CN211528517U - Low-power digital multifunctional meter - Google Patents
Low-power digital multifunctional meter Download PDFInfo
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- CN211528517U CN211528517U CN201921870823.4U CN201921870823U CN211528517U CN 211528517 U CN211528517 U CN 211528517U CN 201921870823 U CN201921870823 U CN 201921870823U CN 211528517 U CN211528517 U CN 211528517U
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Abstract
The utility model relates to a digital ammeter field particularly, relates to a low-power consumption digital multifunctional meter, wherein low-power consumption digital multifunctional meter includes: the processor module and the conversion module are electrically connected with the processor module; the conversion module comprises a switching circuit, a capacitance measuring circuit, a resistance measuring circuit and a transistor beta value measuring circuit; the switching circuit switches different circuits according to different components to be measured; the processor module is suitable for receiving corresponding detection information sent by the capacitance measuring circuit, the resistance measuring circuit, the transistor beta value measuring circuit and the processor module so as to complete the measurement of the physical quantity of the component to be measured; different physical quantity measurement of different components can be realized.
Description
Technical Field
The utility model relates to a digital ammeter field particularly, relates to a low-power consumption digital multifunctional meter.
Background
In the related art, when a multimeter measures a small physical quantity, because the measurement precision of the multimeter is not accurate enough, the displayed precision digit is not complete, so that the obtained numerical value of the physical quantity is not accurate, and the power consumed by the current multimeter when measuring the physical quantity is large, so that the multimeter needs to consume more electric energy.
SUMMERY OF THE UTILITY MODEL
The utility model aims at providing a low-power consumption digital multifunctional meter to reduce the electric energy that consumes when measuring the physical quantity.
The embodiment of the utility model provides a low-power consumption digital multifunctional meter, include: the processor module and the conversion module are electrically connected with the processor module; the conversion module comprises a switching circuit, a capacitance measuring circuit, a resistance measuring circuit and a transistor beta value measuring circuit; the switching circuit switches different circuits according to different components to be measured; the processor module is suitable for receiving corresponding detection information sent by the capacitance measuring circuit, the resistance measuring circuit, the transistor beta value measuring circuit and the processor module so as to measure the physical quantity of the component to be measured.
Further, the switching circuit comprises a plurality of electronic sockets and a keyboard circuit; the keyboard circuit is adapted to send selection information to the processor module; the electronic sockets are respectively arranged at the testing ends of the capacitance measuring circuit, the resistance measuring circuit and the transistor beta value measuring circuit.
Further, the capacitance measuring circuit comprises a capacitance oscillation sub-circuit and a capacitance measuring sub-circuit; the capacitance measuring sub-circuit is connected with the input end of the capacitance oscillating sub-circuit; and the output end of the capacitance oscillation sub-circuit is connected with a component to be measured.
Further, the feedback end of the capacitive oscillation sub-circuit is connected with the processor module so as to send the frequency signal of the capacitive oscillation sub-circuit to the processor module.
Further, the capacitance measuring sub-circuit comprises a resistance selection switch and a plurality of resistors;
and a plurality of resistors with different resistance values are connected in series or in parallel and then are connected into the capacitor oscillator sub-circuit through the selection switch.
Further, the resistance measurement circuit comprises a resistance oscillation sub-circuit and a resistance measuring sub-circuit; the resistance measuring sub-circuit is connected with the oscillation end of the resistance oscillation sub-circuit; the input end of the resistance oscillation sub-circuit is connected with a component to be measured; the resistance oscillation sub-circuit is adapted to send resistance oscillation frequency data to the processor module.
Further, the resistance measuring sub-circuit comprises a capacitance selection switch and a plurality of capacitors connected in parallel; the capacitors with different capacities are connected in parallel through the selection switch and then are connected to the oscillation end of the resistance oscillation sub-circuit.
Further, the transistor beta value measuring circuit comprises a transistor switching sub-circuit and a voltage collecting sub-circuit; the input end of the transistor switching sub-circuit is connected with a component; and the output end of the transistor switching sub-circuit is connected with the voltage acquisition sub-circuit.
Further, the transistor switching sub-circuit includes a selection switch, a first transistor circuit, and a second transistor circuit; the selection switches are respectively connected with the input ends of the first transistor circuit and the second transistor circuit.
Further, the voltage acquisition sub-circuit comprises a sampling resistor; the sampling resistor is suitable for sending sampling data to the processor module so as to generate a beta value of the component to be measured.
Compared with the prior art, the embodiment of the utility model provides a following beneficial effect has: the switching circuit selects a capacitance measuring circuit, a resistance measuring circuit or a transistor beta value measuring circuit according to the components; the processor module detects the physical quantity of the component to be measured according to corresponding detection information sent by different measuring circuits; the circuit design is simplified, and various components and corresponding physical quantities thereof can be measured.
Meanwhile, the processor module can be a single chip microcomputer, the single chip microcomputer is used as a core control chip, accurate measurement of an alternating current voltage value, a direct current voltage value, a resistance value, a capacitance value and a triode beta value is achieved, the single chip microcomputer can generate a 10 Hz-100 kHz sine wave signal source, the resistance is measured through the voltage division principle of the resistance, measurement of voltages with different ranges is achieved through amplification and reduction of the voltages through operational amplification, and the capacitance value is obtained through calculation of oscillation frequency of the single chip microcomputer. And low-power consumption segment liquid crystal can be used as a display, so that the functions of measuring voltage, resistance, capacitance, triode beta parameters and sine wave signal sources with low power consumption and high precision are really realized.
Drawings
The present invention will be further explained with reference to the drawings and examples.
FIG. 1 is a schematic block diagram of a low power consumption digital multifunctional watch according to the present invention;
FIG. 2 is a circuit diagram of a display module of the low power consumption digital multifunctional watch of the present invention;
FIG. 3 shows a circuit diagram of a capacitance measuring circuit of the low power consumption digital multifunctional meter of the present invention;
fig. 4 shows a circuit diagram of a resistance measuring circuit of the low power consumption digital multifunctional meter of the invention;
fig. 5 shows a circuit diagram of the transistor beta value measuring circuit of the low power consumption digital multifunctional meter of the present invention.
Detailed Description
The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic drawings and illustrate the basic structure of the present invention only in a schematic manner, and thus show only the components related to the present invention.
As shown in fig. 1 to 5, an embodiment of the present invention provides a low power consumption digital multifunctional meter, including: the processor module and the conversion module are electrically connected with the processor module; the conversion module comprises a switching circuit, a capacitance measuring circuit, a resistance measuring circuit and a transistor beta value measuring circuit; the switching circuit switches different circuits according to different components to be measured; the processor module is suitable for receiving corresponding detection information sent by the capacitance measuring circuit, the resistance measuring circuit, the transistor beta value measuring circuit and the processor module so as to complete the measurement of the physical quantity of the component to be measured; the utility model relates to a low power consumption digital multifunctional meter, which needs to measure the physical quantity of the connected components; the circuits for measuring the resistance value, the capacitance value and the beta value of the transistor cannot be used universally, so that different circuits are required to be designed to measure different physical quantities; when the physical quantity of the component is measured, different measuring circuits are switched through the switching circuit so as to realize the measurement of the same physical quantity.
Meanwhile, the processor module can be a single chip microcomputer, the single chip microcomputer is used as a core control chip, accurate measurement of an alternating current voltage value, a direct current voltage value, a resistance value, a capacitance value and a triode beta value is achieved, the single chip microcomputer can generate a 10 Hz-100 kHz sine wave signal source, the resistance is measured through the voltage division principle of the resistance, measurement of voltages with different ranges is achieved through amplification and reduction of the voltages through operational amplification, and the capacitance value is obtained through calculation of oscillation frequency of the single chip microcomputer. And low-power consumption segment liquid crystal can be used as a display, so that the functions of measuring voltage, resistance, capacitance, triode beta parameters and sine wave signal sources with low power consumption and high precision are really realized.
Specifically, the processor module is a single chip microcomputer, and can be but is not limited to an MSP430 single chip microcomputer; the MSP430 singlechip has the characteristics of low voltage and ultralow power consumption; the working voltage is 3.3V, the working current is 1.3mA in the waiting mode, the working current is only 0.5mA in the working mode that the RAM is kept closed, and the high precision can be obtained by the 12-bit analog-to-digital converter (ADC12), the trouble brought to the design of a circuit board by using a special analog-to-digital converter is omitted, and the large-capacity storage space is provided. The memory comprises up to 60k Flash ROM and 2kRAM, and the storage space can completely meet the requirements of programs and data; the processor module also comprises a hardware multiplier which is independent of the operation of multiplication performed by the single chip microcomputer, so that the utilization efficiency of the single chip microcomputer is improved while the multiplication speed is improved.
In this embodiment, the processor module is further connected to a display module for displaying the measured physical quantity; the display module is adapted to employ an LCD1602 display module.
In this embodiment, the switching circuit includes a plurality of electronic sockets and a keyboard circuit; the keyboard circuit is adapted to send selection information to the processor module; the electronic sockets are respectively arranged at the testing ends of the capacitance measuring circuit, the resistance measuring circuit and the transistor beta value measuring circuit; the type of the component to be measured is set through a keyboard circuit, so that the single chip microcomputer can select a corresponding algorithm according to the corresponding component; the electronic socket is convenient for accessing components and parts and can ensure stable transmission of data during multiple measurements.
In the present embodiment, the algorithms are all conventional algorithms for those skilled in the art.
In this embodiment, the capacitance measuring circuit includes a capacitance oscillating sub-circuit and a capacitance measuring sub-circuit; the capacitance measuring sub-circuit is connected with the input end of the capacitance oscillating sub-circuit; the output end of the capacitance oscillation sub-circuit is connected with a component to be measured; the capacitance oscillation sub-circuit is suitable for forming a multi-resonant oscillation circuit by adopting a 555 timer and a capacitance range sub-circuit, the capacitance value can be measured and calculated through the oscillation period according to a formula C of the oscillation period which is known as a formula T/1.4R, and the oscillation period can be provided by the processor module.
In addition, a 555 timer and a resistor to be measured form a multi-harmonic oscillation circuit, the oscillation period of the oscillation circuit is measured by the timer of the single chip microcomputer, the resistor to be measured or a non-polar capacitor is indirectly measured through the measurement period, and an RC oscillation circuit experiment is verified. The resistance sensitivity was 0.01 Ω and the capacitance sensitivity was 0.01 pF.
In this embodiment, the feedback end of the capacitive oscillation sub-circuit is connected to the processor module to send the frequency signal of the capacitive oscillation sub-circuit to the processor module; the 555 timer is suitable for sending a frequency signal f to the processor module, and then the timer of the processor module is used for measuring the oscillation period of the oscillation circuit, so that the capacitance value of the component to be measured is measured and calculated.
In this embodiment, the capacitance range sub-circuit includes a resistance selection switch and a plurality of resistors; a plurality of resistors with different resistance values are connected in series or in parallel and then are connected into a capacitor oscillator sub-circuit through a selection switch; the resistors with different resistance values are connected in series and are suitable for increasing the resistance value of the accessed oscillating circuit, the resistors with different resistance values are connected in parallel and are suitable for reducing the resistance value of the accessed oscillating circuit, and the capacitors with different capacities are measured by changing the resistance value of the accessed oscillating circuit.
In the embodiment, the resistance measuring circuit comprises a resistance oscillation sub-circuit and a resistance measuring sub-circuit;
the resistance measuring sub-circuit is connected with the oscillation end of the resistance oscillation sub-circuit; the input end of the resistance oscillation sub-circuit is connected with a component to be measured; the resistance oscillation sub-circuit is suitable for sending resistance oscillation frequency data to the processor module; the resistance oscillation sub-circuit is suitable for forming a multi-harmonic oscillation circuit by adopting a 555 timer and a resistance range sub-circuit; and measuring the resistance to be measured according to the formula R of the oscillation period, namely T/1.4C.
Resistance measurement circuit and capacitance measurement circuit all adopt the 555 timer, can reduce the design cost of circuit, the maintenance of the later stage of being convenient for.
In this embodiment, the resistance measuring sub-circuit includes a capacitance selection switch and a plurality of capacitors connected in parallel; capacitors with different capacities are connected in parallel through a selection switch and then are connected to an oscillation end of a resistance oscillation sub-circuit; the capacitors are formed by a plurality of capacitors, and the charging time T1 and the discharging time T2 of the capacitors are respectively as follows: charging time T1 ═ 0.7 RC; discharge time T2 ═ 0.7 RC; the period T of the multivibrator is therefore: t1+ T2 is 1.4 RC; substituting the T into a formula R/1.4C to calculate the resistance value of the component to be measured; different capacitors are connected in parallel to change the capacity of the access circuit, so that resistors with different sizes are measured.
In this embodiment, the transistor β value measuring circuit includes a transistor switching sub-circuit and a voltage collecting sub-circuit; the input end of the transistor switching sub-circuit is connected with a component; the output end of the transistor switching sub-circuit is connected with the voltage acquisition sub-circuit; the transistors are divided into NPN type and PNP type, corresponding measuring circuits are different, and beta values of different transistors are measured through a transistor switching sub-circuit.
In the present embodiment, the transistor switching sub-circuit includes a selection switch, a first transistor circuit, and a second transistor circuit; the selection switch is respectively connected with the input ends of the first transistor circuit and the second transistor circuit; when the measurement is carried out, the P5.1 pull-down circuit of the single chip microcomputer works, and if the selection switch S6 is switched on, the voltage on the resistor R25 is the same as the voltage division of a collector on the NPN; if the select switch S7 is turned on, the voltage across the resistor R26 is the same as the transmitter voltage across the PNP; different selection circuits are switched through a selection switch to realize measurement of beta values of different transistors; when the NPN type triode is tested, the emitter voltage Ue is measured, and then the relation Ie is determined by the relation Ie/Ue 1, Ic Ib + Ie, and β Ic/Ib; when a triode of PNP type is tested, the collector voltage Uc, Ic, Uc/R4, Ic, Ie + Ib, beta, Ic/Ib are measured.
In this embodiment, the voltage acquisition sub-circuit includes a sampling resistor; the sampling resistor is suitable for sending sampling data to the processor module so as to generate a beta value of the component to be measured; the processor module stores the corresponding relation between the voltage and the current of different transistors and the corresponding relation between the current and the current, and calculates the beta value of the corresponding transistor through sampling data.
In this embodiment, an "automatic shutdown" function may be added, that is, in the measurement mode, if no key is pressed within 1 minute, the meter automatically shuts down the power supply and enters a low power consumption state; then any key is pressed down, the meter automatically returns to the state before automatic shutdown.
In order to weigh the utility model discloses a working condition and measurement accuracy of low-power consumption digital multifunctional meter have carried out following experiment. The measured data are shown in tables 1 to 5.
TABLE 1 resistance test results
| Digital bridge resistance value | Test value | Measuring |
| 10 | 10.1 | 0.01 |
| 47 | 47.3 | 0.0063 |
| 100 | 99.8 | -0.002 |
| 510 | 512 | 0.0039 |
| 1K | 997 | -0.003 |
| 3.3K | 3.29K | -0.003 |
| 10K | 10.42K | 0.0042 |
| 51K | 50.65K | -0.0069 |
| 100K | 100.5K | 0.005 |
TABLE 2 capacitance test results
| Digital bridge capacitance value | TestingValue of | Measuring relative error |
| 10nF | 10.3nF | 0.03 |
| 100nF | 99.5nF | -0.005 |
| 220nF | 216nF | -0.018 |
| 1uF | 0.997nF | -0.003 |
| 10uF | 10.25uF | 0.025 |
| 22uF | 22.3uF | 0.014 |
| 47uF | 46.2uF | -0.017 |
| 100uF | 103.3uF | 0.033 |
TABLE 3 PNP triode test results
| Nominal value of multimeter | Test value | Measuring relative error |
| 160 | 160 | 0 |
| 210 | 211 | 0.0048 |
| 280 | 284 | 0.014 |
| 350 | 346 | -0.011 |
| 410 | 408 | -0.0049 |
| 460 | 456 | -0.0087 |
| 550 | 553 | 0.0055 |
TABLE 4 DC VOLTAGE TEST RESULTS
| Nominal value of DC source | Test value | Measuring relative error |
| 20mv | 19.68mv | -0.0016 |
| 100mv | 100.3mv | 0.003 |
| 200mv | 199.5mv | -0.0025 |
| 500mv | 503mv | 0.006 |
| 1v | 0.998v | -0.002 |
| 5v | 4.98v | -0.004 |
| 10v | 9.96v | -0.004 |
| 15v | 15.06v | 0.004 |
| 20v | 20.15v | 0.0075 |
TABLE 5 AC VOLTAGE TEST RESULTS
| Nominal value of AC source | Test value | Measuring relative error |
| 20mv | 19.68mv | -0.016 |
| 200mv | 201mv | 0.005 |
| 400mv | 398mv | -0.005 |
| 800mv | 806mv | 0.0075 |
| 1v | 1.005v | 0.005 |
| 4v | 4.01v | 0.0025 |
| 8v | 7.96v | -0.005 |
| 16v | 15.89v | -0.0069 |
| 20v | 19.86v | -0.007 |
In summary, through calculation and analysis of the above data, the relative error when measuring the 0.2V gear of the ac voltage is 0.005, which is within the required error range. Also the errors in measuring other physical quantities are within the required error range. The small AC signal is accurately measured, when the measuring range is 0.2V, the precision reaches 0.001, and the minimum value can be measured to 1mv. When the direct current voltage small signal is measured, the precision can reach 0.001, and the function of increasing a sine wave signal source by 1mv. can be measured at minimum: the frequency of the sine wave signal is required to be 10 Hz-100 kHz and is adjustable; the nonlinear distortion is less than or equal to 3 percent.
To sum up, the utility model uses the switching circuit to connect the original to be measured into the capacitance measuring circuit, or the resistance measuring circuit, or the transistor beta value measuring circuit; a capacitance oscillation sub-circuit of the capacitance measuring circuit sends frequency data to a processor module so as to calculate the capacitance value of the capacitance to be measured; the resistance measuring circuit is suitable for sending resistance oscillation frequency data to the processor module so as to calculate the resistance value of the resistance to be measured; the transistor beta value measuring circuit is suitable for sending sampling data adopting a resistor to the processor module so as to calculate the beta value of the transistor; through different measuring circuits, accurate measurement can be carried out to different access components and parts.
The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.
Claims (10)
1. A low power digital multifunctional watch, comprising:
the processor module and the conversion module are electrically connected with the processor module; wherein
The conversion module comprises a switching circuit, a capacitance measuring circuit, a resistance measuring circuit and a transistor beta value measuring circuit;
the switching circuit switches different circuits according to different components to be measured;
the processor module is suitable for receiving corresponding detection information sent by the capacitance measuring circuit, the resistance measuring circuit, the transistor beta value measuring circuit and the processor module so as to measure the physical quantity of the component to be measured.
2. The low power digital multifunctional watch of claim 1,
the switching circuit comprises a plurality of electronic sockets and a keyboard circuit;
the keyboard circuit is adapted to send selection information to the processor module;
the electronic sockets are respectively arranged at the testing ends of the capacitance measuring circuit, the resistance measuring circuit and the transistor beta value measuring circuit.
3. The low power digital multifunctional watch of claim 1,
the capacitance measuring circuit comprises a capacitance oscillation sub-circuit and a capacitance measuring range sub-circuit;
the capacitance measuring sub-circuit is connected with the input end of the capacitance oscillating sub-circuit;
and the output end of the capacitance oscillation sub-circuit is connected with a component to be measured.
4. The low power consumption digital multifunctional watch according to claim 3,
and the feedback end of the capacitive oscillation sub-circuit is connected with the processor module so as to send the frequency signal of the capacitive oscillation sub-circuit to the processor module.
5. The low power consumption digital multifunctional watch according to claim 3,
the capacitance measuring range sub-circuit comprises a resistance selection switch and a plurality of resistors;
and a plurality of resistors with different resistance values are connected in series or in parallel and then are connected into the capacitor oscillator sub-circuit through the selection switch.
6. The low power digital multifunctional watch of claim 1,
the resistance measuring circuit comprises a resistance oscillation sub-circuit and a resistance measuring sub-circuit;
the resistance measuring sub-circuit is connected with the oscillation end of the resistance oscillation sub-circuit;
the input end of the resistance oscillation sub-circuit is connected with a component to be measured;
the resistance oscillation sub-circuit is adapted to send resistance oscillation frequency data to the processor module.
7. The low power digital multifunctional watch of claim 6,
the resistance measuring range sub-circuit comprises a capacitance selection switch and a plurality of capacitors connected in parallel;
the capacitors with different capacities are connected in parallel through the selection switch and then are connected to the oscillation end of the resistance oscillation sub-circuit.
8. The low power consumption digital multifunctional watch according to claim 2,
the transistor beta value measuring circuit comprises a transistor switching sub-circuit and a voltage acquisition sub-circuit;
the input end of the transistor switching sub-circuit is connected with a component;
and the output end of the transistor switching sub-circuit is connected with the voltage acquisition sub-circuit.
9. The low power digital multifunctional watch of claim 8,
the transistor switching sub-circuit comprises a selection switch, a first transistor circuit and a second transistor circuit;
the selection switches are respectively connected with the input ends of the first transistor circuit and the second transistor circuit.
10. The low power digital multifunctional watch of claim 8,
the voltage acquisition sub-circuit comprises a sampling resistor;
the sampling resistor is suitable for sending sampling data to the processor module so as to generate a beta value of the component to be measured.
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
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| CN110672900A (en) * | 2019-11-01 | 2020-01-10 | 菏泽学院 | Low-power digital multifunctional meter |
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN110672900A (en) * | 2019-11-01 | 2020-01-10 | 菏泽学院 | Low-power digital multifunctional meter |
| CN110672900B (en) * | 2019-11-01 | 2024-05-28 | 菏泽学院 | Low-power consumption digital multifunctional meter |
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