TW202407493A - Voltage generating device - Google Patents

Abstract

A voltage generating device includes a low-dropout voltage regulator and a control signal generator. The low-dropout voltage regulator provides an output voltage to a power distribution network. The low-dropout voltage regulator has a feedback circuit, the feedback circuit divides the output voltage to generate a feedback voltage according to a voltage dividing ratio, wherein the feedback circuit sets the voltage dividing ratio according to a plurality of control signals. The control signal generator is coupled to the feedback circuit and the power distribution network, and generates the control signals by comparing a sensing voltage on a reference end of the power distribution network with a plurality of threshold voltages.

Description

voltage generating device

The present invention relates to a voltage generating device, and in particular to a voltage generating device that can compensate for load conditions and power supply networks.

In the conventional technology, a low-dropout voltage regulator is often used to provide an output voltage to a power distribution network and enable operation of multiple circuits connected to the power distribution network. Due to the resistance voltage drop (IR-drop) generated by the internal resistance in the power distribution network, the voltage on the power distribution network may change significantly under different levels of load pumping conditions, and may cause the power distribution network to The circuit on the road may malfunction. Therefore, how to provide a suitable voltage generating device that can stably provide a stable voltage for the power distribution network is an important issue for those skilled in the art.

The present invention provides a voltage generating device that can adjust the generated output voltage in response to the load current of a power distribution network.

The voltage generating device of the present invention includes a low dropout voltage regulator and a control signal generator. The low-dropout voltage regulator provides an output voltage to the power distribution network. The low-dropout voltage regulator has a feedback circuit. The feedback circuit divides the output voltage according to the voltage dividing ratio to generate a feedback voltage. The feedback circuit operates according to multiple controls. signal to set the voltage dividing ratio. The control signal generator is coupled to the feedback circuit and the power distribution network to compare the sensing voltage at the reference point of the power distribution network with a plurality of threshold voltages to generate the control signal.

Based on the above, the voltage generating device of the present invention can adjust the voltage dividing ratio of the feedback circuit in the low-dropout voltage regulator to generate the output voltage according to the sensed voltage at the reference point of the power distribution network. In this way, the output voltage of the voltage generating device can dynamically adjust the voltage value of the output voltage according to the load-carrying status of the power distribution network, effectively improving the stability of the output voltage and maintaining the normal operation of the system.

Please refer to FIG. 1 , which is a schematic diagram of a voltage generating device according to an embodiment of the present invention. The voltage generating device 100 is coupled to the power distribution network PDN, and is used to provide the generated output voltage VLDO to the power distribution network PDN to provide its power supply VDD. The voltage generating device 100 includes a low dropout voltage regulator 110 and a control signal generator 120 . The control signal generator 120 is coupled to the low dropout voltage regulator 110 and the power distribution network PDN. Among them, the low-dropout voltage regulator 110 has a feedback circuit (not shown). The feedback circuit is used to divide the output voltage VLDO according to a voltage dividing ratio and generate a feedback voltage. The low-dropout voltage regulator 110 can divide the output voltage VLDO according to a voltage dividing ratio. The feedback voltage dividing ratio is used to adjust the voltage value of the generated output voltage VLDO.

In this embodiment, the control signal generator 120 is coupled to a reference point RT of the power distribution network PDN, and receives the sensing voltage VSEN on the reference point RT of the power distribution network PDN. The control signal generator 120 receives a plurality of threshold voltages VTHx and compares the sensing voltage VSEN with a plurality of threshold voltages VTHx to respectively generate a plurality of control signals CTx. Further, the control signal generator 120 may provide the control signal CTx to the low dropout voltage regulator 110 . The low-dropout voltage regulator 110 can adjust the voltage dividing ratio provided by the feedback circuit according to the control signal CTx.

In detail, when the power distribution network PDN changes from a light load to a heavy load, the sensing voltage VSEN on the reference point RT of the power distribution network PDN decreases accordingly. The control signal generator 120 can generate the control signal CTx through the comparison result of the sensing voltage VSEN and the threshold voltage VTHx, and adjust the voltage dividing ratio provided by the feedback circuit through the control signal CTx to adjust the voltage value of the output voltage VLDO. is increased to respond to load changes on the power distribution network PDN. In contrast, when the power distribution network PDN changes from a heavy load to a light load, the sensing voltage VSEN on the reference point RT of the power distribution network PDN increases correspondingly. The control signal generator 120 can generate the control signal CTx through the comparison result of the sensing voltage VSEN and the threshold voltage VTHx, and adjust the voltage dividing ratio provided by the feedback circuit through the control signal CTx so that the voltage value of the output voltage VLDO is Adjust it lower to cope with load changes on the power distribution network PDN.

Incidentally, the threshold voltage VTHx in the embodiment of the present invention can be set according to the changing range of the sensing voltage VSEN that may be generated due to the load change of the power distribution network PDN. In addition, the reference point RT of the power distribution network PDN can be set at the end point of the power distribution network PDN with the heaviest load.

Please refer to FIG. 2 below, which is a circuit diagram of a voltage generating device according to another embodiment of the present invention. The voltage generating device 200 is coupled to the power distribution network PDN, and is used to provide the generated output voltage VLDO to the power distribution network PDN. The voltage generating device 200 includes a low dropout voltage regulator 210 and a control signal generator 220 . The low dropout voltage regulator 210 includes an amplifier AMP1, a power transistor M1 and a feedback circuit 211. The feedback circuit 211 includes resistors R1 and R2. The resistors R1 and R2 are coupled in series between the transistor M1 and the reference ground terminal GND. The feedback circuit 211 is used to divide the output voltage VLDO to generate the feedback voltage VFB.

The negative input terminal of the amplifier AMP1 receives the reference voltage REF, and the positive input terminal of the amplifier AMP1 receives the feedback voltage VFB. The output terminal of the amplifier AMP1 is coupled to the control terminal of the transistor M1. In addition, the first terminal of the transistor M1 receives the input voltage VIN, and the second terminal of the transistor M1 serves as the output terminal of the voltage generating device 200 to generate the output voltage VLDO and is coupled to the feedback circuit 211 .

It is worth mentioning that resistor R2 is a variable resistor. Among them, the resistance value of the resistor R2 can be adjusted according to the control signals CT1 and CT2. Control signals CT1 and CT2 are generated by the control signal generator 220. The control signal generator 220 includes comparators CMP1 and CMP2. The comparator CMP1 compares the threshold voltage VTH1 with the sensing voltage VSEN on the reference point RT of the power distribution network PDN and generates the control signal CT1. The comparator CMP2 compares the threshold voltage VTH2 with the sensing voltage VSEN on the reference point RT of the power distribution network PDN and generates the control signal CT2. Take the threshold voltage VTH1 being greater than VTH2 as an example. When the sensing voltage VSEN is greater than the threshold voltage VTH1, the control signal generator 220 can generate the control signals CT1 and CT2 that are both disabled to make the resistor R2 equal to a first resistance; when the sensing voltage VSEN is between the threshold voltages VTH1 and VTH2 When, the control signal generator 220 can generate enable and disable control signals CT1 and CT2 respectively to make the resistor R2 equal to a second resistance; when the sensing voltage VSEN is less than the threshold voltage VTH2, the control signal generator 220 can Control signals CT1 and CT2, both of which are enabled, are generated to make the resistor R2 equal to a third resistor, wherein the first resistor is greater than the second resistor, and the second resistor is greater than the third resistor.

It is worth noting that more than two comparators can also be constructed in the control signal generator 220 and generate more than two control signals accordingly. In this way, the resistor R2 can be adjusted in multiple stages to improve the resolution of the adjustment of the voltage dividing ratio.

From the above description, it is easy to know that the output voltage VLDO generated by the voltage generating device 200 can be adaptively adjusted according to the load status of the power distribution network PDN, reducing the instability time of the output voltage VLDO due to changes in the load status. Improve the stability of the system's operation.

Please refer to FIG. 3 below, which is a circuit diagram of a voltage generating device according to another embodiment of the present invention. The voltage generating device 300 is coupled to the power distribution network PDN, and is used to provide the generated output voltage VLDO to the power distribution network PDN. The voltage generating device 300 includes a low dropout voltage regulator 310, a control signal generator 320, a threshold voltage generator 330, and a bias current generator 340. The implementation details of the low dropout voltage regulator 310 and the control signal generator 320 are similar to the implementation details of the low dropout voltage regulator 210 and the control signal generator 220 in the previous embodiment, and will not be described again here.

In this embodiment, the threshold voltage generator 330 includes an amplifier AMP2, a power transistor M2, and resistors R3 and R4. Amplifier AMP2, power transistor M2 and resistors R3 and R4 construct another low dropout voltage regulator. The negative input terminal of the amplifier AMP2 receives the reference voltage VREF; the positive input terminal of the amplifier AMP2 is coupled to the terminal point where the resistors R3 and R4 are coupled; the output terminal of the amplifier AMP2 is coupled to the control terminal of the power transistor M2. The first terminal of the power transistor M2 receives the input voltage VIN, and the second terminal of the power transistor M2 is coupled to the first terminal of the resistor R3. The resistors R3 and R4 are connected in series between the second terminal of the power transistor M2 and the reference ground terminal GND. The reference voltage VREF may be equal to the reference voltage REF.

In this embodiment, the target voltage VCORE is set to make the sensing voltage VSEN on the reference point RT of the power distribution network PDN. On the premise that the resistor R3 and the resistor R1 are made the same, the target voltage VCORE = . When there is a load current IL at the reference point RT of the power distribution network PDN, the relationship between the target voltage VCORE and the output voltage VLDO of the voltage generating device 300 can be written as VCORE = , where Req is equal to the equal resistance between the output terminal of the voltage generating device 300 and the reference point RT.

To analyze further, the target voltage VCORE can be equal to , so we can get R2 = . In this way, the resistor R2 can be adjusted according to the change of the load current IL.

Incidentally, when the load current IL is equal to 0, the resistors R2 and R4 are equal.

On the other hand, unlike the previous embodiment, the voltage generating device 300 of this embodiment is further provided with a bias current generator 340 . The bias current generator 340 is coupled to the amplifier AMP1 and the control signal generator 320 . The bias current generator 340 receives the control signals CT1 and CT2 generated by the control signal generator 320 and provides a bias current to the amplifier AMP1 according to the control signals CT1 and CT2. The magnitude of the bias current provided by the bias current generator 340 may be positively related to the number of enabled control signals CT1 and CT2.

Please note that when a large load change occurs on the power distribution network PDN, the bias current generator 340 can provide a relatively large bias current to the amplifier AMP1 so that the amplifier AMP1 can increase the response speed to increase the generated output voltage. VLDO tends to a stable state, improving system stability.

Please refer to FIG. 4 below. FIG. 4 is a schematic diagram of an implementation of a bias current generator according to an embodiment of the present invention. The bias current generator 400 includes a plurality of switches SW1˜SWN constructed of transistors, and a plurality of current sources constructed of transistors MB1˜MBN. The switches SW1~SWN are coupled in series with the transistors MB1~MBN respectively. The switches SW1~SWN are connected in parallel with each other, and the transistors MB1~MBN are also connected in parallel with each other. The switches SW1~SWN receive control signals CT1~CTN respectively. Each of the switches SW1 to SWN is turned on or off according to the corresponding control signals CT1 to CTN. Taking the control signal CT1 as an example, when the control signal CT1 is enabled, the corresponding switch SW1 is turned on. In contrast, when the control signal CT1 is disabled, the corresponding switch SW1 is turned off. The control signals CT1 ~ CTN may be provided by the control signal generator 320 as shown in FIG. 3 . The number of control signals CT1~CTN can be 2 or more than 2, and there is no certain limit.

The control terminals of transistors MB1~MBN receive the same bias voltage VBIAS. When the corresponding switches SW1 ~ SWN are turned on, the current source formed by each transistor MB1 ~ MBN can provide the bias current IB according to the bias voltage VBIAS. When more switches SW1 to SWN are turned on, the bias current IB provided by the bias current generator 400 becomes larger.

The transistors MB1 to MBN may have the same channel aspect ratio, or may have different channel aspect ratios, without certain limitations. For example, the channel aspect ratio of transistors MB1~MBN can also be 1:2:...:2 ^N-1 .

Please refer to FIG. 3 , FIG. 5A and FIG. 5B simultaneously below. FIG. 5A and FIG. 5B respectively illustrate the operation waveform diagrams of the voltage generating device under different load conditions according to the embodiment of the present invention. In FIG. 5A , the waveform of the load current IL may be a unit step. Based on the current value of the load current IL being large enough, the comparators CMP1 and CMP2 can simultaneously generate enabled control signals CT1 and CT2. Correspondingly, the output voltage VLDO generated by the low-dropout voltage regulator without compensation in the prior art may be the voltage waveform 501. The voltage waveform 501 has a relatively long stabilization time, the voltage waveform 501 has the highest overshoot and undershoot amplitudes, and the final stable voltage value of the voltage waveform 501 is also lower than the target voltage.

In addition, the output voltage VLDO that can be generated by the voltage generating device 300 can be the voltage waveform 502 only through the compensation action of adjusting the voltage dividing ratio of the feedback circuit 311 . It can be clearly found that by adjusting the compensation action of the voltage dividing ratio of the feedback circuit 311, the final stable voltage value of the voltage waveform 502 of the output voltage VLDO can be close to the target voltage.

If only through the compensation action of the bias current generator 340, the output voltage VLDO that the voltage generating device 300 can generate can be the voltage waveform 503. The voltage waveform 503 can have a relatively short settling time, and its overshoot and undershoot amplitudes can be effectively reduced.

If the compensation action of adjusting the voltage dividing ratio of the feedback circuit 311 and the compensation action of the bias current generator 340 are performed at the same time, the output voltage VLDO that can be generated by the voltage generation device 300 can be the voltage waveform 504 . The voltage waveform 504 can have a relatively short stabilization time, the amplitude of its overshoot and undershoot can be effectively reduced, and the final stable voltage value of the voltage waveform 504 can be close to the target voltage.

In FIG. 5B , the waveform of the load current IL may be a continuous pulse wave. Correspondingly, the comparators CMP1 and CMP2 can simultaneously generate interleaved enabled and disabled control signals CT1 and CT2. Among them, the output voltage VLDO generated by the low-dropout voltage regulator without compensation in the prior art may be the voltage waveform 511. The voltage waveform 511 has a relatively long stabilization time, the overshoot and undershoot amplitudes of the voltage waveform 511 are the highest, and the final stable voltage value of the voltage waveform 511 is also lower than the target voltage. The voltage generation device 300 of the embodiment of the present invention in Figure 3 can generate a relatively short stabilization time; the voltage waveform 512 of the embodiment has relatively low overshoot and undershoot amplitudes; and the final stable voltage value is also a voltage waveform close to the target voltage. .

To sum up, the voltage generating device of the present invention performs voltage dividing by the feedback circuit of the low-dropout voltage regulator by receiving the sensed voltage on the power distribution network and comparing the sensed voltage with a plurality of threshold voltages. Ratio adjustment action. Depending on the size of the load, the voltage generating device can adaptively adjust the voltage value of the output voltage generated, which can effectively improve the stability of the output voltage and maintain the normal operation of the system.

100, 200, 300: Voltage generating device 110, 210, 310: Low dropout voltage regulator 120, 220, 320: Control signal generator 211, 321: Feedback circuit 330:Threshold voltage generator 340, 400: Bias current generator 501~504, 511, 512: Voltage waveform AMP1, AMP2: amplifier CMP1, CMP2: comparator CTx, CT1~CTN: control signal GND: reference ground terminal IB: bias current IL: load current M1, M2: power transistor MB1~MBN: Transistor PDN: Power Distribution Network R1~R4: Resistor RT: reference point SW1~SWN: switch VBIAS: bias voltage VDD: power supply VIN: input voltage VFB: feedback voltage VLDO: output voltage VREF, REF: reference voltage VSEN: sense voltage VTHx, VTH1, VTH2: threshold voltage

FIG. 1 is a schematic diagram of a voltage generating device according to an embodiment of the present invention. FIG. 2 is a circuit diagram of a voltage generating device according to another embodiment of the present invention. FIG. 3 is a circuit diagram of a voltage generating device according to another embodiment of the present invention. FIG. 4 is a schematic diagram of an implementation of a bias current generator according to an embodiment of the present invention. 5A and 5B respectively illustrate operation waveform diagrams of the voltage generating device under different load conditions according to the embodiment of the present invention.

100: Voltage generating device

110:Low dropout voltage regulator

120:Control signal generator

CTx: control signal

PDN: Power Distribution Network

RT: reference point

VDD: power supply voltage

VIN: input voltage

VLDO: output voltage

VSEN: sense voltage

VTHx: threshold voltage

Claims (12)

A voltage generating device comprising: A low-dropout voltage regulator provides an output voltage to a power distribution network. The low-dropout voltage regulator has a feedback circuit that divides the output voltage according to a voltage dividing ratio to generate a feedback voltage. , wherein the feedback circuit sets the voltage dividing ratio according to a plurality of control signals; and A control signal generator is coupled to the feedback circuit and the power distribution network to compare a sensing voltage at a reference point of the power distribution network with a plurality of threshold voltages to generate the control signals. The voltage generating device of claim 1, wherein the feedback circuit includes a first resistor and a second resistor, and the first resistor and the second resistor are connected in series between the output end of the voltage generating device and a Between reference ground terminals. The voltage generating device of claim 2, wherein the second resistor is a variable resistor, and the feedback circuit adjusts the resistance value of the second resistor according to the control signals. The voltage generating device of claim 1, wherein the control signal generator includes a first comparator and a second comparator, the first comparator compares the sensing voltage with a first threshold voltage to generate a The first control signal, the second comparator compares the sensing voltage with a second threshold voltage to generate a second control signal, wherein the first threshold voltage and the second threshold voltage are different. The voltage generating device of claim 4, wherein the first comparator enables the first control signal when the sensing voltage is less than the first threshold voltage, and the second comparator enables the first control signal when the sensing voltage is less than The second threshold voltage enables the second control signal. The voltage generating device of claim 1, wherein the reference point is the end point with the heaviest load on the power distribution network. The voltage generating device of claim 1, wherein the low dropout voltage regulator further includes: An amplifier having a negative input terminal to receive a reference voltage, and a positive input terminal of the amplifier to receive the feedback voltage; and A power transistor has a first terminal receiving an input voltage, a control terminal of the transistor coupled to the output terminal of the amplifier, and a second terminal of the power transistor coupled to the feedback circuit and used to generate the output voltage. . The voltage generating device as claimed in claim 7, further comprising: A bias current generator is coupled to the power transistor and the control signal generator, and adjusts a current value of a bias current provided to the power transistor according to the control signals. The voltage generating device as claimed in claim 8, wherein the bias current generator includes: A plurality of switches, wherein first ends of the switches are commonly coupled to the amplifier, and each switch is controlled by each control signal to be turned on or off; and A plurality of current sources are respectively coupled in series with the switches to respectively generate a plurality of sub-bias currents according to a bias voltage. The voltage generating device of claim 9, wherein each current source includes: A transistor is coupled in series between the corresponding switch and a reference ground terminal. When the corresponding switch is turned on, the transistor generates each sub-bias current according to the bias voltage. The voltage generating device described in claim 1 further includes: A threshold voltage generator is used to generate a first threshold voltage and divide the first threshold voltage to generate at least a second threshold voltage. The voltage generating device of claim 11, wherein the threshold voltage generator is a low dropout voltage regulator.

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