CN104460809A - Temperature compensation type logic amplification power supply device - Google Patents
Temperature compensation type logic amplification power supply device Download PDFInfo
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- CN104460809A CN104460809A CN201410687843.3A CN201410687843A CN104460809A CN 104460809 A CN104460809 A CN 104460809A CN 201410687843 A CN201410687843 A CN 201410687843A CN 104460809 A CN104460809 A CN 104460809A
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Abstract
The invention discloses a temperature compensation type logic amplification power supply device. The temperature compensation type logic amplification power supply device is characterized in that the device is mainly composed of a direct-current power supply S, a control circuit connected with the direct-current power supply S, a temperature compensation circuit connected with the control circuit and a light dependent resistor CDS connected with the temperature compensation circuit; a light beam excitation type logic amplification circuit is connected between the direct-current power supply S and the light dependent resistor CDS in series. The device is simple in overall structure and very convenient to manufacture and use. Meanwhile, an output current value can be automatically adjusted according to the temperature change of external environment, signals amplified by a power amplification circuit cannot be attenuated greatly, and therefore the quality and performance of the amplified signals can be ensured, it is ensured that the performance of the amplified signals is more stable, radio-frequency interference of the circuits and the outside is effectively lowered, and it is ensured the performance is stable.
Description
Technical field
The present invention relates to a kind of supply unit, specifically refer to that a kind of temp. compensation type logic amplifies supply unit.
Background technology
At present; whether battery manufacturer generally all needs the various functions detecting this battery protection circuit with bipolar power supply up to standard after having made battery protection circuit, namely utilizes bipolar power supply to realize the quickly calibrated and test of overvoltage to battery protection circuit, under-voltage, overcurrent fast.When so-called bipolar power supply refers to this corona discharge, the electric current of its power source internal flows to positive pole from negative pole, and be flow to negative pole (when the electric current of traditional its inside of common power all can only flow to positive pole from negative pole, and can not flow to negative pole from positive pole) from positive pole to the electric current of its power source internal during this power source charges.But, bipolar power supply sold on the market is easily subject to the impact of ambient temperature at present, and carry out after power drive amplification through traditional power amplification circuit, the attenuation amplitude of its amplifying signal is larger, but also outside electromagnetic interference (EMI) can be subject to, and then make amplifying signal performance comparatively unstable, make its power supply performance extremely unstable.Therefore having had a strong impact on using and promoting of its profound level, is the difficult problem that people are badly in need of solving.
Summary of the invention
The object of the invention is to overcome the impact that current bipolar power supply is easily subject to ambient temperature, and then cause the defect of unstable properties, provide a kind of temp. compensation type logic to amplify supply unit.
Object of the present invention is achieved through the following technical solutions: a kind of temp. compensation type logic amplifies supply unit, primarily of direct supply S, the control circuit be connected with direct supply S-phase, the temperature-compensation circuit be connected with control circuit, and the photoresistance CDS be connected with temperature-compensation circuit forms.Meanwhile, between direct supply S and photoresistance CDS, be serially connected with beam excitation formula logic amplifying circuit, described beam excitation formula logic amplifying circuit, primarily of power amplifier P2, Sheffer stroke gate IC1, Sheffer stroke gate IC2, Sheffer stroke gate IC3, negative pole is connected with the electrode input end of power amplifier P2, the polar capacitor C5 of positive pole ground connection after optical diode D1, one end is connected with the positive pole of polar capacitor C5, the resistance R8 of other end ground connection after diode D2, positive pole is connected with the tie point of diode D2 with resistance R8, the polar capacitor C6 of minus earth, one end is connected with the negative input of Sheffer stroke gate IC1, the resistance R9 that the other end is connected with the electrode input end of power amplifier P2, be serially connected in the resistance R10 between the negative input of power amplifier P2 and output terminal, one end is connected with the output terminal of Sheffer stroke gate IC1, the resistance R11 that the other end is connected with the negative input of Sheffer stroke gate IC3, positive pole is connected with the output terminal of Sheffer stroke gate IC2, the electric capacity C7 that negative pole is connected with the negative input of Sheffer stroke gate IC3, and one end is connected with the positive pole of polar capacitor C6, the resistance R12 that the other end is connected with the negative input of Sheffer stroke gate IC2 forms, the electrode input end of described Sheffer stroke gate IC1 is connected with the negative input of power amplifier P2, and the electrode input end of its output terminal Sheffer stroke gate IC2 is connected, the electrode input end of Sheffer stroke gate IC3 is connected with the output terminal of power amplifier P2, and its output terminal is connected with one end of photoresistance CDS, the electrode input end of described power amplifier P2 is connected with the negative pole of direct supply S.
Described control circuit is by triode Q1, triode Q2, be serially connected in the resistance R1 between the collector of triode Q1 and the collector of triode Q2, be serially connected in the RC filtering circuit between the emitter of triode Q1 and the negative pole of direct supply S, be serially connected in the resistance R2 between the base stage of triode Q1 and the negative pole of direct supply S, and the resistance R5 in parallel with direct supply S-phase forms; The emitter of described triode Q2 is connected with the positive pole of direct supply S, and the base stage of triode Q2 is also connected with the collector of triode Q1.
Further, described temperature-compensation circuit is by triode Q3, triode Q4, power amplifier P1, be serially connected in the resistance R4 between the collector of triode Q3 and the collector of triode Q2, be serially connected in the electric capacity C2 between the electrode input end of power amplifier P1 and output terminal, be serially connected in the electric capacity C3 between the negative input of power amplifier P1 and output terminal, negative pole is connected with the emitter of triode Q4, the electric capacity C4 of positive pole ground connection after photoresistance CDS, the resistance R6 be in parallel with electric capacity C4, and one end is connected with the output terminal of power amplifier P1, the other end forms through the resistance R7 of photoresistance CDS ground connection, the electrode input end of described power amplifier P1 is connected with the collector of triode Q4, and its negative input is connected with the emitter of triode Q3, the collector of described triode Q4 is connected with the collector of triode Q2, its base earth.Meanwhile, the base stage of triode Q3 is also connected with the positive pole of direct supply S.
Described RC filtered electrical routing resistance R3, and form with the electric capacity C1 that resistance R3 is in parallel, described electric capacity C2, electric capacity C3 and electric capacity C4 are polar capacitor.
The present invention compared with prior art, has the following advantages and beneficial effect:
(1) one-piece construction of the present invention is simple, and it makes and very easy to use.
(2) the present invention can adjust output current value automatically according to the temperature variation of external environment condition, and larger decay can not be there is in the signal after power amplification circuit amplifies, thus the quality and performance of amplifying signal can be guaranteed, really make its performance more stable, and effectively reduce circuit self and extraneous Radio frequency interference (RFI).
Accompanying drawing explanation
Fig. 1 is structural representation of the present invention.
Embodiment
Below in conjunction with embodiment and accompanying drawing, the present invention is described in further detail, but embodiments of the present invention are not limited thereto.
As shown in Figure 1, temp. compensation type power supply of the present invention is primarily of direct supply S, the control circuit be connected with direct supply S-phase, the temperature-compensation circuit be connected with control circuit, the photoresistance CDS be connected with temperature-compensation circuit, and the beam excitation formula logic amplifying circuit be serially connected between direct supply S and photoresistance CDS forms.
Wherein, control circuit is by triode Q1, and triode Q2, resistance R1, resistance R2, resistance R5 and RC filtering circuit form.During connection, resistance R1 is serially connected between the collector of triode Q1 and the collector of triode Q2, and RC filtering circuit is then serially connected between the emitter of triode Q1 and the negative pole of direct supply S.Resistance R2 is serially connected between the base stage of triode Q1 and the negative pole of direct supply S, and resistance R5 is then in parallel with direct supply S-phase.
Meanwhile, the emitter of triode Q2 is connected with the positive pole of direct supply S, and its base stage is also connected with the collector of triode Q1.For guaranteeing operational effect, the resistance of resistance R1, resistance R2, resistance R3 and resistance R5 is 10K Ω.RC filtered electrical routing resistance R3 in the application, and form with the electric capacity C1 that resistance R3 is in parallel.
Described beam excitation formula logic amplifying circuit, primarily of power amplifier P2, Sheffer stroke gate IC5, Sheffer stroke gate IC1 Sheffer stroke gate IC2 polar capacitor C5, polar capacitor C6, optical diode D1, diode D2, resistance R8 resistance R9, resistance R10, resistance R11, and resistance R12 forms.
During connection, the electrode input end of described power amplifier P2 is connected with the negative pole of direct supply S; The positive pole of polar capacitor C5 is connected with the N pole of optical diode D1 simultaneously, the P2 pole then ground connection of optical diode D1; Resistance R8 one end is connected with the positive pole of polar capacitor C5, and its other end is ground connection after diode D2.
The positive pole of described polar capacitor C6 is connected with the tie point of diode D2 with resistance R1, its minus earth; One end of resistance R9 is connected with Sheffer stroke gate IC1 negative input, and its other end is connected with the electrode input end of power amplifier P2; Between the negative input that resistance R10 is then serially connected in power amplifier P2 and output terminal.
One end of resistance R11 is connected with Sheffer stroke gate IC1 output terminal, and its other end is connected with Sheffer stroke gate IC3 negative input; Meanwhile, the positive pole of electric capacity C7 is connected with Sheffer stroke gate IC2 output terminal, and its negative pole is also connected with Sheffer stroke gate IC3 negative input.One end of described resistance R12 is connected with the positive pole of polar capacitor C6, and its other end is connected with Sheffer stroke gate IC2 negative input.
Described Sheffer stroke gate IC1 electrode input end is connected with the negative input of power amplifier P2, its output terminal is connected with Sheffer stroke gate IC2 electrode input end, Sheffer stroke gate IC3 electrode input end is connected with the output terminal of power amplifier P2, and the output terminal of IC3 is connected with one end of photoresistance CDS.
Temperature-compensation circuit is used for power back-off during ambient temperature change, it is by triode Q3, triode Q4, power amplifier P1, be serially connected in the resistance R4 between the collector of triode Q3 and the collector of triode Q2, be serially connected in the electric capacity C2 between the electrode input end of power amplifier P1 and output terminal, be serially connected in the electric capacity C3 between the negative input of power amplifier P1 and output terminal, negative pole is connected with the emitter of triode Q4, the electric capacity C4 of positive pole ground connection after photoresistance CDS, the resistance R6 be in parallel with electric capacity C4, and one end is connected with the output terminal of power amplifier P1, the other end forms through the resistance R7 of photoresistance CDS ground connection.
The electrode input end of power amplifier P1 is connected with the collector of triode Q4, and its negative input is connected with the emitter of triode Q3.Meanwhile, the collector of triode Q4 is also connected with the collector of triode Q2, and its base earth.
For guaranteeing result of use, described electric capacity C2, electric capacity C3 and electric capacity C4 all preferentially adopt polar capacitor to realize.
As mentioned above, just the present invention can be realized preferably.
Claims (4)
1. a temp. compensation type logic amplifies supply unit, it is characterized in that, primarily of direct supply S, the control circuit be connected with direct supply S-phase, the temperature-compensation circuit be connected with control circuit, and the photoresistance CDS to be connected with temperature-compensation circuit forms, and it is characterized in that, is serially connected with beam excitation formula logic amplifying circuit between direct supply S and photoresistance CDS, described beam excitation formula logic amplifying circuit, primarily of power amplifier P2, Sheffer stroke gate IC1, Sheffer stroke gate IC2, Sheffer stroke gate IC3, negative pole is connected with the electrode input end of power amplifier P2, the polar capacitor C5 of positive pole ground connection after optical diode D1, one end is connected with the positive pole of polar capacitor C5, the resistance R8 of other end ground connection after diode D2, positive pole is connected with the tie point of diode D2 with resistance R8, the polar capacitor C6 of minus earth, one end is connected with the negative input of Sheffer stroke gate IC1, the resistance R9 that the other end is connected with the electrode input end of power amplifier P2, be serially connected in the resistance R10 between the negative input of power amplifier P2 and output terminal, one end is connected with the output terminal of Sheffer stroke gate IC1, the resistance R11 that the other end is connected with the negative input of Sheffer stroke gate IC3, positive pole is connected with the output terminal of Sheffer stroke gate IC2, the electric capacity C7 that negative pole is connected with the negative input of Sheffer stroke gate IC3, and one end is connected with the positive pole of polar capacitor C6, the resistance R12 that the other end is connected with the negative input of Sheffer stroke gate IC2 forms, the electrode input end of described Sheffer stroke gate IC1 is connected with the negative input of power amplifier P2, and the electrode input end of its output terminal Sheffer stroke gate IC2 is connected, the electrode input end of Sheffer stroke gate IC3 is connected with the output terminal of power amplifier P2, and its output terminal is connected with one end of photoresistance CDS, the electrode input end of described power amplifier P2 is connected with the negative pole of direct supply S, described control circuit is by triode Q1, triode Q2, be serially connected in the resistance R1 between the collector of triode Q1 and the collector of triode Q2, be serially connected in the RC filtering circuit between the emitter of triode Q1 and the negative pole of direct supply S, be serially connected in the resistance R2 between the base stage of triode Q1 and the negative pole of direct supply S, and the resistance R5 in parallel with direct supply S-phase forms, the emitter of described triode Q2 is connected with the positive pole of direct supply S, and the base stage of triode Q2 is also connected with the collector of triode Q1.
2. a kind of temp. compensation type logic according to claim 1 amplifies supply unit, it is characterized in that, described temperature-compensation circuit is by triode Q3, triode Q4, power amplifier P1, be serially connected in the resistance R4 between the collector of triode Q3 and the collector of triode Q2, be serially connected in the electric capacity C2 between the electrode input end of power amplifier P1 and output terminal, be serially connected in the electric capacity C3 between the negative input of power amplifier P1 and output terminal, negative pole is connected with the emitter of triode Q4, the electric capacity C4 of positive pole ground connection after photoresistance CDS, the resistance R6 be in parallel with electric capacity C4, and one end is connected with the output terminal of power amplifier P1, the other end forms through the resistance R7 of photoresistance CDS ground connection, the electrode input end of described power amplifier P1 is connected with the collector of triode Q4, and its negative input is connected with the emitter of triode Q3, the collector of described triode Q4 is connected with the collector of triode Q2, its base earth, the base stage of triode Q3 is connected with the positive pole of direct supply S.
3. a kind of temp. compensation type logic according to claim 1 amplifies supply unit, it is characterized in that, described RC filtered electrical routing resistance R3, and forms with the electric capacity C1 that resistance R3 is in parallel.
4. a kind of temp. compensation type logic according to claim 2 amplifies supply unit, and it is characterized in that, described electric capacity C2, electric capacity C3 and electric capacity C4 are polar capacitor.
Priority Applications (2)
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CN201410687843.3A CN104460809A (en) | 2014-11-25 | 2014-11-25 | Temperature compensation type logic amplification power supply device |
CN201510315980.9A CN105005347B (en) | 2014-11-25 | 2015-06-11 | A kind of three linear buffer drive-types amplify supply unit |
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CN201410687843.3A CN104460809A (en) | 2014-11-25 | 2014-11-25 | Temperature compensation type logic amplification power supply device |
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CN201410687843.3A Pending CN104460809A (en) | 2014-11-25 | 2014-11-25 | Temperature compensation type logic amplification power supply device |
CN201510315980.9A Active CN105005347B (en) | 2014-11-25 | 2015-06-11 | A kind of three linear buffer drive-types amplify supply unit |
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CN201510315980.9A Active CN105005347B (en) | 2014-11-25 | 2015-06-11 | A kind of three linear buffer drive-types amplify supply unit |
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Cited By (1)
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CN114516486A (en) * | 2020-11-20 | 2022-05-20 | 圣邦微电子(北京)股份有限公司 | Chip memory device |
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JP3633522B2 (en) * | 2001-07-27 | 2005-03-30 | 株式会社デンソー | Load drive circuit |
CN101237186A (en) * | 2007-01-29 | 2008-08-06 | 安葳科技股份有限公司 | Framework for efficient charge pump regulator |
US7504783B2 (en) * | 2007-03-23 | 2009-03-17 | National Semiconductor Corporation | Circuit for driving and monitoring an LED |
DE102010031657A1 (en) * | 2010-07-22 | 2012-01-26 | Osram Ag | Buck converter for LED, has power supply circuit that supplies current to drive device to produce auxiliary portion of control signal for buck switch, where main portion of control signal is produced by voltage drop across shunt resistor |
CN103631294B (en) * | 2013-11-28 | 2016-03-02 | 中国科学院微电子研究所 | A kind of supply voltage automatic regulating apparatus and method |
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- 2014-11-25 CN CN201410687843.3A patent/CN104460809A/en active Pending
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CN114516486A (en) * | 2020-11-20 | 2022-05-20 | 圣邦微电子(北京)股份有限公司 | Chip memory device |
CN114516486B (en) * | 2020-11-20 | 2024-05-14 | 圣邦微电子(北京)股份有限公司 | Chip memory device |
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CN105005347A (en) | 2015-10-28 |
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Application publication date: 20150325 |