CN101039076A - Voltage-stabilizing switch power source with voltage ripple detection circuit - Google Patents

Abstract

The invention provides a voltage regulation switch power supply relating to electric technique field. The power supply output voltage dc amount is detected by a voltage ripple detecting circuit and fed back to a control circuit to control the turn-on and turn-off of the power switch tube thus to realize regulated output. The voltage ripple detecting circuit of the voltage regulation switch power supply provided by this invention comprises a high pass filtering module, a second order differentiation operation module, a linear operation module, and a clock gating/signal memory module which are connected in series sequentially. The voltage ripple of the voltage regulation switch power supply output voltage is firstly extrated and then performed by second order differentiation, linear operation and memory extension to 'resume' the dc output voltage of the voltage regulation switch power supply which is finally fed back to PWM, PFM or PSM control ciucuit so as to realize regulated output via adjusting the turn-on and turn-off of the power switch tube by the control circuit. The present invention has higher power efficiency and lower circuit cost as well as smaller power supply volume compared with prior voltage regulation switch power supply.

Description

Voltage-stabilizing switch power source with voltage ripple detection circuit

Technical field

The invention belongs to electronic technology field, relate to voltage-stabilizing switch power source, particularly the voltage-stabilizing switch power source of output voltage detection and control.

Background technology

The basic functional principle of switching power supply is exactly under the situation that input voltage changes, inner parameter changes, external load changes, control system is by detecting controlled output voltage signal, and this signal feedback carried out closed loop feedback in PWM, PFM or PSM control model, regulate the conducting and the turn-off time of main circuit device for power switching, make the output voltage stabilization of Switching Power Supply.

Fig. 1 is the AC/DC voltage-stabilizing switch power source of existing band transformer isolation.In the main circuit input stage, VAC is an AC-input voltage, representative value is 220V, Vin is process silicon bridge rectification and the filtered line input voltage of input capacitance, transformer carries out the voltage change ratio adjustment provides the isolation of input with output loop simultaneously, input stage and output stage inductance represent that with L1, L2 power switch pipe is used to control the watt level that transmits from input stage, is GND1 input stage; In the main circuit output stage, D1 is a fly-wheel diode, and C1 is an output filter capacitor, R _LBe equivalent load impedance, Vout is a VD, is GND2 output stage; The voltage-stabilizing switch power source control circuit detects output voltage V out by resistor network usually, obtain output voltage feedback signal Vf through after the DC-isolation again, Vf fed back in PWM, PFM or PSM control model carry out closed loop feedback, regulate the conducting and the turn-off time of main circuit power switch pipe, make the output voltage stabilization of voltage-stabilizing switch power source.The purpose that input stage and output stage adopt differently GND1 and GND2, carry out DC-isolation is to guarantee user power utilization safety, and DC-isolation realizes by optical coupler usually.

The deficiency of switching power supply system commonly used is: 1, output voltage detects network needs consume additional power, causes power-efficient to descend; 2, in the AC/DC transducer, input circuit and output loop are generally realized DC-isolation by optical coupler, guaranteeing user power utilization safety, and optical coupler etc. other provide the element of DC-isolation to increase system cost and volume, the power consumption of optical coupler has also reduced power-efficient simultaneously.

Because it is above not enough that electricity switching power supply system commonly used exists, therefore need to propose new output voltage detection technique and overcome, realize higher power-efficient and lower system cost.

Summary of the invention

The invention provides a kind of novel voltage stabilizing Switching Power Supply, this power supply to the detection of electric power output voltage DC quantity and feed back to conducting and the turn-off time of power control circuit with the power controlling switching tube, and then is realized voltage stabilizing output by voltage ripple detection circuit.The present invention is compared to the traditional electrical switch power supply system, has higher power-efficient, more low system cost and littler power volume.

The core concept of switching power supply of the present invention is: extract the AC portion (voltage ripple signals) in the voltage-stabilizing switch power source output voltage signal, then it is carried out the VD signal of second-order differential, linear operation and storage expansion back " recovery " voltage-stabilizing switch power source, at last with the VD signal feedback of the voltage-stabilizing switch power source of " recovery " in PWM, PFM or PSM control circuit, by the conducting and the turn-off time of control circuit adjustment power switch pipe, finally realize voltage stabilizing output.

Detailed technology scheme of the present invention is as follows:

Voltage-stabilizing switch power source with voltage ripple detection circuit as shown in Figure 2, comprises rectification, filter circuit, transformer T, power switch pipe G, control circuit, sustained diode 1, output filter capacitor C1, load RL and voltage ripple detection circuit.Input voltage V _ACBe connected to the end of transformer T secondary inductance L1 by rectification, filter circuit, the drain electrode of another termination power switch pipe G of transformer T secondary inductance L1, the drain-source of power switch pipe G connects input stage ground GND1, the output of the grid connection control circuit of power switch pipe G; The anode of the termination sustained diode 1 of transformer T secondary inductance L2, the negative electrode of sustained diode 1 connects the end after output filter capacitor C1 and the load RL parallel connection, the other end of transformer T secondary inductance L2 meets output stage ground GND2 jointly with the other end after output filter capacitor C1 and load RL are in parallel, the negative electrode of sustained diode 1 connects the input of voltage ripple detection circuit simultaneously, the input of the output connection control circuit of voltage ripple detection circuit.

In Fig. 2, when power switch pipe ended, voltage-stabilizing switch power source input stage loop disconnected, sustained diode 1 conducting, and transformer is sent to load R by the energy that secondary inductance L2 stores the power switch pipe period of contact _L, this moment, output voltage V out rose, corresponding to the output voltage ripple rising edge.Ignore the conduction voltage drop on the diode D1, output stage can equivalence be that three branch roads of transformer secondary inductance L2 and output filter capacitor C1, load RL are in parallel.For inductance L 2 place branch roads, ignore the influence of ripple to VD, it is constant that output voltage keeps, and its current-voltage correlation formula is: $V_{\mathrm{OUT}}=-L_2\frac{d{I}_{\mathrm{<figure-callout\; id="2"\; label="L"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">L</figure-callout>}2}}{\mathrm{dt}}---\left(1\right),$ Wherein, I _L2For flowing through the electric current of transformer secondary L2, L ₂Be the inductance value of transformer secondary inductance L2, V _OUTDC component for output voltage.For output filter capacitor C1 place branch road, its current-voltage correlation formula is: ${\mathrm{<figure-callout\; id="1"\; label="I\; C"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">I</figure-callout>}}_C={\mathrm{<figure-callout\; id="1"\; label="C"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">C</figure-callout>}}_1\frac{{\mathrm{dV}}_{\mathrm{out}}}{\mathrm{dt}}---\left(2\right),$ Wherein, I _C1For flowing through the electric current of output filter capacitor C1, C ₁Be the capacitance of output filter capacitor C1, V _OutThe output voltage of exporting for voltage-stabilizing switch power source that comprises ripple.When output filter capacitor equiva lent impedance during much smaller than load impedance, the electric current I of secondary inductance L2 _L2Variable quantity will be output filter capacitor C1 entirely and absorb, convolution (2) can get: $\frac{{\mathrm{<figure-callout\; id="2"\; label="dI\; L"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">dI</figure-callout>}}_L}{\mathrm{dt}}=\frac{{\mathrm{<figure-callout\; id="1"\; label="dI\; C"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">dI</figure-callout>}}_C}{\mathrm{dt}}=C_1\frac{d^2{V}_{\mathrm{out}}}{{\mathrm{dt}}^2}---\left(3\right).$ Composite type (1), (3) can get: $V_{\mathrm{OUT}}=-L_2{C}_1\frac{d^2{V}_{\mathrm{out}}}{{\mathrm{dt}}^2}---\left(4\right).$

Based on the voltage ripple detection circuit of formula (4) as shown in Figure 3, comprise high-pass filtering module, second-order differential computing module, linear operation module and clock gating/signal storage module.The output voltage V out that comprises ripple and DC quantity obtains voltage ripple signals V1 after the high-pass filtering module; Voltage ripple signals V1 is voltage signal V2 after obtaining differential behind the second-order differential computing module; The voltage signal V3 of voltage signal V2 behind the differential after obtaining linear operation behind the linear computing module; The semaphore V of the voltage signal V3 of voltage signal V3 after the linear operation after the linear operation of clock gating/signal storage module gate voltage ripple signal V1 rising edge correspondence ₃, and with semaphore V ₃Store and export, promptly obtain detecting output voltage signal (being the input signal of control circuit) Vf in the whole clock cycle.

Detected output voltage signal Vf feeds back in PWM, PFM or PSM control circuit, and when detected output voltage is lower than normal value, for pwm control circuit, the power switch pipe duty ratio will increase; For the PFM control circuit, the monocyclic ON time of power switch pipe is constant, and switching frequency will increase; For the PSM control circuit, the periodicity that does not carry out switch motion that power switch pipe is skipped will reduce, and to increase output voltage, finally realize voltage stabilizing output.When detected output voltage is higher than normal value, for pwm control circuit, the power switch pipe duty ratio will reduce; For the PFM control circuit, the monocyclic ON time of power switch pipe is constant, and switching frequency will reduce; For the PSM control circuit, the periodicity that does not carry out switch motion that power switch pipe is skipped will increase, and to reduce output voltage, finally realize voltage stabilizing output.

As shown in Figure 5, in order to strengthen the driving force of detected voltage signal, can add the voltage follow module in above-mentioned voltage ripple detection circuit, the voltage signal V3 after the linear operation obtains storing the voltage signal V4 of output and the input signal Vf of controlled circuit after the voltage follow module after clock gating/signal storage module.

In the above-mentioned voltage ripple detection circuit, described high-pass filtering module is a single order RC high pass filter, as shown in Figure 6, be in series by a capacitor C 2 and a resistance R 2, the output voltage V out that comprises ripple and DC quantity is by the tie point output voltage ripple signal V1 of capacitor C 2 backs from capacitor C 2 and resistance R 2.Whole stabilized voltage power supply output loop adopts different direct current ground respectively with voltage ripple detection circuit: output stage ground GND2 and input stage ground GND1, so that input and output loop DC-isolation, the filter network that resistance R 2 and capacitor C 2 are formed can filtering Vout DC quantity, obtain voltage ripple signals V1, the resistance R of resistance R 2 ₂Capacitance C with capacitor C 2 ₂Product R ₂* C ₂The cut-off frequency of decision high pass filter, this cut-off frequency should be chosen in and be lower than switching frequency below 1/10, to avoid the output voltage ripple signal of decaying; In the AC/DC converter, capacitor C 2 can replace optical coupler that the DC-isolation of input with output stage is provided, and guarantees user power utilization safety, therefore, needs capacitor C 2 can bear higher puncture voltage.

In the above-mentioned voltage ripple detection circuit, described second-order differential computing module is a second order mode quasi-differential device, and as shown in Figure 7, by two capacitor C 31, C32, two resistance R 31, R32 and two operational amplifier OPAMP form.The backward end of one termination, the first operational amplifier OPAMP of first capacitor C 31, the output of the first operational amplifier OPAMP connects the backward end of the second operational amplifier OPAMP by second capacitor C 32; The backward end of the first operational amplifier OPAMP links to each other by first resistance R 31 with output, and the backward end of the second operational amplifier OPAMP links to each other by second resistance R 32 with output; The end in the same way of first and second operational amplifier OPAMP meets input stage ground GND1 jointly; Voltage ripple signals V1 imports this second order mode quasi-differential device by the other end of first capacitor C 31, the voltage signal V2 behind the output output differential of the second operational amplifier OPAMP, and satisfy: ${\mathrm{<figure-callout\; id="2"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_2=R_{31}{R}_{32}{C}_{31}{C}_{32}\frac{d^2{\mathrm{<figure-callout\; id="1"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_1}{{\mathrm{<figure-callout\; id="2"\; label="dt"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">dt</figure-callout>}}^2},$ R wherein ₃₁Be the resistance of first resistance R 31, R ₃₂Be the resistance of second resistance R 32, C ₃₁Be the capacitance of first capacitor C 31, C ₃₂Be the capacitance of second capacitor C 32, V ₁Be the semaphore of voltage ripple signals V1, V ₂Semaphore for the voltage signal V2 behind the differential.

In the above-mentioned voltage ripple detection circuit, described linear operation module is an in-phase amplifier that constitutes with operational amplifier, and as shown in Figure 8, by an operational amplifier OPAMP and two resistance R 6, R7 forms.The backward end of described operational amplifier OPAMP meets input stage ground GND1 by first resistance R 6, and links to each other with its output by second resistance R 7; Voltage signal V2 behind the differential is from the input of end in the same way of operational amplifier OPAMP, and the output of operational amplifier OPAMP is exported the output voltage V 3 after the linear computing, and satisfies: ${\mathrm{<figure-callout\; id="3"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_3=(1+\frac{R_7}{R_6}){\mathrm{<figure-callout\; id="2"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_2,$ Wherein, R ₆Be the resistance of first resistance R 6, R ₇Be the resistance of second resistance R 7, V ₂Be the semaphore of the voltage signal V2 behind the differential, V ₃Semaphore for the output voltage V after the linear computing 3.

In the above-mentioned voltage ripple detection circuit, described linear operation module also can be the inverting amplifier that constitutes with operational amplifier, and as shown in Figure 9, by an operational amplifier OPAMP and two resistance R 4, R5 forms.The backward end of described operational amplifier OPAMP links to each other with an end of first resistance R 4, and links to each other with its output by second resistance R 5, its forward termination input stage ground GND1; Voltage signal V2 behind the differential is from the other end input of first resistance R 4, and the output of operational amplifier OPAMP is exported the output voltage V 3 after the linear computing, and satisfies: ${\mathrm{<figure-callout\; id="3"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_3=-\frac{R_5}{R_4}{\mathrm{<figure-callout\; id="2"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_2,$ Wherein, R ₄Be the resistance of first resistance R 4, R ₅Be the resistance of second resistance R 5, V ₂For being the semaphore of the voltage signal V2 behind the differential, V ₃Semaphore for the output voltage V after the linear computing 3.

The purpose of selecting the employing operational amplifier to build the linear amplification module is to improve the driving force of amplified signal, improves simultaneously and amplifies precision, can select homophase or inverting amplifier for use according to system's needs in building detection system.

In the above-mentioned voltage ripple detection circuit, described clock gating/signal storage module (as shown in figure 10) is made up of a gated clock circuit, a switch and a storage capacitance C4.One end of described switch is connected to the end of storage capacitance C4, another termination input stage ground GND1 of storage capacitance C4, and the gated clock signal that the gated clock circuit is produced acts on switch; Output voltage V 3 after the linear computing is from the other end input of switch, and the voltage signal V4 of storage output is from the tie point output of capacitor C 4 with switch.

Because VD Vout can only be characterized by the second dervative of voltage ripple signals V1 rising edge, only in ripple rising edge time corresponding section effective (promptly in the turn-off time section corresponding to power switch pipe G), and switch power supply system requires output voltage control signal all effective in the whole clock cycle, therefore need carry out clock gating and signal storage, i.e. the semaphore V of voltage signal V3 after the linear operation of gating V1 rising edge correspondence ₃, and with semaphore V ₃Storage, output signal amount V in the whole clock cycle then ₃,, finally obtain detecting output voltage signal Vf (input signal of control circuit) up to the arrival of next gated clock.Clock gating/signal storage module relies on capacitor C 4 to carry out signal storage, and when switch closure, capacitor C 4 both end voltage are charged to the V in the gating time ₃Value, after switch disconnected, capacitor C 4 was kept this voltage, thereby this voltage signal can be expanded to whole switch periods by gating time, simulated control so that the back level to be provided.The value of capacitor C 4 must rationally be chosen, if too big, then is difficult to be charged to corresponding signal level V by the voltage signal V3 after the linear operation ₃If too little, then when disconnecting, switch is difficult in whole switch periods, keep signal.

Described gated clock circuit can be a pierce circuit, and the gated clock signal that pierce circuit produced has the identical clock cycle with power switch pipe G, and its gating time section is in during the voltage ripple signals V1 rising edge; Described switch can be realized that less switching tube conducting resistance will reduce the requirement to the voltage signal V3 driving force after the linear operation by switching transistor.It is the method detection output voltage of the fixedly gated clock of power switch pipe G operating frequency that the present invention adopts clock frequency, being about to output voltage and gating time section fixes, by being set, maximum duty cycle Dmax guaranteed output switching tube G must be in off-state in last (1-Dmax) time period of each switch periods, corresponding to the output voltage ripple rising edge, by the output voltage gated clock being fixed in this (1-Dmax) in the time period, guarantee to detect output voltage signal Vf.

Described voltage follow module (as shown in figure 11) is made up of an operational amplifier OPAMP, and the backward end of described operational amplifier links to each other with output; Storage output voltage V 4 is from the input of end in the same way of operational amplifier OPAMP, and the output output of operational amplifier OPAMP detects output voltage signal Vf; Its role is to strengthen the driving force of control circuit input signal Vf.

Each signal waveform schematic diagram of voltage detecting circuit part in the voltage-stabilizing switch power source of the present invention system, as shown in Figure 4.Fig. 4 (a) is the control signal Vc of power switch pipe, is 50% to be that example describes with duty ratio, Dmin and Dmax minimum and the maximum duty cycle for being provided with.Fig. 4 (b) is the output voltage waveforms Vout of whole stabilized voltage power supply, and Fig. 4 (c) is through the ripple voltage signal V1 after the high-pass filtering.Comparison diagram 4 (a) and Fig. 4 (b), Fig. 4 c), when power switch pipe is in closure state, corresponding to the voltage ripple trailing edge, when power switch pipe is in off-state, corresponding to the voltage ripple rising edge.Fig. 4 (d) is for carrying out the voltage signal V2 after the second-order differential computing to ripple voltage signal V1, Fig. 4 (e) carries output voltage information for the voltage signal V2 after differentiating being carried out the voltage signal V3 after the linear operation among the voltage signal V3 after the linear operation corresponding with the ripple voltage signal V1 rising edge time period.Fig. 4 (f) is an output voltage gated clock waveform, the present invention adopts the fixedly detection method of gated clock, therefore, need to be provided with the maximum duty cycle Dmax shown in Fig. 4 (a), the guaranteed output switching tube has a fixing turn-off time section, to guarantee that voltage ripple has one period set time and is in rising edge, guarantee that finally fixedly gated clock can detect output voltage signal Vf.Fig. 4 (g) is detected output voltage V f, and output voltage signal Vf feeds back in PWM, PFM or PSM control circuit, adjusts the conducting and the turn-off time of power switch pipe, with regulated output voltage.

Voltage-stabilizing switch power source with ripple detection circuit of the present invention is compared with existing voltage-stabilizing switch power source, has the following advantages:

1, utilizes ripple detection circuit to replace traditional output voltage detecting circuit, eliminated the dc power of traditional output voltage detecting circuit, thereby improved the efficient of voltage-stabilizing switch power source.

2, replace optical coupler with electric capacity and import DC-isolation with output loop, reduce the power-supply system volume, reduce system cost.

In the AC/DC transducer, need input circuit and output loop to realize DC-isolation, to guarantee user power utilization safety.The present invention carries out DC-isolation by the capacitor C in the high pass filter 2, replaces optical coupler, can reduce the power-supply system volume, reduces the power supply cost.

Description of drawings

Fig. 1: the AC/DC voltage-stabilizing switch power source schematic diagram of band transformer isolation.

Fig. 2: the voltage-stabilizing switch power source circuit diagram with voltage ripple detection circuit of the present invention.

Fig. 3: voltage ripple detection circuit figure in the voltage-stabilizing switch power source of the present invention.

Fig. 4: each signal waveform schematic diagram of voltage ripple detection circuit part in the voltage-stabilizing switch power source of the present invention.

Fig. 5: the voltage ripple detection circuit schematic diagram that has added voltage follower circuit in the voltage-stabilizing switch power source of the present invention.

Fig. 6: the high-pass filtering module circuit diagram of voltage ripple detection circuit in the voltage-stabilizing switch power source of the present invention.

Fig. 7: 2 rank of the voltage ripple detection circuit module circuit diagram of differentiating in the voltage-stabilizing switch power source of the present invention.

Fig. 8: the linear operation module circuit diagram that the handy inverting amplifier of voltage ripple detection circuit constitutes in the voltage-stabilizing switch power source of the present invention.

Fig. 9: the linear operation module circuit diagram that the handy in-phase amplifier of voltage ripple detection circuit constitutes in the voltage-stabilizing switch power source of the present invention.

Figure 10: the clock of voltage ripple detection circuit gating/signal storage module circuit diagram in the voltage-stabilizing switch power source of the present invention.

Figure 11: the voltage follower circuit figure of voltage ripple detection circuit in the voltage-stabilizing switch power source of the present invention.

Figure 12: utilize voltage ripple detection circuit schematic diagram in the voltage-stabilizing switch power source of the present invention that the part digital circuit realizes.

Embodiment

Execution mode one

Voltage-stabilizing switch power source with voltage ripple detection circuit as shown in Figure 2, comprises rectification, filter circuit, transformer T, power switch pipe G, control circuit, sustained diode 1, output filter capacitor C1, load RL and voltage ripple detection circuit.Input voltage V _ACBe connected to the end of transformer T secondary inductance L1 by rectification, filter circuit, the drain electrode of another termination power switch pipe G of transformer T secondary inductance L1, the drain-source of power switch pipe G connects input stage ground GND1, the output of the grid connection control circuit of power switch pipe G; The anode of the termination sustained diode 1 of transformer T secondary inductance L2, the negative electrode of sustained diode 1 connects the end after output filter capacitor C1 and the load RL parallel connection, the other end of transformer T secondary inductance L2 meets output stage ground GND2 jointly with the other end after output filter capacitor C1 and load RL are in parallel, the negative electrode of sustained diode 1 connects the input of voltage ripple detection circuit simultaneously, the input of the output connection control circuit of voltage ripple detection circuit.

Described voltage ripple detection circuit comprises high-pass filtering module, second-order differential computing module, linear operation module, clock gating/signal storage module and voltage follow module as shown in Figure 5.The output voltage V out that comprises ripple and DC quantity obtains voltage ripple signals V1 after the high-pass filtering module; Voltage ripple signals V1 is voltage signal V2 after obtaining differential behind the second-order differential computing module; The voltage signal V3 of voltage signal V2 behind the differential after obtaining linear operation behind the linear computing module; The semaphore V of the voltage signal V3 of voltage signal V3 after the linear operation after the linear operation of clock gating/signal storage module gate voltage ripple signal V1 rising edge correspondence ₃, and with semaphore V ₃Store and, obtain storing the voltage signal V4 of output and after the voltage follow module, obtain detecting output voltage signal (being the input signal of control circuit) Vf in whole clock cycle output.

In the above-mentioned voltage ripple detection circuit, described high-pass filtering module is a single order RC high pass filter, as shown in Figure 6, be in series by a capacitor C 2 and a resistance R 2, the output voltage V out that comprises ripple and DC quantity is by the tie point output voltage ripple signal V1 of capacitor C 2 backs from capacitor C 2 and resistance R 2.The converter output loop adopts different direct current ground respectively with detection system: output stage ground GND2 and input stage ground GND1, so that input and output loop DC-isolation, the filter network that resistance R 2 and capacitor C 2 are formed can filtering Vout DC quantity, obtain voltage ripple signals V1, the resistance R of resistance R 2 ₂Capacitance C with capacitor C 2 ₂Product R ₂* C ₂The cut-off frequency of decision high pass filter, this cut-off frequency should be chosen in and be lower than switching frequency below 1/10, to avoid the output voltage ripple signal of decaying; In the AC/DC converter, capacitor C 2 can replace optical coupler that the DC-isolation of input with output stage is provided, and guarantees user power utilization safety, therefore, needs capacitor C 2 can bear higher puncture voltage.

Described second-order differential computing module is a second order mode quasi-differential device, and as shown in Figure 7, by two capacitor C 31, C32, two resistance R 31, R32 and two operational amplifier OPAMP form.The backward end of one termination, the first operational amplifier OPAMP of first capacitor C 31, the output of the first operational amplifier OPAMP connects the backward end of the second operational amplifier OPAMP by second capacitor C 32; The backward end of the first operational amplifier OPAMP links to each other by first resistance R 31 with output, and the backward end of the second operational amplifier OPAMP links to each other by second resistance R 32 with output; The end in the same way of first and second operational amplifier OPAMP meets input stage ground GND1 jointly; Voltage ripple signals V1 imports this second order mode quasi-differential device by the other end of first capacitor C 31, the voltage signal V2 behind the output output differential of the second operational amplifier OPAMP, and satisfy: ${\mathrm{<figure-callout\; id="2"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_2=R_{31}{R}_{32}{C}_{31}{C}_{32}\frac{d^2{\mathrm{<figure-callout\; id="1"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_1}{{\mathrm{<figure-callout\; id="2"\; label="dt"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">dt</figure-callout>}}^2},$ R wherein ₃₁Be the resistance of first resistance R 31, R ₃₂Be the resistance of second resistance R 32, C ₃₁Be the capacitance of first capacitor C 31, C ₃₂Be the capacitance of second capacitor C 32, V ₁Be the semaphore of voltage ripple signals V1, V ₂Semaphore for the voltage signal V2 behind the differential.

Described linear operation module is the in-phase amplifier that a usefulness operational amplifier constitutes, and as shown in Figure 8, by an operational amplifier OPAMP and two resistance R 6, R7 forms.The backward end of described operational amplifier OPAMP meets input stage ground GND1 by resistance R 6, and links to each other with its output by resistance R 7; Voltage signal V2 behind the differential is from the input of end in the same way of operational amplifier OPAMP, and the output of operational amplifier OPAMP is exported the output voltage V 3 after the linear computing, and satisfies: ${\mathrm{<figure-callout\; id="3"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_3=(1+\frac{R_7}{R_6}){\mathrm{<figure-callout\; id="2"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_2,$ Wherein, R ₆Be the resistance of first resistance R 6, R ₇Be the resistance of second resistance R 7, V ₂Be the semaphore of the voltage signal V2 behind the differential, V ₃Semaphore for the output voltage V after the linear computing 3.

Described linear operation module also can be the inverting amplifier that constitutes with operational amplifier, and as shown in Figure 9, by an operational amplifier OPAMP and two resistance R 4, R5 forms.The backward end of described operational amplifier OPAMP links to each other with an end of resistance R 4, and links to each other with its output by resistance R 5, its forward termination input stage ground GND1; Voltage signal V2 behind the differential is from the other end input of resistance R 4, and the output of operational amplifier OPAMP is exported the output voltage V 3 after the linear computing, and satisfies: ${\mathrm{<figure-callout\; id="3"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_3=-\frac{R_5}{R_4}{\mathrm{<figure-callout\; id="2"\; label="V"\; filenames="A20071004898900151.png,A20071004898900161.png"\; state="\{\{state\}\}">V</figure-callout>}}_2,$ Wherein, R ₄Be the resistance of first resistance R 4, R ₅Be the resistance of second resistance R 5, V ₂For being the semaphore of the voltage signal V2 behind the differential, V ₃Semaphore for the output voltage V after the linear computing 3.

Described clock gating/signal storage module (as shown in figure 10) is made up of a gated clock circuit, a switching tube and a storage capacitance C4.One end of described switching tube is connected to an end of capacitor C 4, another termination input stage ground GND1 of capacitor C 4, and the gated clock signal that the gated clock circuit is produced acts on switching tube; Output voltage V 3 after the linear computing is from the other end input of switching tube, and the voltage signal V4 of storage output gets tie point output from capacitor C 4 and switching tube.

Described gated clock circuit can be a pierce circuit, and the gated clock signal that pierce circuit produced has the identical clock cycle with power switch pipe G, and its gating time section is in during the voltage ripple signals V1 rising edge; Described switching tube can be realized that less switching tube conducting resistance will reduce the requirement to the voltage signal V3 driving force after the linear operation by switching transistor.

Described voltage follow module (as shown in figure 11) is made up of an operational amplifier OPAMP, and the backward end of described operational amplifier links to each other with output; Storage output voltage V 4 is from the input of end in the same way of operational amplifier OPAMP, the input signal Vf of the output output control circuit of operational amplifier OPAMP; Its role is to strengthen the driving force of control circuit input signal Vf.

Execution mode two

Voltage-stabilizing switch power source with voltage ripple detection circuit as shown in Figure 2, comprises rectification, filter circuit, transformer T, power switch pipe G, control circuit, sustained diode 1, output filter capacitor C1, load RL and voltage ripple detection circuit.Input voltage V _ACBe connected to the end of transformer T secondary inductance L1 by rectification, filter circuit, the drain electrode of another termination power switch pipe G of transformer T secondary inductance L1, the drain-source of power switch pipe G connects input stage ground GND1, the output of the grid connection control circuit of power switch pipe G; The anode of the termination sustained diode 1 of transformer T secondary inductance L2, the negative electrode of sustained diode 1 connects the end after output filter capacitor C1 and the load RL parallel connection, the other end of transformer T secondary inductance L2 meets output stage ground GND2 jointly with the other end after output filter capacitor C1 and load RL are in parallel, the negative electrode of sustained diode 1 connects the input of voltage ripple detection circuit simultaneously, the input of the output connection control circuit of voltage ripple detection circuit.

Described voltage ripple detection circuit as shown in figure 12, comprises high-pass filtering module, linear amplification module, A/D modular converter, second order numerical differentiation computing module, numerical linear computing module and clock gating/digital latch module.The output voltage V out that comprises ripple and DC quantity obtains voltage ripple signals V1 after the high-pass filtering module; Voltage ripple signals V1 obtains the voltage ripple signals V11 of linear amplification behind linear amplification module; The voltage signal V11 of linear amplification converts digital voltage ripple signal V13 to through the A/D modular converter; Digital voltage ripple signal V13 voltage signal V2 after second order numerical differentiation computing module obtains differential; The voltage signal V3 of voltage signal V2 behind the differential after obtaining linear operation behind the numerical linear computing module; The semaphore V of the voltage signal V3 of voltage signal V3 after the linear operation after the linear operation of clock gating/digital latch module gate voltage ripple signal V1 rising edge correspondence ₃, and with semaphore V ₃Store and export, promptly obtain detecting output voltage signal (being the input signal of control circuit) Vf in the whole clock cycle.

Claims (10)

1, the voltage-stabilizing switch power source that has voltage ripple detection circuit comprises rectification, filter circuit, transformer (T), power switch pipe (G), control circuit, fly-wheel diode (D1), output filter capacitor (C1), load (RL) and voltage ripple detection circuit; Input voltage (V _AC) be connected to an end of transformer (T) secondary inductance (L1) by rectification, filter circuit, the drain electrode of another termination power switch pipe (G) of transformer (T) secondary inductance (L1), the drain-source of power switch pipe (G) connects input stage ground (GND1), the output of the grid connection control circuit of power switch pipe (G); The anode of one termination fly-wheel diode (D1) of transformer (T) secondary inductance (L2), the negative electrode of fly-wheel diode (D1) connects the end after output filter capacitor (C1) and load (RL) parallel connection, the other end of transformer (T) secondary inductance (L2) connects output stage ground (GND2) jointly with the other end after output filter capacitor (C1) and load (RL) are in parallel, the negative electrode of fly-wheel diode (D1) connects the input of voltage ripple detection circuit simultaneously, the input of the output connection control circuit of voltage ripple detection circuit;

Described voltage ripple detection circuit comprises high-pass filtering module, second-order differential computing module, linear operation module and clock gating/signal storage module; The output voltage (Vout) that comprises ripple and DC quantity obtains voltage ripple signals (V1) after the high-pass filtering module; Voltage ripple signals (V1) is voltage signal (V2) after obtaining differential behind the second-order differential computing module; The voltage signal (V3) of voltage signal behind the differential (V2) after obtaining linear operation behind the linear computing module; The semaphore V of the voltage signal (V3) of the voltage signal after the linear operation (V3) after the linear operation of clock gating/signal storage module gate voltage ripple signal (V1) rising edge correspondence ₃, and with semaphore V ₃Store and export, promptly obtain detecting output voltage signal (Vf) in the whole clock cycle.

2, the voltage-stabilizing switch power source with voltage ripple detection circuit according to claim 1, it is characterized in that, described voltage ripple detection circuit also comprises a voltage follow module, and the voltage signal after the linear operation (V3) obtains storing the voltage signal (V4) of output and obtain detecting output voltage signal (Vf) after the voltage follow module after clock gating/signal storage module.

3, the voltage-stabilizing switch power source with voltage ripple detection circuit according to claim 1 and 2, it is characterized in that, described high-pass filtering module is a single order RC high pass filter, be in series by electric capacity (C2) and a resistance (R2), the output voltage (Vout) that comprises ripple and DC quantity is by the tie point output voltage ripple signal (V1) of electric capacity (C2) back from electric capacity (C2) and resistance (R2).

4, the voltage-stabilizing switch power source with voltage ripple detection circuit according to claim 1 and 2, it is characterized in that, described second-order differential computing module is a second order mode quasi-differential device, by two electric capacity (C31, C32), two resistance (R31, R32) and two operational amplifiers (OPAMP) are formed; The backward end of one termination, first operational amplifier (OPAMP) of first electric capacity (C31), the output of first operational amplifier (OPAMP) connect the backward end of second operational amplifier (OPAMP) by second electric capacity (C32); The backward end of first operational amplifier (OPAMP) links to each other by first resistance (R31) with output, and the backward end of second operational amplifier (OPAMP) links to each other by second resistance (R32) with output; The end in the same way of first and second operational amplifier (OPAMP) connects input stage ground (GND1) jointly; Voltage ripple signals (V1) is imported this second order mode quasi-differential device by the other end of first electric capacity (C31), the voltage signal (V2) behind the output output differential of second operational amplifier (OPAMP), and satisfy: $V_2=R_{31}{R}_{32}{C}_{31}{C}_{32}\frac{d^2{V}_1}{{\mathrm{dt}}^2},$ R wherein ₃₁Be the resistance of first resistance (R31), R ₃₂Be the resistance of second resistance (R32), C ₃₁Be the capacitance of first electric capacity (C31), C ₃₂Be the capacitance of second electric capacity (C32), V ₁Be voltage ripple signals (V1) semaphore, V ₂Be the voltage signal behind the differential (V2) semaphore.

5, the voltage-stabilizing switch power source with voltage ripple detection circuit according to claim 1 and 2, it is characterized in that, described linear operation module is an in-phase amplifier that constitutes with operational amplifier, by an operational amplifier (OPAMP) and two resistance (R6, R7) compositions; The backward end of described operational amplifier (OPAMP) connects input stage ground (GND1) by first resistance (R6), and links to each other with its output by second resistance (R7); Voltage signal behind the differential (V2) is from the input of end in the same way of operational amplifier (OPAMP), and the output of operational amplifier (OPAMP) is exported the output voltage (V3) after the linear computing, and satisfies: $V_3=(1+\frac{R_7}{R_6})V_2,$ Wherein, R ₆Be the resistance of first resistance (R6), R ₇Be the resistance of second resistance (R7), V ₂Be the semaphore of the voltage signal behind the differential (V2), V ₃Semaphore for the output voltage after the linear computing (V3).

6, the voltage-stabilizing switch power source with voltage ripple detection circuit according to claim 1 and 2, it is characterized in that, described linear operation module also can be the inverting amplifier that constitutes with operational amplifier, by an operational amplifier (OPAMP) and two resistance (R4, R5) compositions; The backward end of described operational amplifier (OPAMP) links to each other with an end of first resistance (R4), and links to each other with its output by second resistance (R5), its forward termination input stage ground (GND1); Voltage signal behind the differential (V2) is from the other end input of first resistance (R4), and the output of operational amplifier (OPAMP) is exported the output voltage (V3) after the linear computing, and satisfies: $V_3=-\frac{R_5}{R_4}{V}_2,$ Wherein, R ₄Be the resistance of first resistance (R4), R ₅Be the resistance of second resistance (R5), V ₂For being the semaphore of the voltage signal (V2) behind the differential, V ₃Semaphore for the output voltage after the linear computing (V3).

7, the voltage-stabilizing switch power source with voltage ripple detection circuit according to claim 1 and 2 is characterized in that, described clock gating/signal storage module is made up of a gated clock circuit, switch and a storage capacitance (C4); One end of described switch is connected to an end of storage capacitance (C4), another termination input stage ground (GND1) of storage capacitance (C4), and the gated clock signal that the gated clock circuit is produced acts on switch; Output voltage after the linear computing (V3) is from the other end input of switch, and the voltage signal (V4) of storage output is from the tie point output of storage capacitance (C4) with switch.

8, the voltage-stabilizing switch power source with voltage ripple detection circuit according to claim 7, it is characterized in that, described gated clock circuit can be a pierce circuit, the gated clock signal that pierce circuit produced has the identical clock cycle with power switch pipe (G), and its gating time section is in during voltage ripple signals (V1) rising edge; Described switch can be realized by switching transistor.

9, the voltage-stabilizing switch power source with voltage ripple detection circuit according to claim 2 is characterized in that, described voltage follow module is made up of an operational amplifier (OPAMP), and the backward end of described operational amplifier links to each other with output; Storage output voltage (V4) is from the input of end in the same way of operational amplifier (OPAMP), and the output output of operational amplifier (OPAMP) detects output voltage signal (Vf).

10, the voltage-stabilizing switch power source with voltage ripple detection circuit according to claim 1, it is characterized in that, described voltage ripple detection circuit comprises high-pass filtering module, linear amplification module, A/D modular converter, second order numerical differentiation computing module, numerical linear computing module and clock gating/digital latch module; The output voltage (Vout) that comprises ripple and DC quantity obtains voltage ripple signals (V1) after the high-pass filtering module; Voltage ripple signals (V1) obtains the voltage ripple signals (V11) of linear amplification behind linear amplification module; The voltage signal of linear amplification (V11) converts digital voltage ripple signal (V13) to through the A/D modular converter; Digital voltage ripple signal (V13) is voltage signal (V2) after second order numerical differentiation computing module obtains differential; The voltage signal (V3) of voltage signal behind the differential (V2) after obtaining linear operation behind the numerical linear computing module; The semaphore V of the voltage signal (V3) of the voltage signal after the linear operation (V3) after the linear operation of clock gating/digital latch module gate voltage ripple signal (V1) rising edge correspondence ₃, and with semaphore V ₃Store and export, promptly obtain detecting output voltage signal (Vf) in the whole clock cycle.

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