than second switch of a plurality of lock-in circuits and processor, more than second switch is suitable for selected second reference signal in corresponding a plurality of second reference signals is transformed into processor.In addition, control circuit can be connected to more than second switch, control circuit be suitable for providing control signal to more than second switch so that selected second reference signal is transformed into processor.Perhaps, second coefficient register can be connected to more than second switch, second coefficient register be suitable for providing control coefrficient to more than second switch so that selected second reference signal is transformed into processor.
In other exemplary embodiment, integrated circuit comprises: comprise the resonator of inductor and capacitor, resonator is suitable for providing first reference signal with first frequency; Be suitable for providing the transducer of secondary signal in response to operating temperature or manufacturing process variations; Be suitable for providing the voltage controller of a plurality of voltage control signals; Be connected to a plurality of convertible controlled reactance modules of resonator and voltage controller, each reactance module in a plurality of reactance module is suitable for providing selected reactance to revise first frequency in response to the relevant voltage control signal in a plurality of voltage control signals; Be connected to a plurality of lock-in circuits of resonator in the running, a plurality of lock-in circuits are suitable for locking onto first reference signal and corresponding a plurality of second reference signals with a plurality of corresponding frequencies are provided; Be suitable for receiving the processor of selected second reference signal in a plurality of second reference signals; And being connected to the change-over circuit of a plurality of lock-in circuits and processor, change-over circuit is suitable for selected second reference signal is transformed into processor.
Equally, generally speaking, the invention provides the device that comprises following assembly: the resonator that is suitable for providing first signal with resonance frequency; Be connected to the amplifier of resonator; And the frequency controller (being connected to resonator) that is suitable for selecting having the resonance frequency of the first frequency in a plurality of frequencies.Described device also comprises frequency divider (being connected to resonator), its first signal that is suitable for having first frequency is divided into a plurality of secondary signals with corresponding a plurality of frequencies, described a plurality of frequency is equal to or less than first frequency in fact, realizes frequency division as passing through divided by rational.
First signal can be differential signal or single-ended signal.When first signal was differential signal, frequency divider also was suitable for differential signal is converted to single-ended signal.Similarly, when first signal was the essence sinusoidal signal, frequency divider also was suitable for the essence sinusoidal signal is converted to the essence square-wave signal.
In different embodiment, frequency divider can comprise a plurality of triggers or the counter of series connection downlink connection, the output of wherein selected trigger or counter is last trigger or counter divided by 2 frequency, or more generally, a plurality of frequency divider series connection downlink connection, wherein the output of frequency divider is lower than the frequency of the output of last frequency divider in succession.A plurality of frequency dividers can be the frequency dividers of difference, single-ended or difference and single-ended combination, as being last single-ended section after the difference.Frequency divider can comprise that also being suitable for first conversion of signals is the square-wave generator with essence square-wave signal of equal in fact height and low duty ratio.
The present invention also can comprise the frequency-selector that is connected to frequency divider, and it is suitable for providing output signal from a plurality of secondary signals.Frequency-selector also can comprise multiplexer and discriminator.
The present invention also can comprise the mode selector that is connected to frequency-selector, wherein mode selector is suitable for providing plurality of operating modes, and described operational mode can be selected from down group: clock module, timing and frequency reference pattern, power save mode and be subjected to the impulse action pattern.
For reference model, the present invention also can comprise the synchronous circuit that is connected to mode selector; And be connected to synchronous circuit and be suitable for providing the controlled oscillator of the 3rd signal; Wherein in timing and reference model, mode selector also is suitable for output signal is connected to timing and the frequency of synchronous circuit to control the 3rd signal.Described synchronous circuit can be delay lock loop, phase-locked loop or injection locking circuit.
In selected embodiment, amplifier can be a negative transconductance amplifier.Frequency controller also is suitable in response to the electric current of temperature modification by negative transconductance amplifier, and it can comprise the current source in response to temperature.Described current source can have one or more structures that are selected from multiple structure, comprises CTAT, PTAT and PTAT as multiple structure 2Structure.In addition, frequency controller also be suitable for revising electric current by negative transconductance amplifier with the selective resonance frequency, revise the mutual conductance of negative transconductance amplifier with the selective resonance frequency or in response to the electric current of voltage modifications by negative transconductance amplifier.Frequency controller also can comprise the voltage isolator that is connected to resonator and is suitable for resonator and change in voltage are isolated in fact, and can comprise current mirror, and it also can comprise the cobasis common-emitter configuration.Frequency controller also is suitable for revising in response to manufacturing process variations, variations in temperature or change in voltage the electric capacity or the inductance of resonator.
Frequency controller can have the different embodiment of these difference in functionalitys, and also can comprise: the coefficient register that is suitable for preserving more than first coefficient; And first array with a plurality of switchable capacitive module that are connected to the coefficient register resonator, each switchable capacitive module has fixed capacity and variable capacitance, and each switchable capacitive module is transformed into control voltage in response to the corresponding coefficient in more than first coefficient with conversion between fixed capacity and variable capacitance and with each variable capacitance.A plurality of switchable capacitive module can be the modules of binary weighting, or have another weighting scheme.Frequency controller also can comprise having a plurality of switchable resistive module that are connected to coefficient register and second array that also has capacitance module, capacitance module and a plurality of switchable resistive module are also connected to node so that control voltage to be provided, and each switchable resistive module is transformed into the control voltage node in response to the corresponding coefficient in more than second coefficient of preserving in the coefficient register with switchable resistive module; Reach the temperature-dependent current source that is connected to second array by current mirror.
Frequency controller also can comprise the process variation compensator that is connected to resonator and is suitable for revising in response to manufacturing process variations resonance frequency.In the exemplary embodiment, process variation compensator can comprise: the coefficient register that is suitable for preserving a plurality of coefficients; And array with a plurality of switchable capacitive module that are connected to the coefficient register resonator, each switchable capacitive module has first fixed capacity and second fixed capacity, and each switchable capacitive module is changed between first fixed capacity and second fixed capacity in response to the corresponding coefficient in a plurality of coefficients.A plurality of switchable capacitive module can be the modules of binary weighting, or have another weighting scheme.
In a further exemplary embodiment, process variation compensator can comprise: the coefficient register that is suitable for preserving a plurality of coefficients; And the array with a plurality of switchable variable capacitive module that are connected to the coefficient register resonator, each switchable variable capacitive module is changed between first voltage and second voltage in response to the corresponding coefficient in a plurality of coefficients.A plurality of switchable variable capacitive module are the module of binary weighting also, or has another weighting scheme.
The present invention also can comprise the frequency calibration module that is connected to frequency controller and is suitable for revising in response to reference signal resonance frequency.For example, frequency calibration module can comprise the frequency divider that is connected to frequency controller, and the output signal that frequency divider is suitable for being derived from first signal with first frequency is converted to lower frequency so that the signal behind the frequency division to be provided; Also comprise the frequency detector that is connected to frequency divider, frequency detector is suitable for the signal behind comparison reference signal and the frequency division and one or more rising signals or dropping signal is provided; And being connected to the pulse counter of frequency detector, pulse counter is suitable for the difference between one or more risings or the dropping signal is defined as the indication of the difference between output signal and the reference signal.
The resonator that uses with the present invention can comprise inductor (L) and the capacitor (C) that is connected to form the LC accumulator, has the selected structure in the multiple LC accumulator structure, as series, parallel etc., and can comprise other assembly.In other embodiments, resonator can be selected from down group: ceramic resonator, mechanical resonator, micro-electro-mechanical resonator, and thin film bulk acoustic resonator, or be equivalent to any other resonator that inductor (L) is connected to capacitor (C) on the electricity.
For example, resonator generally includes one or more inductors and capacitor, thereby forms one or more LC accumulators or LC resonator.In first embodiment, use two balanced differential LC resonator layouts.In other exemplary embodiment, difference or single-ended LC oscillator layout be can use, Bi Zi LC oscillator (cobasis reaches and collects version altogether), difference Hartley LC oscillator (cobasis reaches and collects version altogether), single-ended Pierre Si LC oscillator, quadrature oscillator (as forming) or active inductor LC oscillator (it can be embodied as or difference or single-ended LC oscillator) examined by at least two two balances, difference LC oscillators as the single-ended Bi Zi of examining LC oscillator, single-ended Hartley LC oscillator, difference.Other LC oscillator layout no matter be now known or be about to know, all is considered as equivalent arrangements and within the scope of the present invention.
Apparatus of the present invention can be used as timing and frequency reference or are used as clock generator.In addition, the present invention also can comprise second oscillator (as annular, tension and relaxation or phaseshift oscillator) that second oscillator output signal is provided; And being connected to the mode selector of the frequency controller and second oscillator, mode selector is suitable for being transformed into second oscillator output signal so that power save mode to be provided.Other operational mode can be provided by the mode selector that is connected to frequency controller, and it can be suitable for regularly starting and stop resonator so that the output signal that is subjected to impulse action to be provided, or is suitable for starting selectively and stopping resonator so that power save mode to be provided.
In another selected embodiment, apparatus of the present invention comprise: the resonator that is suitable for providing first signal with resonance frequency; Be connected to the amplifier of resonator; Be connected to the temperature compensator of amplifier resonator, temperature compensator is suitable in response to the temperature modification resonance frequency; Be connected to the process variation compensator of resonator, process variation compensator is suitable in response to the temperature modification resonance frequency; Be connected to the frequency divider of resonator, first signal that frequency divider is suitable for having resonance frequency is divided into a plurality of secondary signals with corresponding a plurality of frequencies, and a plurality of frequencies are equal to or less than resonance frequency in fact; And being connected to the frequency-selector of frequency divider, frequency-selector is suitable for providing output signal from a plurality of secondary signals.
In another selected embodiment, apparatus of the present invention clocking, and comprising: be suitable for providing difference with resonance frequency, the LC resonator of the first sinusoidal signal in fact; Be connected to the negative transconductance amplifier of LC resonator; Be connected to the temperature compensator of negative transconductance amplifier and LC resonator, temperature compensator is suitable in response to the electric current in the temperature modification negative transconductance amplifier and also in response to the electric capacity of temperature modification LC resonator; Be connected to the process variation compensator of LC resonator, process variation compensator is suitable for revising in response to manufacturing process variations the electric capacity of LC resonator; Be connected to the frequency divider of resonator, it is a plurality of single-ended, the secondary signal of square wave in fact with corresponding a plurality of frequencies that frequency divider is suitable for having first conversion of signals of resonance frequency and frequency division, a plurality of frequencies are equal to or less than resonance frequency in fact, and each secondary signal has height and the low duty ratio that equates in fact; And being connected to the frequency-selector of frequency divider, frequency-selector is suitable for providing output signal from a plurality of secondary signals.
From as can be seen aforementioned, can carry out numerous variations and modification and do not deviate from the spirit and scope of new ideas of the present invention.Should be appreciated that unawareness for to be limited to concrete grammar shown here and device, but contain all described variations that drop in the scope of the invention by claims.

Claims (51)

1. integrated circuit comprises:
The oscillator that comprises inductor and capacitor, oscillator are suitable for providing first reference signal with first frequency, and oscillator also is suitable for moving being not locked under the situation of external reference signal;
Be suitable for providing the voltage controller of a plurality of voltage control signals;
Be connected to a plurality of convertible controlled reactance modules of oscillator and voltage controller, thereby each reactance module in a plurality of reactance module is suitable for providing selected reactance to revise first frequency in response to the relevant voltage control signal in a plurality of voltage control signals; And
Be suitable for being provided for the output circuit of the output interface of signal communication.
2. according to the integrated circuit of claim 1, also comprise:
Be connected to the control circuit of a plurality of convertible controlled reactance modules, control circuit is suitable for providing the time-varying conversion of a plurality of convertible controlled reactance modules to have spread-spectrum first reference signal of a plurality of different first frequencies to provide to change in time.
3. according to the integrated circuit of claim 1, also comprise:
Be connected to the divider circuit of oscillator, divider circuit is suitable for providing second reference signal of second frequency.
4. according to the integrated circuit of claim 3, also comprise:
Be connected to divider circuit and be suitable for locking onto second reference signal and the lock-in circuit of the 3rd reference signal with the 3rd frequency is provided, the 3rd frequency is determined from the frequency dividing ratio of second frequency and lock-in circuit.
5. according to the integrated circuit of claim 4, also comprise:
Be connected to the control circuit of lock-in circuit, described control circuit is suitable for providing time-varying frequency dividing ratio to change spread-spectrum the 3rd reference signal with a plurality of different the 3rd frequencies in time to provide.
6. according to the integrated circuit of claim 3, wherein configurable aspect the signal type of output circuit in selecting a plurality of signal types of second reference signal, a plurality of signal types comprise at least one in the following signal type: difference, single-ended, full voltage main line arrive the part voltage rail to full voltage main line or part voltage rail.
7. according to the integrated circuit of claim 3, also comprise:
Be connected to a plurality of lock-in circuits of divider circuit, a plurality of lock-in circuits are suitable for locking onto second reference signal and corresponding a plurality of the 3rd reference signals with a plurality of corresponding the 3rd frequencies are provided, and the frequency dividing ratio of the corresponding lock-in circuit of each the 3rd frequency from second frequency and a plurality of lock-in circuit in a plurality of corresponding the 3rd frequencies is determined.
8. according to the integrated circuit of claim 7, each lock-in circuit in wherein a plurality of lock-in circuits can be one of following lock-in circuit: phase-locked loop, delay lock loop or injection locking circuit.
9. according to the integrated circuit of claim 7, each lock-in circuit in wherein a plurality of lock-in circuits is configurable aspect the selection frequency dividing ratio.
10. according to the integrated circuit of claim 7, also comprise:
Be suitable for being provided for a plurality of output circuits of corresponding a plurality of output interfaces of signal communication; And
Be connected to first change-over circuit of a plurality of lock-in circuits and a plurality of output circuits, first change-over circuit is suitable for selectively selected the 3rd reference signal in a plurality of the 3rd reference signals being transformed into the selected output circuit in a plurality of output circuits.
11. the integrated circuit according to claim 10 also comprises:
Be connected to the control circuit of a plurality of output circuits, thereby control circuit is suitable for that control signal is offered selected output circuit in a plurality of output circuits selects signal type in a plurality of signal types of corresponding the 3rd reference signal, and a plurality of signal types comprise at least one in the following signal type: difference, single-ended, full voltage main line to full voltage main line or part voltage rail to the part voltage rail.
12. the integrated circuit according to claim 10 also comprises:
Be connected to the control circuit of first change-over circuit, described control circuit is suitable for control signal is offered first change-over circuit so that selected the 3rd reference signal is transformed into selected output circuit.
13. the integrated circuit according to claim 10 also comprises:
Be connected to the coefficient register of first change-over circuit, coefficient register is suitable for first control coefrficient in more than first control coefrficient is offered first change-over circuit so that selected the 3rd reference signal is transformed into selected output circuit.
14. integrated circuit according to claim 13, wherein coefficient register is also connected to a plurality of convertible controlled reactance modules, and coefficient register is suitable for preserving more than second coefficient and provides more than second corresponding coefficient in the coefficient to be transformed into oscillator to control corresponding controlled reactance modules.
15. according to the integrated circuit of claim 14, wherein a plurality of convertible controlled reactance modules also comprise:
Be connected to more than second switch of coefficient register; And
Be connected to a plurality of variable capacitors of more than second switch and voltage controller accordingly, a plurality of variable capacitors are suitable for providing selected electric capacity in response to corresponding control voltage.
16. according to the integrated circuit of claim 15, wherein a plurality of convertible controlled reactance modules also comprise:
Be connected to a plurality of fixed capacitors of more than second switch accordingly, a plurality of fixed capacitors are suitable for providing selected electric capacity in response to corresponding coefficient.
17. according to the integrated circuit of claim 14, wherein more than second coefficient provides the external signal of reference frequency to determine by being calibrated to after manufacturing.
18. the integrated circuit according to claim 14 also comprises:
Be connected to the user interface of coefficient register, described user interface is suitable in response to user input the coefficient in more than first coefficient or more than second coefficient being offered coefficient register.
19. according to the integrated circuit of claim 10, wherein first change-over circuit comprises a plurality of multiplexers and demultiplexer, or a plurality of transmission transistor or cross bar switch.
20. integrated circuit according to claim 1, but wherein first frequency mask programming, its size by selecting inductor or a plurality of connections by selecting a plurality of convertible controlled reactance modules or undertaken by a plurality of sizes of selecting a plurality of convertible controlled reactance modules.
21. according to the integrated circuit of claim 1, wherein first frequency can dispose after manufacturing by a plurality of connections of selecting a plurality of convertible controlled reactance modules.
22. according to the integrated circuit of claim 1, wherein oscillator has at least one structure in the following structure: two balanced differential LC structures, difference n-MOS interconnection layout, difference p-MOS interconnection layout, the single-ended Bi Zi of examining LC structure, single-ended Hartley LC structure, difference cobasis are examined Bi Zi LC structure, difference and are collected altogether and examine Bi Zi LC structure, difference cobasis Hartley LC structure, difference and collect Hartley LC structure, single-ended Pierre Si LC oscillator or quadrature LC oscillator structure altogether.
23. according to the integrated circuit of claim 1, wherein oscillator also comprises the trsanscondutance amplifier with variable current source, variable current source is suitable for providing corresponding electric current in response to environment or operating temperature.
24. integrated circuit comprises:
The harmonic oscillator that comprises inductor and capacitor, harmonic oscillator are suitable for providing first reference signal with first frequency;
Be connected to a plurality of controlled reactance modules of harmonic oscillator, each reactance module in a plurality of reactance module is suitable for providing selected reactance to revise first frequency in response to the control voltage in a plurality of control voltages;
Be suitable for preserving first coefficient register of more than first conversion coefficient;
Be connected to more than first switch of a plurality of controlled reactance modules, the corresponding conversion coefficient of each switching response in more than first conversion coefficient in more than first switch is connected to corresponding controlled reactance modules with the selected control voltage in a plurality of control voltages;
Be connected to first frequency divider of harmonic oscillator, first frequency divider is suitable for providing second reference signal of second frequency; And
Be connected to a plurality of lock-in circuits of first frequency divider, a plurality of lock-in circuits are suitable for locking onto second reference signal and corresponding a plurality of the 3rd reference signals with a plurality of corresponding the 3rd frequencies are provided, and the frequency dividing ratio of the corresponding lock-in circuit of each the 3rd frequency from second frequency and a plurality of lock-in circuit in a plurality of corresponding the 3rd frequencies is determined.
25. according to the integrated circuit of claim 24, wherein harmonic oscillator also is suitable for moving being not locked under the situation of external reference signal.
26. the integrated circuit according to claim 24 also comprises:
Be connected to the control circuit of a plurality of lock-in circuits, control circuit is suitable for providing the time-varying frequency dividing ratio of first lock-in circuit in a plurality of lock-in circuits to change spread-spectrum the 3rd reference signal with a plurality of different the 3rd frequencies in time to provide.
27. the integrated circuit according to claim 24 also comprises:
Be connected to the control circuit of a plurality of controlled reactance modules, control circuit is suitable for providing the time-varying conversion of a plurality of control voltages to have spread-spectrum first reference signal of a plurality of different first frequencies to provide to change in time.
28. the integrated circuit according to claim 24 also comprises:
Be connected to more than second switch of a plurality of controlled reactance modules, each switching response in more than second switch is connected to harmonic oscillator in control signal with selected controlled reactance modules.
29. the integrated circuit according to claim 28 also comprises:
Be connected to the control circuit of more than second switch, control circuit is suitable for providing a plurality of controlled reactance modules to have spread-spectrum first reference signal of a plurality of different first frequencies to the time-varying conversion of harmonic oscillator to provide to change in time.
30. integrated circuit according to claim 24, wherein configurable aspect the signal type of divider circuit in selecting a plurality of signal types of second reference signal, a plurality of signal types comprise at least one in the following signal type: difference, single-ended, full voltage main line arrive the part voltage rail to full voltage main line or part voltage rail.
31. according to the integrated circuit of claim 24, each lock-in circuit in wherein a plurality of lock-in circuits is at least one in the following lock-in circuit: phase-locked loop, delay lock loop or injection locking circuit.
32. according to the integrated circuit of claim 24, each lock-in circuit in wherein a plurality of lock-in circuits is configurable aspect the selection frequency dividing ratio.
33. the integrated circuit according to claim 24 also comprises:
A plurality of output circuits; And
Be connected to second change-over circuit of a plurality of lock-in circuits and a plurality of output circuits, second change-over circuit is suitable for selected the 3rd reference signal in a plurality of the 3rd reference signals is transformed into selected output circuit in a plurality of output circuits selectively.
34. it is, configurable aspect the signal level of each output circuit in wherein a plurality of output circuits in a plurality of signal levels of the output of corresponding the 3rd reference signal of selecting to be used for a plurality of the 3rd reference signals according to the integrated circuit of claim 33.
35. the integrated circuit according to claim 33 also comprises:
Be connected to the control circuit of second change-over circuit, described control circuit is suitable for control signal is offered second change-over circuit so that selected the 3rd reference signal is transformed into selected output circuit.
36. the integrated circuit according to claim 33 also comprises:
Be connected to second coefficient register of second change-over circuit, second coefficient register is suitable for the control coefrficient in more than second control coefrficient is offered second change-over circuit so that selected the 3rd reference signal is transformed into selected output circuit.
37. according to the integrated circuit of claim 33, wherein second change-over circuit comprises a plurality of multiplexers and demultiplexer or a plurality of transmission transistor or cross bar switch.
38. according to the integrated circuit of claim 24, wherein a plurality of convertible controlled reactance modules also comprise:
Be connected to more than second switch of first coefficient register; And
Be connected to a plurality of variable capacitors of more than second switch and voltage controller accordingly, a plurality of variable capacitors are suitable for providing selected electric capacity in response to corresponding control voltage.
39. according to the integrated circuit of claim 38, wherein a plurality of convertible controlled reactance modules also comprise:
Be connected to a plurality of fixed capacitors of more than second switch accordingly, a plurality of fixed capacitors are suitable for providing selected electric capacity in response to corresponding coefficient.
40. according to the integrated circuit of claim 36, wherein more than second coefficient determined by being calibrated to second reference frequency signal after manufacturing.
41. the integrated circuit according to claim 36 also comprises:
Be connected to the user interface of first and second coefficient registers, described user interface is suitable in response to user input the coefficient in more than first conversion coefficient or more than second control coefrficient being offered coefficient register.
42. integrated circuit according to claim 24, but wherein first frequency mask programming, its size by selecting inductor or a plurality of connections by selecting a plurality of convertible controlled reactance modules or undertaken by a plurality of sizes of selecting a plurality of convertible controlled reactance modules.
43. according to the integrated circuit of claim 24, wherein first frequency can dispose after manufacturing by a plurality of connections of selecting a plurality of convertible controlled reactance modules.
44. according to the integrated circuit of claim 24, wherein oscillator has at least one structure in the following structure: two balanced differential LC structures, difference n-MOS interconnection layout, difference p-MOS interconnection layout, the single-ended Bi Zi of examining LC structure, single-ended Hartley LC structure, difference cobasis are examined Bi Zi LC structure, difference and are collected altogether and examine Bi Zi LC structure, difference cobasis Hartley LC structure, difference and collect Hartley LC structure, single-ended Pierre Si LC oscillator or quadrature LC oscillator structure altogether.
45. according to the integrated circuit of claim 1, wherein oscillator also comprises the trsanscondutance amplifier with variable current source, variable current source is suitable for providing corresponding electric current in response to environment or operating temperature.
46. according to the integrated circuit of claim 45, wherein variable current source has following at least one structure: in contrast to absolute temperature CTAT structure, be proportional to absolute temperature PTAT structure or be proportional to square PTAT of absolute temperature 2Structure.
47. configurable integrated circuit comprises:
The oscillator that comprises inductor, capacitor and trsanscondutance amplifier, oscillator is suitable for providing first reference signal with first frequency, oscillator also is suitable for moving being not locked under the situation of external reference signal, and trsanscondutance amplifier also comprises the variable current source that is suitable for providing in response to operating temperature corresponding electric current;
Be suitable for providing the voltage controller of a plurality of voltage control signals;
Be connected to a plurality of convertible controlled reactance modules of oscillator and voltage controller, each reactance module in a plurality of reactance module is suitable for providing selected reactance to revise first frequency in response to the relevant voltage control signal in a plurality of voltage control signals;
Be connected to first frequency divider of oscillator, first frequency divider is suitable for providing second reference signal of second frequency; And
Be connected to a plurality of configurable lock-in circuit of first frequency divider, a plurality of lock-in circuits are suitable for locking onto second reference signal and corresponding a plurality of the 3rd reference signals with a plurality of corresponding the 3rd frequencies are provided, and the configurable frequency dividing ratio of the corresponding lock-in circuit of each the 3rd frequency from second frequency and a plurality of lock-in circuit in a plurality of corresponding the 3rd frequencies is determined.
48. the configurable integrated circuit according to claim 47 also comprises:
Be connected to the control circuit of a plurality of configurable lock-in circuits, control circuit is suitable in time and the configurable frequency dividing ratio that becomes the selected configurable lock-in circuit of configuration changes spread-spectrum the 3rd reference signal with a plurality of different the 3rd frequencies to provide in time.
49. the configurable integrated circuit according to claim 47 also comprises:
A plurality of output circuits; And
Be connected to first change-over circuit of a plurality of lock-in circuits and a plurality of output circuits, first change-over circuit is suitable for selected the 3rd reference signal in a plurality of the 3rd reference signals is transformed into selected output circuit in a plurality of input and output circuit selectively.
50. according to the configurable integrated circuit of claim 47, wherein resonator has at least one structure in the following structure: two balanced differential LC structures, difference n-MOS interconnection layout, difference p-MOS interconnection layout, the single-ended Bi Zi of examining LC structure, single-ended Hartley LC structure, difference cobasis are examined Bi Zi LC structure, difference and are collected altogether and examine Bi Zi LC structure, difference cobasis Hartley LC structure, difference and collect Hartley LC structure, single-ended Pierre Si LC oscillator or quadrature LC oscillator structure altogether.
51. the integrated circuit according to claim 47 also comprises:
Be connected to the coefficient register of a plurality of convertible controlled reactance modules, coefficient register is suitable for preserving a plurality of coefficients and provides corresponding coefficient to be transformed into resonator to control corresponding controlled reactance modules.
CNA2006800170063A 2005-03-21 2006-03-20 Frequency controller for a monolithic clock generator and timing/frequency refrence Pending CN101176254A (en)

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