CN203691241U - Voltage-adjustable current-adjustable high-performance positive laser power supply circuit composed of 555 - Google Patents
Voltage-adjustable current-adjustable high-performance positive laser power supply circuit composed of 555 Download PDFInfo
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Abstract
The utility model relates to a voltage-adjustable current-adjustable high-performance positive laser power supply circuit composed of 555, which is used for working of a laser device in the fields of war industry, electronic industry, medical treatment and the like. The power supply circuit comprises a control and drive circuit, an output feedback circuit, an output voltage control circuit, a current control and protection circuit and a composite high-voltage output circuit, wherein the output feedback circuit is respectively connected with the control and drive circuit, the output voltage control circuit, the current control and protection circuit and the composite high-voltage output circuit; and the control and drive circuit is connected with the composite high-voltage output circuit. The power supply circuit has the following effects: the circuit structure is simple, and the conversion efficiency is high; the current stabilization precision is high, and the current can be continuously adjusted; the working voltage can be kept adjustable, thus changing the start voltage and adapting to various types of laser devices; the power supply circuit has the functions of external output enablement control and internal output current control protection; and the power supply circuit has a modular design, can work with high reliability for long time, and is light in weight, small in overall dimension and easy to mount.
Description
Technical field
The utility model relates to a kind of in fields such as military project, electronics industry and medical treatment, in the instrument and equipment of the aspects such as laser ranging, laser communications, laser guidance, laser photo-typesetting, adjust the positive laser power supply circuit of stream high-performance for a kind of of laser works by 555 pressure-adjustables that form.
Background technology
Along with high-tech development, the application of various gas lasers is more and more extensive, the requirement of the important component part Laser Power Devices of market to laser is thereupon also more and more higher, although current Laser Power Devices have been introduced high frequency switch power technology mostly, carry out high frequency design, its circuit structure is more complicated, exist conversion efficiency lower, precision of steady current is not high, and the overall dimension of product is larger, the poor deficiency that waits of reliable long-term working.
Summary of the invention
In view of the deficiency of existing conditions of demand and existence, the utility model provides a kind of precision of steady current high, and overall dimension is less, be easy to install and circuit is simply adjusted the positive laser power supply circuits of stream high-performance by 555 pressure-adjustables that form.
The utility model for achieving the above object; the technical scheme of taking is: a kind of by the 555 positive laser power supply circuits of pressure-adjustables tune stream high-performance that form; it is characterized in that: it comprises control and drive circuit, output feedback circuit, output voltage controlling circuit, Current Control and protective circuit, composite high pressure output circuit; described output feedback circuit is connected with control and drive circuit, output voltage controlling circuit, Current Control and protective circuit, composite high pressure output circuit respectively, and described control and drive circuit are connected with composite high pressure output circuit.
The beneficial effects of the utility model are: circuit structure is simple, and conversion efficiency is high; Precision of steady current is high and can regulate continuously; Maintenance work voltage is adjustable, and then changes starting voltage, adapts to polytype laser; There is the function of outside output enable control and inner output current control protection; Modularized design, lightweight, overall dimension is little, and reliable long-term working is high, is easy to install.
Brief description of the drawings
Fig. 1 is that circuit of the present utility model connects block diagram;
Fig. 2 is circuit theory diagrams of the present utility model.
Embodiment
As shown in Figure 1, 2; a kind of by the 555 positive laser power supply circuits of pressure-adjustables tune stream high-performance that form; comprise control and drive circuit, output feedback circuit, output voltage controlling circuit, Current Control and protective circuit, composite high pressure output circuit; output feedback circuit is connected with control and drive circuit, output voltage controlling circuit, Current Control and protective circuit, composite high pressure output circuit respectively, and control and drive circuit are connected with composite high pressure output circuit.
In above-mentioned control and drive circuit, 1 end of transformer TRF primary coil Lp connects respectively one end of inductance L 1, the positive pole of capacitor C 3, the negative pole of capacitor C 3 meets input ground GND, the control end 1 pin difference connecting resistance R8 of voltage stabilizing a reference source U2 and one end of R9, the other end of resistance R 8 connects respectively negative electrode 3 pin of voltage stabilizing a reference source U2, the positive pole of one end of resistance R 2 and capacitor C 4, and as reference voltage output end Vref, the other end of resistance R 9 respectively with the negative pole of capacitor C 4, anode 2 pin of voltage stabilizing a reference source U2 are connected and meet input ground GND, one end of resistance R 1 connects respectively the negative pole of diode D2, the positive pole of capacitor C 6, one end of resistance R 3 and resistance R 5, power positive end 8 pin of control chip U1, the negative pole of capacitor C 6 is connected with the positive pole of diode D2 and meets input ground GND, one end of resistance R 12 connects respectively the negative pole of diode D1, the positive pole of capacitor C 5, and as in-line power end Vcc, the negative pole of capacitor C 5 is connected with the positive pole of diode D1 and meets input ground GND, for electrical input+Vin connecting resistance R1 respectively, R2, the other end of the other end of R12 and inductance L 1, the drain electrode of the 2 termination triode T1 of transformer TRF primary coil Lp, resistance R 10 is in parallel with diode D3, the grid of triode T1 connects respectively the positive pole of diode D3 and one end of resistance R 11, the negative pole of diode D3 connect control chip U1 output 3 pin, the other end of resistance R 11 is connected with the source electrode of triode T1 and meets input ground GND, the other end of resistance R 3 respectively one end of connecting resistance R4 and control chip U1 discharge end 7 pin, the other end of resistance R 4 connects respectively one end of capacitor C 1, control chip U1 trigger end 2 pin and threshold value end 6 pin, the other end of resistance R 5 connects respectively the collector electrode of triode T2, control chip U1 reset terminal 4 pin, the base stage of triode T2 is connecting resistance R6 respectively, one end of R7 and capacitor C 2, another termination on off control end R/S of resistance R 6, the emitter of triode T2 is connecting resistance R7 respectively, with capacitor C 1, the other end of C2, and with control chip U1 earth terminal 1 pin meet input ground GND after being connected, control chip U1 voltage controling end 5 pin meet input ground GND by capacitor C 7,
In above-mentioned output feedback circuit, resistance R 21 is in parallel with capacitor C 23, one end of resistance R 21 connects respectively one end of capacitor C 25 and resistance R 19 by resistance R 20, inverting input 6 pin of control chip U4B, resistance R 18 is in parallel with capacitor C 24, one end of the in-phase input end 5 pin connecting resistance R18 of control chip U4B, resistance R 18 is connected with the other end of resistance R 19 and meets input ground GND, resistance R 16 is in parallel with diode D4, output 7 pin of control chip U4B connect respectively the other end of capacitor C 25, one end of the negative pole of diode D4 and resistance R 17, the positive pole of diode D4 be connected with the positive pole of diode D5 and connect control and drive circuit in voltage controling end 5 pin of control chip U1, another termination input ground GND of resistance R 17, resistance R 23 is in parallel with capacitor C 27, the in-phase input end 3 pin connecting resistance R23 respectively of control chip U4A, one end of R24, another termination input ground GND of resistance R 23, diode D6, D7 series aiding connection and in parallel with resistance R 25 and capacitor C 22, the other end of the negative pole connecting resistance R24 of diode D6, the positive pole of diode D7 meets output ground HVG, the inverting input 2 pin difference connecting resistance R22 of control chip U4A and one end of capacitor C 26, another termination input ground GND of resistance R 22, output 1 pin of control chip U4A connects respectively the negative pole of diode D5, the other end of capacitor C 26, 4 pin of control chip U4A meet input ground GND, 8 pin of control chip U4A meet in-line power end Vcc,
In above-mentioned output voltage controlling circuit, in-phase input end 5 pin of control chip U5B connect adjustable end 3 pin of potentiometer W, stiff end 1 pin of potentiometer W meets reference voltage output end Vref, another stiff end 2 pin of potentiometer W meet input ground GND by resistance R 15, the inverting input 6 pin difference connecting resistance R13 of control chip U5B and one end of capacitor C 8, one end of the output 7 pin difference connecting resistance R14 of control chip U5B, the other end of capacitor C 8, resistance R 13 is connected with the other end of resistance R 14 and connects in-phase input end 5 pin of exporting control chip U4B in feedback circuit;
In above-mentioned Current Control and protective circuit, in-phase input end 3 pin of control chip U5A connect respectively the positive pole of diode D8, one end of resistance R 29, the other end of resistance R 29 respectively with one end of resistance R 31 and capacitor C 10, output current adjustable side Iadj is connected, one end of the control end 1 pin difference connecting resistance R32 of voltage stabilizing a reference source U3 and the other end of resistance R 31, anode 2 pin of voltage stabilizing a reference source U3 are connected with the other end of capacitor C 10 with resistance R 32 respectively and meet input ground GND, negative electrode 3 pin of voltage stabilizing a reference source U3 connect respectively the negative pole of diode D8, one end of resistance R 30, another termination in-line power end Vcc of resistance R 30, the inverting input 2 pin difference connecting resistance R26 of control chip U5A and one end of capacitor C 9, output 1 pin one end of connecting resistance R27 respectively of control chip U5A, the other end of capacitor C 9, one end of resistance R 28 is connecting resistance R26 respectively, the other end of R27, in-phase input end 3 pin of control chip U4A in another termination output feedback circuit of resistance R 28, 4 pin of control chip U5A meet input ground GND, 8 pin of control chip U5A meet in-line power end Vcc,
In above-mentioned composite high pressure output circuit, 1 end of transformer TRF secondary high pressure coil Ls connects respectively one end of capacitor C 19 and capacitor C 11, the other end of capacitor C 19 connects respectively the negative pole of diode D19 and the positive pole of diode D20, the positive pole of diode D19 connects respectively one end of capacitor C 20 and 2 ends of transformer TRF secondary high pressure coil Ls, the other end of capacitor C 20 connects respectively the negative pole of diode D20 and one end of resistance R 36, the other end of resistance R 36 connects respectively one end of capacitor C 21 and resistance R 37, the other end of resistance R 21 in output feedback circuit, the other end of capacitor C 21 connects respectively 2 ends of transformer TRF secondary high pressure coil Ls and exports the negative pole of diode D6 in feedback circuit, capacitor C 28 and resistance R 38 parallel connections, one end of the other end connecting resistance R38 of resistance R 37, the positive pole of another terminating diode D9 of resistance R 38, the negative pole of diode D9 connects the positive pole of diode D10, the negative pole of diode D10 is one end and the compound positive high voltage output+HV.Out of connecting resistance R34 respectively, the other end of capacitor C 11 connects respectively one end of capacitor C 13, the positive pole of the negative pole of diode D11 and diode D12, the other end of capacitor C 13 connects respectively one end of capacitor C 15, the positive pole of the negative pole of diode D13 and diode D14, the other end of capacitor C 15 connects respectively one end of capacitor C 17, the positive pole of the negative pole of diode D15 and diode D16, the other end of capacitor C 17 connects respectively the negative pole of diode D17 and the positive pole of diode D18, the positive pole of diode D11 connects respectively one end of capacitor C 12 and 2 ends of transformer TRF secondary high pressure coil Ls, the other end of capacitor C 12 connects respectively the negative pole of diode D12, one end of the positive pole of diode D13 and capacitor C 14, the other end of capacitor C 14 connects respectively the negative pole of diode D14, one end of the positive pole of diode D15 and capacitor C 16, the other end of capacitor C 16 connects respectively the negative pole of diode D16, one end of the positive pole of diode D17 and capacitor C 18, the other end of capacitor C 18 connects respectively the negative pole of diode D18 and one end of resistance R 33, the other end of resistance R 33 is connected with the other end of resistance R 34,
Master control chip adopts 7555 common time-base circuits, utilizes the features such as it is controlled simply, extremely low power consumption, power supply accommodation is wide, load capacity is strong, connects by peripheral circuit, forms astable multivibrator circuit.Circuit overall structure is simple, consumes energy little, and output precision of steady current is high, and its outside enables control end and output constant current regulates control, and there is multi-protective function inside.High-pressure section adopts composite high pressure output, and output voltage and electric current are adjustable, and build-up of luminance, maintain voltage and automatically switch, after build-up of luminance, be constant current output.
Select control chip and other components and parts of low noise, Low Drift Temperature, good stability; PCB rational deployment, the various types of signal such as control, power have independent pathway, reduce mutually crosstalking between each signal, effectively control EMI; Guarantee high-quality high frequency transformer, at aspects such as its structural manufacturing process, assembly technology and High-Voltage Insulation processing, be rigid in checking up, ensure stability and the reliability of power supply long-term work.
Operation principle
In control and drive circuit, form astable multivibrator circuit by U1 control chip 7555, capacitor C 1, resistance R 3 and resistance R 4 etc.Internal supply voltage Vcc does not take from 8 pin of U1 chip, and adopts independent output, avoids the interference to other control chip.From the oscillation pulse signal of the 3 pin outputs of control chip U1, by triode T1 driving transformer TRF primary coil Lp, produce higher-order of oscillation pulse voltage at its two ends, and be coupled to by switch transformer TRF that it is secondary.
In composite high pressure output circuit, the alternating-current pulse high pressure Fen Liangtiao road multiplication of voltage on the secondary high pressure coil Ls of switch transformer TRF, the octuple of leading up to is pressed, and exports very high positive high voltage, as build-up of luminance high pressure; Separately lead up to two multiplication of voltages, export lower positive maintenance work high pressure.Before laser load is breakdown, build-up of luminance high pressure is higher than maintenance work high pressure, and diode D9, D10 are reverse, and output voltage is very high starting voltage; After laser load is breakdown, load current increases, and two high pressure automatically switch, and high-voltage power output, by resistance R 37, R38 and diode D9, D10, is provided by maintenance work voltage.
In Current Control and protective circuit, output voltage controlling circuit and output feedback circuit, control chip U4B, resistance R 19, R20, R21 etc. form voltage feedback circuit, and the follower consisting of through U5B etc. potentiometer W, and output voltage is regulated; Form output current feedback circuit by control chip U4A, resistance R 25 etc., thereby obtain high-precision output current, and by external control adjustable side Iadj, through the follower of the composition such as control protection electric circuit and U5A, output current is regulated continuously.
Claims (2)
1. adjust the positive laser power supply circuit of stream high-performance by 555 pressure-adjustables that form for one kind; it is characterized in that: it comprises control and drive circuit, output feedback circuit, output voltage controlling circuit, Current Control and protective circuit, composite high pressure output circuit; described output feedback circuit is connected with control and drive circuit, output voltage controlling circuit, Current Control and protective circuit, composite high pressure output circuit respectively, and described control and drive circuit are connected with composite high pressure output circuit.
2. according to claim 1 a kind of by the 555 positive laser power supply circuits of pressure-adjustables tune stream high-performance that form, it is characterized in that: in described control and drive circuit, 1 end of transformer TRF primary coil Lp connects respectively one end of inductance L 1, the positive pole of capacitor C 3, the negative pole of capacitor C 3 meets input ground GND, the control end 1 pin difference connecting resistance R8 of voltage stabilizing a reference source U2 and one end of R9, the other end of resistance R 8 connects respectively negative electrode 3 pin of voltage stabilizing a reference source U2, the positive pole of one end of resistance R 2 and capacitor C 4, and as reference voltage output end Vref, the other end of resistance R 9 respectively with the negative pole of capacitor C 4, anode 2 pin of voltage stabilizing a reference source U2 are connected and meet input ground GND, one end of resistance R 1 connects respectively the negative pole of diode D2, the positive pole of capacitor C 6, one end of resistance R 3 and resistance R 5, power positive end 8 pin of control chip U1, the negative pole of capacitor C 6 is connected with the positive pole of diode D2 and meets input ground GND, one end of resistance R 12 connects respectively the negative pole of diode D1, the positive pole of capacitor C 5, and as in-line power end Vcc, the negative pole of capacitor C 5 is connected with the positive pole of diode D1 and meets input ground GND, for electrical input+Vin connecting resistance R1 respectively, R2, the other end of the other end of R12 and inductance L 1, the drain electrode of the 2 termination triode T1 of transformer TRF primary coil Lp, resistance R 10 is in parallel with diode D3, the grid of triode T1 connects respectively the positive pole of diode D3 and one end of resistance R 11, the negative pole of diode D3 connect control chip U1 output 3 pin, the other end of resistance R 11 is connected with the source electrode of triode T1 and meets input ground GND, the other end of resistance R 3 respectively one end of connecting resistance R4 and control chip U1 discharge end 7 pin, the other end of resistance R 4 connects respectively one end of capacitor C 1, control chip U1 trigger end 2 pin and threshold value end 6 pin, the other end of resistance R 5 connects respectively the collector electrode of triode T2, control chip U1 reset terminal 4 pin, the base stage of triode T2 is connecting resistance R6 respectively, one end of R7 and capacitor C 2, another termination on off control end R/S of resistance R 6, the emitter of triode T2 is connecting resistance R7 respectively, with capacitor C 1, the other end of C2, and with control chip U1 earth terminal 1 pin meet input ground GND after being connected, control chip U1 voltage controling end 5 pin meet input ground GND by capacitor C 7,
In described output feedback circuit, resistance R 21 is in parallel with capacitor C 23, one end of resistance R 21 connects respectively one end of capacitor C 25 and resistance R 19 by resistance R 20, inverting input 6 pin of control chip U4B, resistance R 18 is in parallel with capacitor C 24, one end of the in-phase input end 5 pin connecting resistance R18 of control chip U4B, resistance R 18 is connected with the other end of resistance R 19 and meets input ground GND, resistance R 16 is in parallel with diode D4, output 7 pin of control chip U4B connect respectively the other end of capacitor C 25, one end of the negative pole of diode D4 and resistance R 17, the positive pole of diode D4 be connected with the positive pole of diode D5 and connect control and drive circuit in voltage controling end 5 pin of control chip U1, another termination input ground GND of resistance R 17, resistance R 23 is in parallel with capacitor C 27, the in-phase input end 3 pin connecting resistance R23 respectively of control chip U4A, one end of R24, another termination input ground GND of resistance R 23, diode D6, D7 series aiding connection and in parallel with resistance R 25 and capacitor C 22, the other end of the negative pole connecting resistance R24 of diode D6, the positive pole of diode D7 meets output ground HVG, the inverting input 2 pin difference connecting resistance R22 of control chip U4A and one end of capacitor C 26, another termination input ground GND of resistance R 22, output 1 pin of control chip U4A connects respectively the negative pole of diode D5, the other end of capacitor C 26, 4 pin of control chip U4A meet input ground GND, 8 pin of control chip U4A meet in-line power end Vcc,
In described output voltage controlling circuit, in-phase input end 5 pin of control chip U5B connect adjustable end 3 pin of potentiometer W, stiff end 1 pin of potentiometer W meets reference voltage output end Vref, another stiff end 2 pin of potentiometer W meet input ground GND by resistance R 15, the inverting input 6 pin difference connecting resistance R13 of control chip U5B and one end of capacitor C 8, one end of the output 7 pin difference connecting resistance R14 of control chip U5B, the other end of capacitor C 8, resistance R 13 is connected with the other end of resistance R 14 and connects in-phase input end 5 pin of exporting control chip U4B in feedback circuit;
In described Current Control and protective circuit, in-phase input end 3 pin of control chip U5A connect respectively the positive pole of diode D8, one end of resistance R 29, the other end of resistance R 29 respectively with one end of resistance R 31 and capacitor C 10, output current adjustable side Iadj is connected, one end of the control end 1 pin difference connecting resistance R32 of voltage stabilizing a reference source U3 and the other end of resistance R 31, anode 2 pin of voltage stabilizing a reference source U3 are connected with the other end of capacitor C 10 with resistance R 32 respectively and meet input ground GND, negative electrode 3 pin of voltage stabilizing a reference source U3 connect respectively the negative pole of diode D8, one end of resistance R 30, another termination in-line power end Vcc of resistance R 30, the inverting input 2 pin difference connecting resistance R26 of control chip U5A and one end of capacitor C 9, output 1 pin one end of connecting resistance R27 respectively of control chip U5A, the other end of capacitor C 9, one end of resistance R 28 is connecting resistance R26 respectively, the other end of R27, in-phase input end 3 pin of control chip U4A in another termination output feedback circuit of resistance R 28, 4 pin of control chip U5A meet input ground GND, 8 pin of control chip U5A meet in-line power end Vcc,
In described composite high pressure output circuit, 1 end of transformer TRF secondary high pressure coil Ls connects respectively one end of capacitor C 19 and capacitor C 11, the other end of capacitor C 19 connects respectively the negative pole of diode D19 and the positive pole of diode D20, the positive pole of diode D19 connects respectively one end of capacitor C 20 and 2 ends of transformer TRF secondary high pressure coil Ls, the other end of capacitor C 20 connects respectively the negative pole of diode D20 and one end of resistance R 36, the other end of resistance R 36 connects respectively one end of capacitor C 21 and resistance R 37, the other end of resistance R 21 in output feedback circuit, the other end of capacitor C 21 connects respectively 2 ends of transformer TRF secondary high pressure coil Ls and exports the negative pole of diode D6 in feedback circuit, capacitor C 28 and resistance R 38 parallel connections, one end of the other end connecting resistance R38 of resistance R 37, the positive pole of another terminating diode D9 of resistance R 38, the negative pole of diode D9 connects the positive pole of diode D10, the negative pole of diode D10 is one end and the compound positive high voltage output+HV.Out of connecting resistance R34 respectively, the other end of capacitor C 11 connects respectively one end of capacitor C 13, the positive pole of the negative pole of diode D11 and diode D12, the other end of capacitor C 13 connects respectively one end of capacitor C 15, the positive pole of the negative pole of diode D13 and diode D14, the other end of capacitor C 15 connects respectively one end of capacitor C 17, the positive pole of the negative pole of diode D15 and diode D16, the other end of capacitor C 17 connects respectively the negative pole of diode D17 and the positive pole of diode D18, the positive pole of diode D11 connects respectively one end of capacitor C 12 and 2 ends of transformer TRF secondary high pressure coil Ls, the other end of capacitor C 12 connects respectively the negative pole of diode D12, one end of the positive pole of diode D13 and capacitor C 14, the other end of capacitor C 14 connects respectively the negative pole of diode D14, one end of the positive pole of diode D15 and capacitor C 16, the other end of capacitor C 16 connects respectively the negative pole of diode D16, one end of the positive pole of diode D17 and capacitor C 18, the other end of capacitor C 18 connects respectively the negative pole of diode D18 and one end of resistance R 33, the other end of resistance R 33 is connected with the other end of resistance R 34.
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| Application Number | Priority Date | Filing Date | Title |
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| CN201320841123.9U CN203691241U (en) | 2013-12-19 | 2013-12-19 | Voltage-adjustable current-adjustable high-performance positive laser power supply circuit composed of 555 |
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| Application Number | Priority Date | Filing Date | Title |
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| CN201320841123.9U CN203691241U (en) | 2013-12-19 | 2013-12-19 | Voltage-adjustable current-adjustable high-performance positive laser power supply circuit composed of 555 |
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103633851A (en) * | 2013-12-19 | 2014-03-12 | 东文高压电源(天津)有限公司 | Voltage-adjustable current-adjustable high-performance positive laser power supply circuit composed of 555 |
| CN106411133A (en) * | 2016-06-28 | 2017-02-15 | 东文高压电源(天津)股份有限公司 | Efficient high-power quasi double-tube parallel driving high-voltage power supply circuit |
| CN110137793A (en) * | 2018-02-09 | 2019-08-16 | 舜宇光学(浙江)研究院有限公司 | Adjustable extent drive system and its driving method and application |
-
2013
- 2013-12-19 CN CN201320841123.9U patent/CN203691241U/en not_active Expired - Lifetime
Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103633851A (en) * | 2013-12-19 | 2014-03-12 | 东文高压电源(天津)有限公司 | Voltage-adjustable current-adjustable high-performance positive laser power supply circuit composed of 555 |
| CN106411133A (en) * | 2016-06-28 | 2017-02-15 | 东文高压电源(天津)股份有限公司 | Efficient high-power quasi double-tube parallel driving high-voltage power supply circuit |
| CN110137793A (en) * | 2018-02-09 | 2019-08-16 | 舜宇光学(浙江)研究院有限公司 | Adjustable extent drive system and its driving method and application |
| CN110137793B (en) * | 2018-02-09 | 2020-11-13 | 舜宇光学(浙江)研究院有限公司 | Adjustable range driving system and driving method and application thereof |
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