JP2013059186A - Power supply circuit and method of controlling the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply circuit and a method of controlling the same capable of optimizing an input/output potential difference of a voltage regulator without requiring complicated control.SOLUTION: A power supply circuit 304 has: a DC-DC converter 301 stepping up or down an output voltage of a battery 300; a voltage regulator 302 stepping down an output voltage of the DC-DC converter 301; and voltage setting means 303 setting a step-up value or a step-down value of the output voltage of the DC-DC converter 301 depending on a value correlating with an output voltage of the voltage regulator 302.

Description

  The present invention relates to a power supply circuit for controlling the voltage of a battery to a constant voltage and a control method therefor, and more particularly to a power supply circuit that does not require complicated control for setting an output voltage and a control method therefor.

  Generally, a power supply circuit in a battery-driven electronic device includes a battery and a stabilization circuit that stabilizes an output voltage (also referred to as a terminal voltage) of the battery.

  The simplest stabilization circuit is, for example, a “voltage regulator” such as a linear regulator described in Patent Document 1 below. The voltage regulator outputs a stabilized voltage by dropping (decreasing) the input voltage. However, the voltage regulator discharges the drop of the input voltage as Joule heat, so there is a disadvantage that the power loss is large.

  On the other hand, a switching regulator, also called a switching power supply, uses a switching element (an element capable of turning on / off a part of an electric circuit) to convert and adjust power in a power converter that obtains desired output power from input power. A generic term for power supply devices. Among them, the one that converts DC power into another DC power is called a “DCDC converter”, and unlike voltage regulators that discharge voltage drops as Joule heat, power loss can be reduced. There is an advantage that high accuracy and high efficiency can be obtained. As a related technique of the DCDC converter, for example, there are those described in Patent Document 2 and Patent Document 3.

  Patent Document 2 describes a technique that can suppress fluctuations in output voltage such as stepping down and stepping up and down in a step-up / step-down DCDC converter, and can stabilize the output voltage. Patent Document 3 describes a technique that can suppress a useless switching loss in a boost conversion circuit by suppressing a voltage for power supply switching and improve a power saving effect.

  As described above, since the DCDC converter has an advantage that power loss can be reduced, it is conceivable to stabilize the voltage of the battery by using the DCDC converter instead of the voltage regulator, that is, “battery → DCDC”. Although a configuration of “converter → load” is conceivable, this configuration has a problem that a high-quality output voltage cannot be obtained due to the influence of ripple noise (a minute vibration component accompanying switching) appearing in the output of the DCDC converter. Therefore, in general, a configuration in which ripple noise is suppressed by a dropper (voltage regulator), that is, a combination of “battery → DCDC converter → voltage regulator → load” is adopted. In many cases, such a configuration is adopted.

  As a technique related to the combination of the DCDC converter and the voltage regulator, for example, there are those described in Patent Document 4 and Patent Document 5 below.

  Patent Document 4 includes a booster (DCDC converter) that boosts the output voltage of an auxiliary power source (lithium ion secondary battery) and a step-down (voltage regulator) that steps down the output of the booster and supplies it to a load. The power supply technology is described. Patent Document 5 describes a technology of a constant voltage power supply device including a step-up DCDC converter and a voltage regulator.

JP 2005-278111 A JP 2008-092779 A JP 2009-273249 A Japanese Patent Laid-Open No. 10-0333759 JP 2007-336795 A

  As described above, the voltage regulator has a disadvantage that power loss is large, and the DCDC converter has a disadvantage that a high-quality output voltage cannot be obtained due to the influence of ripple noise. In many cases, the configuration is a combination of a DCDC converter and a voltage regulator (hereinafter referred to as a combination type).

  However, in such a combination type, in order to optimize the input / output potential difference of the voltage regulator, the output voltage of the DCDC converter must be controlled in accordance with the output voltage of the voltage regulator, and the control becomes complicated. There is a point. Further, in the case of a variable output (programmable) voltage regulator, in addition to controlling the output voltage of the DCDC converter, it is necessary to control the output voltage of the voltage regulator, which further complicates the control. There is.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a power supply circuit that can optimize the input / output potential difference of a voltage regulator without requiring complicated control, and a control method therefor.

The power supply circuit according to the present invention includes a DCDC converter that boosts or steps down an output voltage of a battery, a voltage regulator that steps down the output voltage of the DCDC converter, and the DCDC converter according to a value correlated with the output voltage of the voltage regulator. Voltage setting means for setting a step-up value or a step-down value of the output voltage.
The method for controlling a power supply circuit according to the present invention is a method for controlling a power supply circuit comprising: a DCDC converter that boosts or steps down an output voltage of a battery; and a voltage regulator that steps down the output voltage of the DCDC converter, the voltage regulator And a voltage setting step for setting a step-up value or a step-down value of the output voltage of the DCDC converter according to a value correlated with the output voltage.

  ADVANTAGE OF THE INVENTION According to this invention, the power supply circuit which can optimize the input-output potential difference of a voltage regulator, and its control method can be provided, without requiring complicated control.

It is a block diagram of a basic power supply circuit. It is a figure which shows the flow of the voltage control in the basic type power supply circuit. 3 is a voltage output characteristic diagram of a basic power supply circuit 1. FIG. It is a block diagram of the power supply circuit which concerns on embodiment. It is a figure which shows the flow of the voltage control in the power supply circuit 100 which concerns on embodiment. It is a voltage output characteristic figure in power supply circuit 100 concerning an embodiment. FIG.

Embodiments of the present invention will be described below with reference to the drawings.
1. Basic power circuit:
First, before describing the embodiment, a basic power supply circuit to which the embodiment is not applied will be described. The basic power supply circuit refers to the above-mentioned problem, that is, a power supply circuit that needs to perform complicated control when optimizing the input / output potential difference of the voltage regulator.
FIG. 1 is a configuration diagram of a basic power supply circuit. In this figure, a power supply circuit 1 is connected in parallel to a battery 3 such as a lithium ion secondary battery having one end connected to the ground (GND) and the other end connected to a battery power supply line 2. A bypass capacitor 4, a step-up / step-down DCDC converter 5 for stepping up or stepping down the output voltage of the battery 3 (voltage between the battery power supply line 2 and GND; also referred to as terminal voltage) to an arbitrary voltage, A first phase compensation capacitor 6 connected between the output and GND; a voltage regulator 8 inserted between the output of the DCDC converter 5 and a load (arbitrary electronic circuit or the like) 7; and a voltage regulator 8 Of the second phase compensation capacitor 9 connected between the output of the first and second terminals, and the DCDC converter 5 and the voltage regulator 8. And a power supply controller 10 for controlling.

  It is assumed that the output voltage of the battery 3 is “Vbat”, the output voltage of the DCDC converter 5 (which is also the input voltage of the voltage regulator 8) is “Vddout”, and the output voltage of the voltage regulator 8 is “Vregout”.

<Configuration of DCDC converter 5>
The DCDC converter 5 monitors the four FETs 11 to 14, the coil 15, the DCDC controller 16 that controls on / off of the FETs 11 to 14, the switching oscillation circuit (OSC) 17, and Vddout and feeds back to the DCDC controller 16. The voltage dividing resistor ladder 18 and the voltage dividing resistor 19, a correction error amplifier 20, and a reference voltage generator 21 that generates a predetermined reference voltage Vr 1 are configured.

  As described above, the DCDC converter 5 having such a configuration boosts or steps down the terminal voltage of the battery 3, converts it to an arbitrary voltage (Vddout), and outputs it.

  The DCDC converter 5 operates in two modes, step-up and step-down. At the time of step-up, the FET 13 is turned on and off at the oscillation period of the oscillation circuit 17 while the FET 11 is turned on, and the current flowing through the coil 15 is chopped to produce a coil. The operation of obtaining a desired output voltage (Vddout) by storing current in 15 and discharging the current stored in the coil 15 to the first phase compensation capacitor 6 via the FET 14 is repeated. At this time, the FET 14 functions as a switch for returning the current of the coil 15 when the FET 13 is off, and the FET 14 and the FET 13 operate in opposite phases.

  On the other hand, at the time of step-down, the FET 11 is turned on and off at the oscillation cycle of the oscillation circuit 17, the current flowing through the coil 15 is chopped and the current is stored in the coil 15, and the current stored in the coil 15 is The operation of obtaining a desired output voltage (Vddout) by discharging to the capacitor 6 is repeated. At this time, the FET 12 functions as a switch for returning the current of the coil 15 when the FET 11 is off, and the FET 12 and the FET 11 operate in opposite phases.

  The DCDC controller 16 controls the output voltage (Vddout) of the DCDC converter 5 at the time of step-up or step-down according to the output voltage of the error amplifier 20, and the output voltage of the error amplifier 20 is applied to the DCDC controller 16. ing.

  The error amplifier 20 is composed of an operational amplifier, and a divided voltage Va of a resistance voltage dividing circuit composed of a voltage dividing resistor ladder 18 and a voltage dividing resistor 19 is applied to an inverting input (−input) of the operational amplifier (error amplifier 20). In addition, the reference voltage Vr1 generated by the reference voltage generator 21 is applied to the non-inverting input (+ input).

  In general, an operational amplifier outputs a value corresponding to the difference between an inverting input and a non-inverting input. Therefore, the DCDC controller 16 that controls the value of Vddout according to the output voltage of the operational amplifier (error amplifier 20) basically corresponds to the reference voltage Vr1. The value of Vddout is controlled so as to be a constant voltage.

  The divided voltage Va applied to the inverting input (−input) of the error amplifier 20 changes according to the value of the voltage dividing resistor ladder 18, and the value of the voltage dividing resistor ladder 18 increases or decreases according to the control of the power supply controller 10. It is a mechanism to do.

  Therefore, the DCDC converter 5 is a program-type constant voltage circuit that can arbitrarily change its output voltage (Vddout) in accordance with the control of the power supply controller 10, and boosts or steps down the voltage of the battery 3. This is a step-up / step-down constant voltage circuit that can

<Configuration of voltage regulator 8>
The voltage regulator 8 includes a driver FET 22, a voltage dividing resistor ladder 23 and a voltage dividing resistor 24 for monitoring the output voltage (Vregout) of the voltage regulator 8, an error amplifier 26, and a reference voltage for generating a reference voltage Vr 2. The generator 27 is configured to control the current (hereinafter referred to as iDS) flowing between the source and drain of the FET 22, thereby stepping down the output voltage (Vddout) of the DCDC converter 5 and a predetermined DC voltage (Vregout). To output.

  The iDS of the FET 22 changes according to the gate potential of the FET 22, and the gate potential of the FET 22 is given by the output voltage of the error amplifier 25.

  The error amplifier 25 is composed of an operational amplifier. A non-inverting input (+ input) of the operational amplifier (error amplifier 25) has a divided voltage of a resistance voltage dividing circuit including a voltage dividing resistor ladder 23 and a voltage dividing resistor 24. Vb is applied, and the reference voltage Vr2 generated by the reference voltage generator 26 is applied to the inverting input (-input).

  The divided voltage Vb applied to the non-inverting input (+ input) of the error amplifier 25 changes according to the value of the voltage dividing resistor ladder 23, and the value of the voltage dividing resistor ladder 23 increases or decreases according to the control of the power supply controller 10. It is a changing mechanism.

  Therefore, the voltage regulator 8 is a program-type constant voltage circuit that can arbitrarily change its output voltage (Vregout) according to the control of the power supply controller 10 and is set to a voltage (vregout) that does not exceed Vddout. This is a step-down constant voltage circuit that can be converted into a voltage.

  In the above example, the DCDC converter 5 is a step-up / step-down type, but may be a step-down type as long as it is always used below the terminal voltage of the battery 3, and in this case, the FET 13 is unnecessary.

  The voltage control in the basic power supply circuit 1 shown in FIG.

  FIG. 2 is a diagram illustrating a flow of voltage control in the basic power supply circuit 1. In this figure, the power supply controller 10 first sets the output voltage (Vddout) of the DCDC converter 5 (step S11) and the initial output voltage (Vregout) of the voltage regulator 8 (step S12). Next, the operations of the DCDC converter 5 and the voltage regulator 8 are turned on (steps S13 and S14).

  Then, it is determined whether or not the output voltage (Vregout) of the voltage regulator 8 is changed (step S15). If there is no change, step S15 is repeated as it is. If there is a change, next, the voltage regulator 8 The change direction (increase / decrease) of the output voltage (Vregout) is determined (step S16). Thereafter, control corresponding to the change direction is executed, and then the process returns to step S15 again.

<Control when raising>
When the change direction of the output voltage (Vregout) of the voltage regulator 8 is “increase”, setting for increasing the output voltage (Vddout) of the DCDC converter 5 (step S17; changing the value of the voltage dividing resistor ladder 18); Setting for increasing the output voltage (Vregout) of the voltage regulator 8 is performed (step S18; the value of the voltage dividing resistor ladder 23 is changed).

<Control when lowering>
When the change direction of the output voltage (Vregout) of the voltage regulator 8 is “decrease”, setting for reducing the output voltage (Vddout) of the DCDC converter 5 (step S19; changing the value of the voltage dividing resistor ladder 18); Setting for lowering the output voltage (Vregout) of the voltage regulator 8 is performed (step S20; the value of the voltage dividing resistor ladder 23 is changed).

  In such voltage control, the output voltage (Vddout) of the DCDC converter 5 is a voltage higher than the output voltage (Vregout) of the voltage regulator 8 plus the minimum input / output voltage difference (hereinafter referred to as Vsat) of the voltage regulator 8. If there is. In other words, “Vddout ≧ Vregout + Vsat” may be satisfied.

  FIG. 3 is a voltage output characteristic diagram of the basic power supply circuit 1. This figure shows a state in which the state is controlled to “Vddout ≧ Vregout + Vsat”. That is, it shows a state where control is performed so as to satisfy the above condition (Vddout ≧ Vregout + Vsat) both at the time of step-down and at the time of step-up. In the figure, ΔVa to ΔVe indicate the input / output potential difference of the voltage regulator 8, that is, Vregout + Vsat. Although it is desirable that ΔVa to ΔVe be always constant, for that purpose, more precise control is required, which causes a drawback that the control is complicated. On the other hand, if the control is simplified, the input / output potential difference (ΔVa to ΔVd) is not fixed this time, and depending on the location, it may become larger than necessary.

  For example, in this figure, the operation of decreasing Vregout (step-down operation) is performed at time t0 and time t2, respectively, and the operation of increasing Vregout (step-up operation) is performed at time t5. Since the step-up operation and the step-down operation each have a predetermined response delay, the step-down operation started at time t0 is completed at time t1, and the step-down operation started at time t2 is completed at time t3. The step-up operation started at t5 is completed at time t6.

  The target voltages of Vregout in the step-down operation are all smaller than Vddout. Accordingly, during the step-down operation, Vddout is not controlled and Vddout maintains a constant value. Therefore, the input / output potential difference of the voltage regulator 8 is given by the potential difference between Vddout and Vregout. Specifically, the input / output potential difference from time t0 to time t0 is given by ΔVa, the input / output potential difference from time t1 to time t2 is given by ΔVb, and the input / output potential difference from time t3 to time t4 is given by ΔVc.

  Here, since Vddout during the step-down operation maintains a constant value as described above, these input / output potential differences (ΔVa, ΔVb, ΔVc) inevitably become unequal values (ΔVa <ΔVb <ΔVc). As described at the beginning, the voltage regulator 8 generates Joule heat corresponding to the input / output potential difference and causes a loss due to the heat. As a result, the basic power supply circuit 1 eventually has the input / output potential difference (ΔVa, A loss corresponding to an unequal value (ΔVa <ΔVb <ΔVc) of ΔVb, ΔVc) occurs. A characteristic line indicated by a one-dot chain line in the figure indicates the loss. That is, with respect to the loss up to time t0, the loss increases at time t0 to t2, and further, the loss further increases at time t2 to t4. The loss at times t0 to t2 corresponds to ΔVa <ΔVb, and the loss at times t2 to t4 corresponds to ΔVb <ΔVc.

  Further, the loss increases at the start of the boost operation. That is, in the example shown in the figure, boosting of Vregout is started at time t5, but it is necessary to start boosting Vddout in advance at time t4 in consideration of the response delay of Vddout. This is because the input / output potential difference Vd of the voltage regulator 8 temporarily increases due to the pre-boost. When the boosting operation is completed at time t6, the loss during the boosting operation falls within a small value corresponding to the input / output potential difference ΔVe at that time.

  As described above, the basic power supply circuit 1 has a disadvantage that the loss increases with the step-down operation or step-up operation of Vregout. This inconvenience can be solved by changing Vddout in accordance with the change of Vregout (particularly step-down). However, such a solution causes an inconvenience that the control is complicated. This is because it is necessary to change the Vddout, that is, to set the value of the voltage dividing resistor ladder 18 according to a command from the power supply controller 10, and the control in the power supply controller 10 becomes complicated.

Hereinafter, an embodiment intended to solve such inconvenience (increased loss and complication of control) will be described.
2. Power circuit of embodiment:
In the embodiment, the basic power supply circuit is improved in order to reduce loss and avoid complicated control.
FIG. 4 is a configuration diagram of a power supply circuit according to the embodiment. In FIG. 4 (FIG. 4), the same reference numerals are given to components common to the basic power supply circuit 1 (see FIG. 1).
The power supply circuit 100 according to the embodiment is common to the basic power supply circuit 1 in many respects, but there are structural differences in the following points.

[First difference]
Instead of the reference voltage generator 21 that generates the constant reference voltage Vr1, a reference voltage Vr1 that dynamically changes its value according to a value (here, Vb) correlated with the output voltage (Vregout) of the voltage regulator 80 is used. The point which provided the reference voltage generation part 210 to generate | occur | produce.

[Second difference]
An offset generator that generates an offset voltage Vofst that is optimally set so that the output voltage (Vddout) of the DCDC converter 50 is higher than the output voltage (Vregout) of the voltage regulator 80 by the input / output potential difference (Vsat) of the voltage regulator 80. 101 is newly provided.

[Third difference]
Instead of the error amplifier 20 composed of a two-input type operational amplifier, an error amplifier 200 composed of a three-input type operational amplifier is provided, Va is added to the inverting input (−input), and the first non-inverting input is provided. Vr1 is added to (+ input), and Vofst is added to the second non-inverting input (+ input).

  With the above first to third differences, the power supply circuit 100 according to the embodiment can exhibit a specific effect that loss can be reduced without requiring complicated voltage control.

This will be described in detail below.
FIG. 5 is a diagram illustrating a flow of voltage control in the power supply circuit 100 according to the embodiment. In this figure, step S11 to step S15 are common to the same step number in the voltage control flow (see FIG. 2) in the previous basic type power supply circuit 1, and the difference is the previous voltage control flow (see FIG. 2). However, step S21 is provided instead of steps S16 to S20.

  That is, in the previous voltage control flow (see FIG. 2), the change direction (increase / decrease) of the output voltage (Vregout) of the voltage regulator 8 is determined (step S16), and the control when increasing according to the determination result (step S17 and step S18) and the complicated control of performing the lowering control (step S19 and step S20) are performed. However, the power supply circuit 100 according to the embodiment needs to perform such complicated control. The difference is that a simple operation (step S21) is performed in which the output voltage (Vddout) of the DCDC converter 50 is automatically set by following the change of the output voltage (Vregout) of the voltage regulator 80.

  This is because the above-described structural differences (first difference to third difference) are present, and in particular, a value (here, a value correlated with the output voltage (Vregout) of the voltage regulator 80). Vb) is provided with a reference voltage generator 210 that generates a reference voltage Vr1 that dynamically changes its value, and the output voltage (Vddout) of the DCDC converter 50 is higher than the output voltage (Vregout) of the voltage regulator 80. The offset generator 101 for generating the offset voltage Vofst optimally set so as to be higher than the input / output potential difference (Vsat) of the voltage regulator 80 is newly provided, and the inversion of the error amplifier 200 composed of a three-input type operational amplifier. Va is applied to the input (−input), and Vr is applied to the first non-inverting input (+ input). This is because Vofst is added to the second non-inverting input (+ input), so that the DCDC converter 50 is caused to follow the operation of step S21, that is, the change of the output voltage (Vregout) of the voltage regulator 80. This is because a simple operation of automatically setting the output voltage (Vddout) is performed.

  As described above, in the power supply circuit 100 according to the embodiment, the output voltage (Vregout) of the voltage regulator 80 can be monitored on the DCDC converter 50 side, and the output voltage (Vregout) of the voltage regulator 80 is used as a reference. Since feedback is applied to the output voltage (Vddout), that is, the input voltage of the voltage regulator 80, when the output voltage of the voltage regulator 80 is changed, the change is made regardless of the rise or fall of the voltage. Since the feedback voltage is fed back to the DCDC converter 50 and the output voltage of the DCDC converter 50 (that is, the input voltage of the voltage regulator 80) is automatically set to follow, the control of the power supply controller 10 can be simplified. Effect can be obtained.

  Further, the second effect that the input / output potential difference of the voltage regulator 80 can always be made constant regardless of the change of the output voltage of the voltage regulator 80, and the loss (heat loss) can be minimized. .

The second effect will be described.
FIG. 6 is a voltage output characteristic diagram of the power supply circuit 100 according to the embodiment. Time t0 and time t2 are Vregout step-down operation start points, time t4 is a Vregout step-up operation start point, and time t1, time t3, and time t5 are respective operation completion points. As shown in this figure, in the power supply circuit 100 of the embodiment, the value of Vddout changes in the same direction and by the same amount following the step-down or step-up operation of Vregout. That is, Vregout is stepped down from time t0 to t1, but at this time, Vddout also changes in the same direction and by the same amount. Similarly, Vregout is further stepped down from time t2 to time t3. At this time, Vddout also changes in the same direction and by the same amount. Similarly, Vregout is boosted from time t4 to time t5. At this time, Vddout also changes in the same direction and by the same amount.

  Accordingly, at any location, the difference between Vregout and Vddout, that is, the input / output potential difference ΔV of the voltage regulator 80 is “constant”, and this input / output potential difference ΔV corresponds to a loss. Regardless of the change, the input / output potential difference of the voltage regulator 80 can always be maintained constant, and loss (heat loss) can be minimized. In addition, such “constant” of the input / output potential difference ΔV is not performed under the control of the power supply controller 10, but is automatically performed following the value (Vb) correlated with Vregout. There is no inconvenience.

Since it is as above, according to the power supply circuit 100 which concerns on embodiment, there can exist the following effects.
(1) The output voltage of the DCDC converter 50, that is, the input voltage of the voltage regulator 80 can be automatically followed with respect to the output voltage of the voltage regulator 80, and the output voltage of the voltage regulator 80 and the output voltage of the DCDC converter 50, respectively. Therefore, the burden on the voltage controller 10 can be reduced.
(2) The input voltage of the voltage regulator 80 (the output voltage of the DCDC converter 50) can be automatically optimized with respect to the output voltage of the voltage regulator 80, and the loss can be minimized.
(3) Since the output voltage of the DCDC converter 50 can be automatically set to follow the output voltage of the voltage regulator 80, it is not necessary to control the output voltage of the DCDC converter 50, and the control burden on the power supply controller 10 can be reduced.

  The application field of the power supply circuit 100 according to the embodiment is not particularly limited. For example, a portable electronic device such as a mobile phone may be used, but in short, any electronic device that operates on a battery is applicable.

The features of the present invention will be described below.
A part or all of the above-described embodiment can be described as in the following supplementary notes, but is not limited thereto.
(Appendix 1)
FIG. 7 is a configuration diagram of Supplementary Note 1.
Appendix 1
A DCDC converter 301 (corresponding to the DCDC converter 50 of the embodiment) for boosting or lowering the output voltage of the battery 300 (corresponding to the battery 3 of the embodiment);
A voltage regulator 302 (corresponding to the voltage regulator 80 of the embodiment) for stepping down the output voltage of the DCDC converter 301;
Voltage setting means 303 (a reference voltage generation unit 210, an offset generation unit 101, an error in the embodiment) that sets a step-up value or a step-down value of the output voltage of the DCDC converter 301 in accordance with a value correlated with the output voltage of the voltage regulator 302 And a power supply circuit 304 (corresponding to the power supply circuit 100 of the embodiment).

(Appendix 2)
Appendix 2
The voltage setting means generates a reference voltage that dynamically changes its value according to a value correlated with the output voltage of the voltage regulator, and the output voltage of the DCDC converter is higher than the output voltage of the voltage regulator. The offset voltage set to be higher than the input / output potential difference of the voltage regulator is generated, and the output voltage of the DCDC converter is boosted or lowered based on the reference voltage and the offset voltage. It is a power supply circuit as described in.

(Appendix 3)
Appendix 3
A method for controlling a power supply circuit comprising: a DCDC converter that boosts or steps down an output voltage of a battery; and a voltage regulator that steps down the output voltage of the DCDC converter,
A method for controlling a power supply circuit, comprising: a voltage setting step for setting a step-up value or a step-down value of an output voltage of the DCDC converter according to a value correlated with an output voltage of the voltage regulator.

300 battery 300
301 DCDC converter 302 Voltage regulator 303 Voltage setting means 304 Power supply circuit

Claims (3)

A DCDC converter that boosts or steps down the output voltage of the battery;
A voltage regulator for stepping down the output voltage of the DCDC converter;
A power supply circuit comprising: voltage setting means for setting a step-up value or a step-down value of the output voltage of the DCDC converter according to a value correlated with the output voltage of the voltage regulator.   The voltage setting means generates a reference voltage that dynamically changes its value according to a value correlated with the output voltage of the voltage regulator, and the output voltage of the DCDC converter is higher than the output voltage of the voltage regulator. The offset voltage set to be higher than the input / output potential difference of the voltage regulator is generated, and the output voltage of the DCDC converter is boosted or lowered based on the reference voltage and the offset voltage. The power supply circuit according to 1. A method for controlling a power supply circuit comprising: a DCDC converter that boosts or steps down an output voltage of a battery; and a voltage regulator that steps down the output voltage of the DCDC converter,
A method for controlling a power supply circuit, comprising: a voltage setting step of setting a boost value or a step-down value of an output voltage of the DCDC converter according to a value correlated with an output voltage of the voltage regulator.

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