CN206848850U - A kind of low pressure difference linear voltage regulator of super low-power consumption - Google Patents
A kind of low pressure difference linear voltage regulator of super low-power consumption Download PDFInfo
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- CN206848850U CN206848850U CN201720775815.6U CN201720775815U CN206848850U CN 206848850 U CN206848850 U CN 206848850U CN 201720775815 U CN201720775815 U CN 201720775815U CN 206848850 U CN206848850 U CN 206848850U
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Abstract
Technical field of power management is the utility model is related to, particularly a kind of low pressure difference linear voltage regulator of super low-power consumption.The utility model discloses a kind of low pressure difference linear voltage regulator of super low-power consumption, including major loop circuit, output voltage detection and the first dynamic bias generation circuit and the first current source, first current source provides quiescent bias current Ib0 for the error amplifier of main loop circuit, the output voltage that the output voltage detection and the first dynamic bias source generating circuit are used to detect major loop circuit over-pressed and under-voltage and using over-pressed and under-voltage the first dynamic bias Ib1 being converted into its positively related electric current as the error amplifier of major loop circuit.The utility model has super low-power consumption (being less than 300nA) while fast response time, and output voltage electric current is stable, and has overtemperature and overcurrent defencive function, and safety and reliability is high.
Description
Technical field
The utility model belongs to technical field of power management, more particularly to a kind of low pressure difference linearity voltage stabilizing of super low-power consumption
Device.
Background technology
With the development of technology and the quick popularization of portable electric appts so that IC design is intended to low work(
The features such as consumption, high security, high energy efficiency and high integration.
Power management module is the basic element circuit of chip, low pressure difference linear voltage regulator (LDO, Low
DropOutRegulator) it is widely used as power management module in large scale integrated circuit system
LDO is widely applied because required external component is less in the power-supply management system of low-power consumption.By
The influence of low-power consumption requirement, traditional LDO's is relatively simple for structure, when supply voltage or output load condition change due to not having
There are enough electric currents to support LDO quick responses to cause LDO outputs to show larger over-pressed or under-voltage phenomenon, and return to
The time of stable output valve is also longer.Further, since defencive function needs to consume certain power consumption in LDO, so traditional is low
Mostly clipped defencive function, including overheat protector and overcurrent protection function, such as publication in power consumption LDO:
CN102789256B, so it is unfavorable for the work safety of chip, easy excess temperature or excessively stream so as to cause chip failure.
The content of the invention
The purpose of this utility model is to provide a kind of low pressure difference linear voltage regulator of super low-power consumption above-mentioned to solve
Problem.
To achieve the above object, the technical solution adopted in the utility model is:A kind of low pressure difference linearity of super low-power consumption is steady
Depressor, including the detection of major loop circuit, output voltage and the first dynamic bias generation circuit and the first current source, described the
One current source provides quiescent bias current Ib0 for the error amplifier of main loop circuit, and the output voltage detection and first move
State bias current generating circuit is used to detect output voltage over-pressed and under-voltage of major loop circuit and over-pressed and under-voltage conversion
First dynamic bias Ib1 of the positively related electric currents of Cheng Yuqi as the error amplifier of major loop circuit.
Further, the quiescent bias current Ib0 is less than 10nA.
Further, the output voltage detection and the first dynamic bias generation circuit include the first current mirror, ratio
The electricity of homophase input termination major loop compared with device A0, comparator A1, PMOS M4-M5 and NMOS tube M6-M7, the comparator A0
The output end Vfb, the comparator A0 of sample circuit anti-phase input termination reference voltage Vref are pressed, the comparator A0's is defeated
Go out to terminate PMOS M4 grid, the output end of the voltage sampling circuit of the anti-phase input termination major loop of the comparator A1
Vfb, the comparator A1 homophase input termination reference voltage Vref, the output termination PMOS M5 of comparator A1 grid
Pole, the grounded drain of the PMOS M4 and M5, the source electrode of the PMOS M4 and M5 connects the input of the first current mirror, described
The output end of first current mirror connects the drain electrode of NMOS tube M6 grid, NMOS tube M7 grid and NMOS tube M7 simultaneously, described
NMOS tube M6 and M7 source ground, the drain electrode of the NMOS tube M6 provide the first dynamic for the error amplifier of main loop circuit
Bias current Ib1.
Further, first current mirror is non-linear current mirror.
Further, first current mirror includes PMOS M8-M10, and the source electrode of the PMOS M8 and M9 connects electricity
Source VCC, the PMOS M8 drain electrode connect the drain electrode of NMOS tube M6 grid, NMOS tube M7 grid and NMOS tube M7 simultaneously,
The drain electrode of the PMOS M9 connects PMOS M4, M5 and M10 source electrode simultaneously, and the grid of the PMOS M8-M10 connects partially simultaneously
Voltage Vbias is put, the drain electrode of the PMOS M10 meets current source Ib3.
Further, in addition to output electric current measure and the second dynamic bias generation circuit, the output current are examined
Survey and the second dynamic bias generation circuit is used to detect the output current of major loop circuit and by the output of major loop circuit
Electric current change by a certain percentage after as major loop circuit error amplifier the second dynamic bias Ib2.
Further, the output electric current measure and the second dynamic bias generation circuit include PMOS Ms1,
NMOS tube M11 and NMOS tube M12, the PMOS Ms1 grid connect the power output pipe Mp0 of major loop circuit control terminal,
The source electrode of the PMOS Ms1 connects power supply VCC, the PMOS Ms1 drain electrode while connects NMOS tube M11 drain electrode, NMOS tube
M11 grid and NMOS tube M12 grid, the source ground of the NMOS tube M11 and NMOS tube M12, the NMOS tube M12's
Drain and provide the second dynamic bias Ib2 for the error amplifier of main loop circuit.
Further, in addition to output current decision circuitry and current foldback circuit, the output current decision circuitry are used
Whether exceed setting value in the output current for judging major loop circuit, when the output current of major loop circuit exceedes setting value,
Then output control signal makes it start work to current foldback circuit, and the current foldback circuit is used to carry out major loop circuit
Overcurrent protection.
Further, the current foldback circuit is Zigzag type current foldback circuit.
Further, in addition to output current decision circuitry and thermal-shutdown circuit, the output current decision circuitry are used
Whether exceed setting value in the output current for judging major loop circuit, when the output current of major loop circuit exceedes setting value,
Then output control signal makes it start work to thermal-shutdown circuit, and the thermal-shutdown circuit is used to carry out major loop circuit
Overheat protector.
Further, the voltage sampling circuit of the major loop circuit includes resistance R1 and R0, and the first of the resistance R1
End is connected with resistance R0 first end, the output end of the power output pipe of the second termination major loop circuit of the resistance R1, institute
Resistance R0 the second end ground connection is stated, the resistance R1 is adjustable resistance.
Advantageous effects of the present utility model:
The utility model is detected by output voltage and the first dynamic bias generation circuit, when output overvoltage or owes
The first dynamic bias Ib1 can be produced during pressure, the electric current is dynamic current, electric only under output overvoltage or undervoltage condition
Flow valuve becomes big, and the current value very little when exporting stable, and quiescent bias current Ib0 sets very little, meets super low-power consumption
Design.
Non-linear current mirror technology employed in output voltage detection and the first dynamic bias generation circuit so that
The amplitude of LDO load voltages mutation can provide mistakes of more first dynamic bias Ib1 to major loop circuit when larger
Poor amplifier, so that LDO has faster dynamic responding speed.
Output current decision circuitry is used for the effect for switching LDO defencive functions, and only output current exceedes set threshold
Defencive function is just opened during value so that defencive function is closed so as to reach low-power consumption under the conditions of low-load when load current is smaller
Purpose, because the extreme case of overtemperature and overcurrent will not occur for low-load condition, therefore the on-off action of output electric current measure makes
The work safety of circuit is not influenceed while power consumption must be reduced.
The threshold value of overcurrent protection does not change with the difference of person's output voltage setting, is set by different resistance R1 value
The startup threshold value of overcurrent protection and the current limit value of output short-circuit will not change when determining different output voltages.So as to assign
More possible Configuration Values, realization have the selection of programmable voltage in several modes to output voltage.
Brief description of the drawings
Fig. 1 is the structural representation of the utility model embodiment;
Fig. 2 is the circuit theory diagrams of the major loop circuit of the utility model embodiment;
Fig. 3 is the output voltage detection and the circuit of the first dynamic bias source generating circuit of the utility model embodiment
Schematic diagram;
Fig. 4 is the circuit theory diagrams of first current mirror of the utility model embodiment;
Fig. 5 is the output electric current measure of the utility model embodiment and the circuit of the second dynamic bias source generating circuit
Schematic diagram;
Fig. 6 is the output current decision circuitry of the utility model embodiment and the circuit theory diagrams of current foldback circuit;
Fig. 7 is the circuit theory diagrams of the thermal-shutdown circuit of the utility model embodiment.
Embodiment
The utility model is further illustrated in conjunction with the drawings and specific embodiments.
As shown in figure 1, a kind of low pressure difference linear voltage regulator of super low-power consumption, including the inspection of major loop circuit 11, output voltage
Survey and the first dynamic bias generation circuit 13 and the first current source 12, first current source 12 are the mistake of main loop circuit
Poor amplifier provides quiescent bias current Ib0, and the output voltage detection and the first dynamic bias generation circuit 13 are used for
The output voltage of detection major loop circuit 11 over-pressed and under-voltage and over-pressed and under-voltage be converted into and its positively related electric current work
For the first dynamic bias Ib1 of the error amplifier of main loop circuit 11.
In this specific embodiment, the quiescent bias current Ib0 is less than 10nA, preferably smaller than 5nA, more preferably less than 3nA.
As long as i.e. quiescent bias current Ib0 size meets the minimum of the normal work of major loop circuit 11, ultralow so as to realize
Power consumption.Certainly, in other embodiments, quiescent bias current Ib0 is set according to actual conditions, as long as meeting major loop circuit 11
The minimum of normal work, this is that those skilled in the art can realize easily, is no longer described in detail.
In this specific embodiment, major loop circuit 11 includes error comparator, power output pipe, compensation network and voltage and adopted
Sample circuit, specifically, as shown in Fig. 2 error comparator includes NMOS tube M0-M1 and PMOS M2-M3, power output pipe is
PMOS Mp0, compensation network include electric capacity Cc and resistance Rc, and voltage sampling circuit includes resistance R1 and R0, and its specific connection is closed
System may refer to Fig. 2, and this is no longer described in detail.
In this specific embodiment, resistance R1 is adjustable resistance, and output voltage can be realized by the resistance for changing resistance R1
Programmable function.Loop, which controls, causes voltage Vfb=Vref, so as to obtain stable output voltage Vout=(R1+R0) *
Vref/R0。
Certainly, in other embodiments, major loop circuit 11 can also use existing other low pressure difference linear voltage regulators
Circuit, this is that those skilled in the art can realize easily, is no longer described in detail.
In this specific embodiment, as shown in figure 3, output voltage detection and the first dynamic bias generation circuit 13 include
First current mirror 1, comparator A0, comparator A1, PMOS M4-M5 and NMOS tube M6-M7, the homophase input of the comparator A0
Terminate the output end Vfb (node i.e. between resistance R1 and R0), the comparator A0 of the voltage sampling circuit of major loop circuit
Anti-phase input termination reference voltage Vref, the output termination PMOS M4 of comparator A0 grid, the comparator A1
Anti-phase input termination major loop circuit 11 voltage sampling circuit output end Vfb, the in-phase input end of the comparator A1
Reference voltage Vref, the output termination PMOS M5 of comparator A1 grid are connect, the drain electrode of the PMOS M4 and M5 connects
Ground, the source electrode of the PMOS M4 and M5 connect the input of the first current mirror 1, and the output end of first current mirror 1 connects simultaneously
The drain electrode of NMOS tube M6 grid, NMOS tube M7 grid and NMOS tube M7, the source ground of the NMOS tube M6 and M7 are described
NMOS tube M6 drain electrode connects NMOS tube M0 and M1 source electrode, and the as error amplifier of major loop circuit 11 provides the first dynamic partially
Put electric current Ib1.
In this specific embodiment, first current mirror 1 is preferably non-linear current mirror, certainly, in other embodiments,
Linear current mirror can also be used.
Specifically, as shown in figure 4, first current mirror 1 includes PMOS M8-M10, the source of the PMOS M8 and M9
Pole connects power supply VCC, the PMOS M8 drain electrode while meets NMOS tube M6 grid, NMOS tube M7 grid and NMOS tube M7
Drain electrode, the drain electrode of the PMOS M9 connect PMOS M4, M5 and M10 source electrode simultaneously, and the grid of the PMOS M8-M10 is same
When meet bias voltage Vbias, the drain electrode of the PMOS M10 meets current source Ib3.Certainly, in other embodiments, the first electric current
Mirror 1 can also use other non-linear current mirror circuits, and this is that those skilled in the art can realize easily, no longer in detail
Explanation.
When output voltage is over-pressed or under-voltage, i.e. voltage Vref is more than or less than voltage Vfb, due to comparator A0 and
A1 inputs generates electric current Idyn to the imbalance of pipe, completes from the over-pressed or under-voltage conversion process for changing into electric current.It is non-thread
Property current mirror 1 cause electric current Imirr/Idyn value increase with electric current Idyn increase, so as to output overvoltage or owe
In the case of pressure quickly produce the first dynamic bias Ib1, and the first dynamic bias Ib1 value with overvoltage or
The increase of under-voltage amplitude and increase rapidly so that LDO has faster dynamic responding speed.
Certainly, in other embodiments, output voltage detection and the first dynamic bias generation circuit 13 can also be adopted
With existing other voltage detectings and change-over circuit, this is that those skilled in the art can realize easily, is no longer described in detail.
In this specific embodiment, in addition to output electric current measure and the second dynamic bias generation circuit 14, it is described defeated
Go out the output current that current detecting and the second dynamic bias generation circuit 14 are used to detecting major loop circuit 11 and by main ring
The output current of road circuit 11 change by a certain percentage after as major loop circuit 11 error amplifier the second dynamic bias
Electric current Ib2.
Specifically, as shown in figure 5, the output electric current measure and the second dynamic bias generation circuit 14 include PMOS
Pipe Ms1, NMOS tube M11 and NMOS tube M12, the grid of the PMOS Ms1 connect the PMOS Mp0 of major loop circuit 11 grid
(power output pipe Mp0 control terminal), the source electrode of the PMOS Ms1 meet power supply VCC, and the drain electrode of the PMOS Ms1 is simultaneously
The grid of NMOS tube M11 drain electrode, NMOS tube M11 grid and NMOS tube M12 is connect, the NMOS tube M11's and NMOS tube M12
Source ground, the drain electrode of the NMOS tube M12 connect the error amplifier of NMOS tube M0 and M1 source electrode, as major loop circuit 11
Second dynamic bias Ib2 is provided.
The output current of major loop circuit 11 is pressed one by output electric current measure and the second dynamic bias generation circuit 14
Certainty ratio exports the error amplifier to major loop circuit 11 after reducing, as its second dynamic bias Ib2, when output electricity
When stream is bigger, the second dynamic bias Ib2 is bigger, so that LDO has faster dynamic responding speed.
Fig. 5 has been merely given as output electric current measure and the preferred embodiment of the second dynamic bias generation circuit 14,
In other embodiments, other circuit implementations can also be used, this is that those skilled in the art can realize easily, no
Describe in detail again.
In this specific embodiment, in addition to output current decision circuitry 15 and current foldback circuit 16, the output current
Decision circuitry 15 is used to judge whether the output current of major loop circuit 11 exceedes setting value, when the output electricity of major loop circuit 11
When stream exceedes setting value, then output control signal makes it start work, the current foldback circuit 16 to current foldback circuit 16
For carrying out overcurrent protection to major loop circuit 11.
In this specific embodiment, the current foldback circuit 16 is preferably Zigzag type current foldback circuit.
Specifically, as shown in fig. 6, output current decision circuitry 15 includes PMOS Ms0 and reference current source Ib4, it is described
Current foldback circuit 16 includes PMOS M13-M17, NMOS tube M22-M23, switch SW0-SW2, PMOS Mp1-Mp2, resistance
R2-R3 and current source Ib5-Ib7.Specific annexation is referring to Fig. 6, and this is no longer described in detail, PMOS Ms0 and reference current source Ib4
Between node OC be output current decision circuitry 15 output end, for output control signal to switch SW0-SW2 control
End, controlling switch SW0-SW2 conductings.
When the output current of major loop circuit 11 is more than setting value (excessively stream), i.e. electric current in PMOS Ms0 is more than reference
During current source Ib4 electric current, output end OC outputs are high level, and switch SW0-SW2 is closed so as to connect current foldback circuit 16,
The limit value of PMOS Mp0 upstream overcurrent when current foldback circuit 16 determines startup threshold value and output short-circuit.Load overcurrent
When startup threshold value Ioc=N*Vref/R2, wherein N is PMOS Mp0 and PMOS Ms0 mirroring ratios.During output short-circuit
Current limit value Ilim=N*Ib8*R3/R2.Mistake during by setting different resistance R1 value to set different output voltages
Flowing the startup threshold value of protection and the current limit value of output short-circuit will not change.So as to assign, output voltage is more possible to match somebody with somebody
Put value.
When the electric current in PMOS Ms0 is less than reference current source Ib4 electric current, output end OC outputs are low level, are opened
Close SW0-SW2 to disconnect so as to disconnect current foldback circuit, save energy consumption.
Certainly, in other embodiments, output current decision circuitry 15 and current foldback circuit 16 can also use existing
Circuit realize that this is that those skilled in the art can realize easily, no longer describe in detail.
In this specific embodiment, in addition to thermal-shutdown circuit 16, when the output current of major loop circuit 11 exceedes setting
During value, the output control signal of output current decision circuitry 15 makes it start work, the overheat protector to thermal-shutdown circuit 16
Circuit 16 is used to carry out overheat protector to major loop circuit 11.
Specifically, the NMOS tube M0 and M1 of major loop circuit 11 source electrode are by switching SW6 and the first current source 12,
One dynamic bias Ib1 and the second dynamic bias Ib2 connections, thermal-shutdown circuit 16 include PMOS M18-M19,
NMOS tube M20-M21, switch SW3-SW5, resistance R3, current source Ib8-Ib10 and temperature sensor D1, specific annexation are detailed
See Fig. 7, this is no longer described in detail, switchs the output end OC, PMOS M18 of SW3-SW5 control termination output current decision circuitry 15
Drain electrode and NMOS tube M20 drain electrode between node be thermal-shutdown circuit 16 output end OT, output end OT with switch SW6
Control terminal connection.In this specific embodiment, temperature sensor D1 is thermal diode.
When output end OC is high level, switch SW3-SW5 closures are so as to connect thermal-shutdown circuit 16, when temperature exceedes
During setting value, output end OT output high level, switch SW6 is disconnected, so that major loop circuit 11 is stopped, realizes excess temperature
Protection.
When output end OC is low level, switch SW3-SW5 is disconnected so as to disconnect thermal-shutdown circuit 16, reduces energy consumption.
Because excess temperature situation is only possible to occur in the case where output current is bigger, therefore excess temperature is turned off when output current is relatively descended
Protection circuit 16 does not interfere with the overheat protector function of its chip.
Although specifically showing and describing the utility model with reference to preferred embodiment, those skilled in the art should
This is understood, is not departing from the spirit and scope of the present utility model that appended claims are limited, in form and details
On the utility model can be made a variety of changes, be the scope of protection of the utility model.
Claims (10)
- A kind of 1. low pressure difference linear voltage regulator of super low-power consumption, it is characterised in that:Including major loop circuit, output voltage detection and First dynamic bias generation circuit and the first current source, first current source carry for the error amplifier of main loop circuit For quiescent bias current Ib0, the output voltage detection and the first dynamic bias generation circuit are used to detect major loop electricity The output voltage on road over-pressed and under-voltage and using over-pressed and under-voltage be converted into its positively related electric current as major loop circuit First dynamic bias Ib1 of error amplifier.
- 2. the low pressure difference linear voltage regulator of super low-power consumption according to claim 1, it is characterised in that:The quiescent biasing electricity Stream Ib0 is less than 10nA.
- 3. the low pressure difference linear voltage regulator of super low-power consumption according to claim 1 or 2, it is characterised in that:The output electricity Pressure detection and the first dynamic bias generation circuit include the first current mirror, comparator A0, comparator A1, PMOS M4-M5 It is described with NMOS tube M6-M7, the output end Vfb of the voltage sampling circuit of the homophase input termination major loop of the comparator A0 Comparator A0 anti-phase input termination reference voltage Vref, the output termination PMOS M4 of comparator A0 grid are described The output end Vfb of the voltage sampling circuit of comparator A1 anti-phase input termination major loop, the homophase input of the comparator A1 Terminate reference voltage Vref, the output termination PMOS M5 of comparator A1 grid, the drain electrode of the PMOS M4 and M5 Ground connection, the source electrode of the PMOS M4 and M5 connect the input of the first current mirror, and the output end of first current mirror connects simultaneously The drain electrode of NMOS tube M6 grid, NMOS tube M7 grid and NMOS tube M7, the source ground of the NMOS tube M6 and M7 are described NMOS tube M6 drain electrode provides the first dynamic bias Ib1 for the error amplifier of main loop circuit.
- 4. the low pressure difference linear voltage regulator of super low-power consumption according to claim 3, it is characterised in that:First current mirror For non-linear current mirror.
- 5. the low pressure difference linear voltage regulator of super low-power consumption according to claim 4, it is characterised in that:First current mirror Including PMOS M8-M10, the source electrode of the PMOS M8 and M9 connects power supply VCC, the PMOS M8 drain electrode while meets NMOS The drain electrode of pipe M6 grid, NMOS tube M7 grid and NMOS tube M7, the drain electrode of the PMOS M9 connect PMOS M4, M5 simultaneously With M10 source electrode, the grid of the PMOS M8-M10 meets bias voltage Vbias simultaneously, and the drain electrode of the PMOS M10 connects electricity Stream source Ib3.
- 6. the low pressure difference linear voltage regulator of super low-power consumption according to claim 1 or 2, it is characterised in that:Also include output Current detecting and the second dynamic bias generation circuit, the output electric current measure and the second dynamic bias generation circuit For detecting the output current of major loop circuit and after the output current of major loop circuit is changed by a certain percentage as main ring Second dynamic bias Ib2 of the error amplifier of road circuit.
- 7. the low pressure difference linear voltage regulator of super low-power consumption according to claim 6, it is characterised in that:The output current inspection Survey and the second dynamic bias generation circuit includes PMOS Ms1, NMOS tube M11 and NMOS tube M12, the PMOS Ms1 Grid connect major loop circuit power output pipe Mp0 control terminal, the source electrode of the PMOS Ms1 meets power supply VCC, described PMOS Ms1 drain electrode connects the grid of NMOS tube M11 drain electrode, NMOS tube M11 grid and NMOS tube M12 simultaneously, described NMOS tube M11 and NMOS tube M12 source ground, the drain electrode of the NMOS tube M12 carry for the error amplifier of main loop circuit For the second dynamic bias Ib2.
- 8. the low pressure difference linear voltage regulator of super low-power consumption according to claim 1 or 2, it is characterised in that:Also include output Electric current decision circuitry and current foldback circuit, the output current decision circuitry are used to judge that the output current of major loop circuit to be No to exceed setting value, when the output current of major loop circuit exceedes setting value, then output control signal is to current foldback circuit It is set to start work, the current foldback circuit is used to carry out overcurrent protection to major loop circuit.
- 9. the low pressure difference linear voltage regulator of super low-power consumption according to claim 1 or 2, it is characterised in that:Also include output Electric current decision circuitry and thermal-shutdown circuit, the output current decision circuitry are used to judge that the output current of major loop circuit to be No to exceed setting value, when the output current of major loop circuit exceedes setting value, then output control signal is to thermal-shutdown circuit It is set to start work, the thermal-shutdown circuit is used to carry out overheat protector to major loop circuit.
- 10. the low pressure difference linear voltage regulator of super low-power consumption according to claim 1 or 2, it is characterised in that:The major loop The voltage sampling circuit of circuit includes resistance R1 and R0, and the first end of the resistance R1 is connected with resistance R0 first end, described The output end of the power output pipe of resistance R1 the second termination major loop circuit, the second end ground connection of the resistance R0, the electricity Resistance R1 is adjustable resistance.
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CN201720775815.6U CN206848850U (en) | 2017-06-29 | 2017-06-29 | A kind of low pressure difference linear voltage regulator of super low-power consumption |
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Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
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CN107066014A (en) * | 2017-06-29 | 2017-08-18 | 英麦科(厦门)微电子科技有限公司 | A kind of low pressure difference linear voltage regulator of super low-power consumption |
CN108471230A (en) * | 2018-06-02 | 2018-08-31 | 丹阳恒芯电子有限公司 | A kind of current foldback circuit applied to Internet of Things |
CN108521119A (en) * | 2018-06-02 | 2018-09-11 | 丹阳恒芯电子有限公司 | A kind of current foldback circuit of resistance multiplexing |
CN108631270A (en) * | 2018-06-02 | 2018-10-09 | 丹阳恒芯电子有限公司 | A kind of current foldback circuit with self-test |
CN110488905A (en) * | 2019-07-17 | 2019-11-22 | 南开大学深圳研究院 | Low pressure difference linear voltage regulator overload protecting circuit |
CN114077273A (en) * | 2020-08-12 | 2022-02-22 | 株式会社东芝 | Constant voltage circuit |
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2017
- 2017-06-29 CN CN201720775815.6U patent/CN206848850U/en not_active Withdrawn - After Issue
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
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CN107066014A (en) * | 2017-06-29 | 2017-08-18 | 英麦科(厦门)微电子科技有限公司 | A kind of low pressure difference linear voltage regulator of super low-power consumption |
CN108471230A (en) * | 2018-06-02 | 2018-08-31 | 丹阳恒芯电子有限公司 | A kind of current foldback circuit applied to Internet of Things |
CN108521119A (en) * | 2018-06-02 | 2018-09-11 | 丹阳恒芯电子有限公司 | A kind of current foldback circuit of resistance multiplexing |
CN108631270A (en) * | 2018-06-02 | 2018-10-09 | 丹阳恒芯电子有限公司 | A kind of current foldback circuit with self-test |
CN110488905A (en) * | 2019-07-17 | 2019-11-22 | 南开大学深圳研究院 | Low pressure difference linear voltage regulator overload protecting circuit |
CN110488905B (en) * | 2019-07-17 | 2021-02-12 | 南开大学深圳研究院 | Low dropout linear regulator overload protection circuit |
CN114077273A (en) * | 2020-08-12 | 2022-02-22 | 株式会社东芝 | Constant voltage circuit |
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