JP6769717B2 - Voltage drop compensation circuit, switching power supply, voltage drop compensation method, and switching power supply control method - Google Patents

Description

The present invention relates to a voltage drop compensation circuit, a switching power supply device, a voltage drop compensation method, and a switching power supply control method.

An example of a technique relating to a switching power supply device is described in Patent Document 1. This technology has a first control loop that monitors and stabilizes the output voltage of the output terminal of the switching power supply, and a second control loop that monitors the voltage near the power supply terminal of the load connected to the output terminal. And have.

Japanese Unexamined Patent Publication No. 2003-289664

In the second control loop of Patent Document 1, since the path to the switching power supply device and the load is long, there is a high possibility that various disturbances such as electromagnetic noise and crosstalk enter. As a result, the disturbance from the second control loop is fed back, and there is a problem that the power supply signal (DC component) lowered by the path to the load cannot be accurately extracted.

An object of the present invention is to provide a voltage drop compensation circuit, a switching power supply device, a voltage drop compensation method, and a switching power supply control method that solve the above problems.

The voltage drop compensation circuit of the present invention includes an AC coupling capacitor that removes the DC component of the first input signal and outputs the AC component, and an RC filter that removes the AC component of the second input signal and outputs the DC component. , The output of the AC coupling capacitor, and the voltage follower that inputs the coupling of the output of the RC filter, lowers the impedance, and outputs it as a signal for feedback.

In the voltage drop compensation method of the present invention, the AC coupling capacitor removes the DC component of the first input signal and outputs the AC component, and the RC filter removes the AC component of the second input signal to remove the DC component. The voltage follower inputs the output of the AC coupling capacitor and the coupling of the output of the RC filter to lower the impedance and outputs it as a signal for feedback.

The effect of the present invention is that the AC component can be removed from the power supply signal lowered by the path from the DCDC converter to the load end, the DC component can be extracted, and the voltage drop can be compensated.

It is a block diagram which shows the structure of the 1st Embodiment of this invention. It is a block diagram which shows the structure of the 2nd Embodiment of this invention.

Next, the first embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram showing a configuration of the first embodiment. Referring to FIG. 1, the voltage drop compensation circuit 100 includes an AC coupling capacitor 110, an RC filter 120, and a voltage follower 130. Here, AC is Alternating Current (that is, alternating current). The RC is a Resistor Capacitor (ie, a resistor, a capacitor).

The outlet of the output signal from the voltage drop compensation circuit 100 (that is, the output signal from the voltage follower 130) is called the output end 151.

The entrance of the input signal to the AC coupling capacitor 110, which is the input signal to the voltage drop compensation circuit 100, is called the input end 161. Further, the entrance of the input signal to the RC filter 120, which is the input signal to the voltage drop compensation circuit 100, is called an input end 162.

Next, the operation of the first embodiment will be described with reference to the drawings.

The AC coupling capacitor 110 removes the DC (direct current) component of the input signal from the input terminal 161 and allows the AC component to pass through. The RC filter 120 is composed of, for example, a resistor and a capacitor, removes the AC component of the input signal from the input terminal 162, and passes the DC component. The output of the AC coupling capacitor 110 and the output of the RC filter 120 are coupled. As a result of the coupling, the voltages of both outputs are superposed and input to the positive terminals of the voltage follower 130.

The voltage follower 130 is composed of, for example, an operational amplifier, and forms a negative feedback circuit that inputs its own output to a negative terminal. Then, since the impedance is increased by the AC coupling capacitor 110 and the RC filter 120, the voltage follower 130 lowers the impedance.

A configuration (local sensing) is possible in which a power supply signal from an output terminal (including a vicinity) of a DCDC converter circuit (not shown) is input to the input terminal 161. Further, the input terminal 162 can be configured to input the power supply signal from the load end (including the vicinity) of the load (not shown) for inputting the power supply signal from the DCDC converter circuit (remote sensing).

Then, the output signal from the output terminal 151 can be supplied to the feedback input terminal of the DCDC converter circuit.

Next, the effect of the first embodiment will be described.

In the first embodiment, when the remote sensing configuration described above is adopted, the AC component can be removed from the power supply signal lowered by the path from the DCDC converter to the load end, the DC component can be extracted, and the voltage drop can be compensated. It has the first effect.

Further, the first embodiment has both the advantages of local sensing (stability) and the advantages of remote sensing (voltage drop compensation) by adopting both the above-mentioned local sensing and remote sensing configurations. It has the second effect of preparing.

Next, a second embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 2 is a block diagram showing the configuration of the second embodiment. Referring to FIG. 2, the switching power supply 500 includes a DCDC converter circuit 200 and a voltage drop compensation circuit 100 of the first embodiment.

The DCDC converter circuit 200 includes a PWM control circuit 210, a switching circuit 221, a switching circuit 222, a smoothing circuit 230, and a noise removing circuit 240. PWM is Pulse Width Modulation, that is, pulse width modulation. The switching circuits 221 and 222 are composed of FETs (Field Effect Transistors) and the like.

The entrance of the feedback signal of the PWM control circuit 210 (that is, equivalent to the entrance of the feedback signal of the DCDC converter circuit 200) is called an input terminal 211. The source power supply signal Vin is input to the switching circuit 221 via the noise reduction circuit 240 that removes power supply noise.

The outlet (including the vicinity) of the power supply signal (that is, the power supply signal from the smoothing circuit 230) from the switching power supply 500 (that is, from the DCDC converter circuit 200) is called the output end 501.

The power supply signal from the output terminal 501 is input to the load 800. The inlet (including the vicinity) of the power signal of the load 800 is called the load end 801. The power supply signal from the output terminal 501 is input to the voltage drop compensation circuit 100 from the input terminal 161. The power supply signal from the load end 801 is input to the voltage drop compensation circuit 100 from the input end 162.

The feedback signal from the output terminal 151 of the voltage drop compensation circuit 100 is input to the PWM control circuit 210 from the input terminal 211.

Next, the operation of the second embodiment will be described with reference to the drawings.

The PWM control circuit 210 compares the voltage of the feedback signal from the input terminal 211 with a reference voltage (not shown). When the voltage of the feedback signal is lower than the reference voltage, the PWM control circuit 210 outputs the control signal 251 so as to prolong the time for turning on the switching circuit 221.

When the voltage of the feedback signal is higher than the reference voltage, the PWM control circuit 210 outputs the control signal 252 so as to prolong the time for turning on the switching circuit 222. Further, the PWM control circuit 210 does not turn on the switching circuit 221 and the switching circuit 222 at the same time.

When the switching circuit 221 is on, the noise-removed source power supply Vin is output to the source terminal. When the switching circuit 222 is on, the drain terminal is pulled into the ground. The source terminal of the switching circuit 221 and the drain terminal of the switching circuit 222 are connected to generate a pulse, which is input to the smoothing circuit 230.

That is, when the voltage of the feedback signal is lower than the reference voltage, the duty of the pulse is controlled to increase, and when the voltage of the feedback signal is higher than the reference voltage, the duty of the pulse is controlled to decrease. Then, the smoothing circuit 230 smoothes the pulse and outputs it as a power supply signal to the output terminal 501.

That is, the DCDC converter circuit 200 adjusts the power supply signal higher when the voltage of the feedback signal is lower than the reference voltage, and adjusts the power supply signal lower when the voltage of the feedback signal is higher than the reference voltage.

At the output terminal 501, a ripple wave that reciprocates in the vicinity of an appropriate voltage is generated. The AC coupling capacitor 110 of the voltage drop compensation circuit 100 can extract only the AC component of this ripple wave.

On the other hand, there is a high possibility that the voltage drops at the load end 801 and a waveform mixed with various disturbances (AC components) such as electromagnetic noise and crosstalk appears. The RC filter 120 of the voltage drop compensation circuit 100 can remove this disturbance (AC component) and take out only the DC component.

As described above, the voltage drop compensation circuit 100 can output an excellent feedback signal to the PWM control circuit 210 of the DCDC converter circuit 200.

Next, the effect of the second embodiment will be described.

Since the second embodiment includes the voltage drop compensation circuit 100 of the first embodiment, it has the same effect as that of the first embodiment.

Some or all of the above embodiments may also be described, but not limited to:

[Appendix 1]
An AC coupling capacitor that removes the DC component of the first input signal and outputs the AC component,
An RC filter that removes the AC component of the second input signal and outputs the DC component,
A voltage follower that inputs the output of the AC coupling capacitor and the output of the RC filter, lowers the impedance, and outputs it as a feedback signal.
A voltage drop compensation circuit characterized by including.

[Appendix 2]
With the voltage drop compensation circuit
When the feedback signal from the voltage drop compensation circuit is input and the voltage of the feedback signal is lower than the reference voltage, the power supply signal is adjusted to be higher, and the voltage of the feedback signal is higher than the reference voltage. And a DCDC converter circuit that adjusts the power supply signal to a low voltage and outputs it.
A switching power supply characterized by including.

[Appendix 3]
The voltage drop compensation circuit is
The switching power supply according to Appendix 2, wherein the power supply signal from the output end of the DCDC converter circuit is input as the first input signal, and the power supply signal from the load end is input as the second input signal. apparatus.

[Appendix 4]
A PWM control circuit that inputs the feedback signal and outputs a control signal,
Two switching circuits that generate pulses according to the control signal,
A smoothing circuit that inputs the pulse, smoothes it, and outputs it as the power supply signal.
The switching power supply device according to Appendix 3, which comprises the above.

[Appendix 5]
The PWM control circuit
When the voltage of the feedback signal is lower than the reference voltage, the control signal is output so as to increase the duty of the pulse, and when the voltage of the feedback signal is higher than the reference voltage, the duty of the pulse is lowered. The switching power supply device according to Appendix 4, wherein the control signal is output as described above.

[Appendix 6]
The AC coupling capacitor removes the DC component of the first input signal and outputs the AC component.
The RC filter removes the AC component of the second input signal and outputs the DC component.
A voltage drop compensation method, wherein the voltage follower inputs a coupling of the output of the AC coupling capacitor and the output of the RC filter, lowers the impedance, and outputs the signal as a feedback signal.

[Appendix 7]
The DCDC converter circuit inputs the feedback signal generated by the voltage drop compensation method of Appendix 6, and when the voltage of the feedback signal is lower than the reference voltage, the power supply signal is adjusted higher and the feedback signal is adjusted. A switching power supply control method, characterized in that when the voltage of the above is higher than the reference voltage, the power supply signal is adjusted to be lower and output.

[Appendix 8]
The switching power supply according to Appendix 7, wherein the power supply signal from the output end of the DCDC converter circuit is input as the first input signal, and the power supply signal from the load end is input as the second input signal. Control method.

[Appendix 9]
The PWM control circuit inputs the feedback signal and outputs the control signal.
The two switching circuits generate pulses according to the control signal,
The switching power supply control method according to Appendix 8, wherein the smoothing circuit inputs the pulse, smoothes it, and outputs it as the power supply signal.

[Appendix 10]
The PWM control circuit
When the voltage of the feedback signal is lower than the reference voltage, the control signal is output so as to increase the duty of the pulse, and when the voltage of the feedback signal is higher than the reference voltage, the duty of the pulse is lowered. The switching power supply control method according to Appendix 9, wherein the control signal is output as described above.

100 Voltage drop compensation circuit 110 AC coupling capacitor 120 RC filter 130 Voltage follower 151 Output end 161 Input end 162 Input end 200 DCDC converter circuit 210 PWM control circuit 211 Input end 221 Switching circuit 222 Switching circuit 230 Smoothing circuit 251 Control signal 252 Control Signal 500 Switching power supply 501 Output end 800 Load 801 Load end

Claims (10)

An AC coupling capacitor that removes the DC component of the first input signal and outputs the AC component,
An RC filter that removes the AC component of the second input signal and outputs the DC component,
A voltage follower that inputs the output of the AC coupling capacitor and the output of the RC filter, lowers the impedance, and outputs it as a feedback signal.
Only including,
The first input signal is the power supply signal at the output end, which is a portion where the switching power supply device outputs the power supply signal.
The voltage drop compensation circuit is characterized in that the second input signal is the power supply signal at the load end where the power supply signal is input to the load . The voltage drop compensation circuit according to claim 1 and
Inputs the signal for the feedback from the voltage drop compensation circuit, the direction of the voltage of the signal for the feedback is lower than the reference voltage, the higher adjust the power signal at the output terminal, the signal for the feedback When the voltage is higher than the reference voltage, the DCDC converter circuit that adjusts the power supply signal at the output end to a lower value and outputs it.
A switching power supply characterized by including. The voltage drop compensation circuit is
The switching power supply device according to claim 2, wherein the power supply signal from the output terminal is input as the first input signal, and the power supply signal from the load end is input as the second input signal. A PWM control circuit for outputting a control signal inputs the signal for the feedback,
Two switching circuits that generate pulses according to the control signal,
A smoothing circuit that inputs the pulse, smoothes it, and outputs it as the power supply signal.
3. The switching power supply device according to claim 3. The PWM control circuit
When towards the voltage of the signal for the feedback is lower than the reference voltage, and outputs the control signal to raise the duty cycle of the pulse, the direction of the voltage of the signal for the feedback is higher than the reference voltage, the The switching power supply device according to claim 4, wherein the control signal is output so as to reduce the duty of the pulse. The AC coupling capacitor removes the DC component of the first input signal and outputs the AC component.
The RC filter removes the AC component of the second input signal and outputs the DC component.
The voltage follower inputs the coupling of the output of the AC coupling capacitor and the output of the RC filter, lowers the impedance, and outputs it as a feedback signal .
The first input signal is the power supply signal at the output end, which is a portion where the switching power supply device outputs the power supply signal.
The voltage drop compensation method, wherein the second input signal is the power supply signal at the load end where the power supply signal is input to the load . DCDC converter circuit, and inputs the signal for the feedback the generated by the voltage drop compensation method of claim 6, the direction of the voltage of the signal for the feedback is lower than the reference voltage, the power supply signal at the output terminal the high adjusted, the direction of the voltage of the signal for the feedback is higher than the reference voltage, the switching power supply control method and outputs the power signal to adjust to low at the output end. The switching power supply control method according to claim 7, wherein the power supply signal from the output terminal is input as the first input signal, and the power supply signal from the load end is input as the second input signal. PWM control circuit inputs the signal for the feedback outputs a control signal,
The two switching circuits generate pulses according to the control signal,
The switching power supply control method according to claim 8, wherein the smoothing circuit inputs the pulse, smoothes it, and outputs it as the power supply signal. The PWM control circuit
When towards the voltage of the signal for the feedback is lower than the reference voltage, and outputs the control signal to raise the duty cycle of the pulse, the direction of the voltage of the signal for the feedback is higher than the reference voltage, the The switching power supply control method according to claim 9, wherein the control signal is output so as to reduce the duty of the pulse.