JPH09266664A - Current mode control dc/dc converter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To keep an excellent S/N ratio and avoid the deterioration of control characteristics, by a method wherein a current gain is switched at the time of a light load and, when the current gain is increased, a phase compensation resistor is switched to increase the resistance value. SOLUTION: In a current mode control DC/DC converter, a reactor current is fed back to a current mode control circuit 4 through a light load current gain 17 and a light load time current gain is increased to keep an excellent S/N ratio at the time of a light load. Also, at the time of a light load, a voltage gain changeover switch 15 is connected to a 2nd phase compensation resistor 14 and the decline of a control band when a current gain 13 is switched to the light load current gain 17 and a current gain is increased is avoided and, further, the decline of the frequency at the point where the open loop characteristic curve of the current mode control DC/DC converter is not continuous is avoided.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a current mode control DC / DC converter.

[0002]

2. Description of the Related Art FIG. 11 shows an example of a conventional current mode control DC / DC converter.
In the figure, 1 is a switching regulator, 2 is a load,
3 is a reactor current detection circuit, 4 is a current mode control control circuit, 5 is a voltage input terminal, 6 is an error amplifier, 7 is a first voltage detection resistor, 8 is a second voltage detection resistor, 9 is a reference voltage source, Reference numeral 10 is a first phase compensation capacitor, 11 is a first phase compensation resistor, 12 is a voltage compensation circuit, and 13 is a current gain.

In the figure, the electric power supplied from the voltage input terminal 5 is converted into electric power by the switching regulator 1, the output end of the switching regulator 1 is connected to the load 2, and the electric power is supplied to the load 2. At this time, the reactor current inside the switching regulator 1 is detected by the reactor current detection circuit 3, and the current feedback signal obtained via the current gain 13 and the output voltage of the switching regulator 1 are used as the first voltage detection resistor 7 and the second voltage. Detected by the detection resistor 8, the first voltage detection resistor 7, the second voltage detection resistor 8, the error amplifier 6, the reference voltage source 9, the first phase compensation capacitor 10, the first phase compensation resistor 11 The phase-compensated voltage feedback signal obtained by the voltage compensation circuit 12 is fed back to the current mode control control circuit 4, and the current mode control control circuit 4 controls the output voltage of the switching regulator 1.

[0004]

The open loop gain characteristic T of the current mode control DC / DC converter becomes the characteristic shown in FIG. 8 and is given by "Equation 1". In addition,
In the equation 1, R1, RL, and C1 are the first phase compensation resistor 11, the load 2, and the first phase compensation capacitor 10, respectively.
Is the resistance value and the capacitance of the capacitor.

[0005]

[Equation 1]

Current mode control DC / D
The control band ωvc of the C converter is given by “Equation 2”. Note that a is the magnitude of the current gain, and R2 is the resistance value of the first voltage detection resistor 7.

[0007]

[Equation 2]

Here, the current mode control DC /
When the DC converter has a light load, the breakpoint frequency 1 / T1 in FIG. 8 is inversely proportional to the resistance value of the load, so the breakpoint frequency 1 / T1 becomes low, and finally the breakpoint frequency 1 in FIG.
/ T3, and as shown in FIG. 9, the open loop gain characteristic T is − between the break point frequencies 1 / T1 and 1 / T3.
Since it has a slope of 40 dB, it becomes difficult to obtain system stability. The current mode control DC / DC converter is a DC / D that controls the peak value of the reactor current.
Since it is a C converter, the peak value of the current feedback signal decreases at a light load as shown in FIG. 10, while the amplitude of the turn-on noise does not decrease.
Since the ratio becomes worse and a malfunction tends to occur, it is necessary to switch the current gain to a large value and maintain a good S / N ratio when feeding back the reactor current at a light load.
Since the control band ωvc of the current mode control DC / DC converter is inversely proportional to the current gain when the current gain changes, the control band ωvc decreases as the current gain increases. Therefore, the current mode control tends to impair the stability of the control system when the load is light,
There is also a problem that the control band is lowered.

The present invention switches the current gain during a light load to maintain a good S / N ratio, and compensates for either or both of the stability that is impaired during a light load and the control band that decreases when the voltage compensation circuit is switched. However, it is intended to prevent the deterioration of the control characteristics of the current mode control DC / DC converter.

[0010]

In the current mode control DC / DC converter according to the first invention, the current gain is switched by the current gain switching circuit at light load, and the phase compensation resistor of the error amplifier in the voltage compensation circuit is used. When the current gain is switched and becomes large, by increasing the switching resistance value using a switch,
By increasing T3 in "Equation 1" and setting 1 / T3 to a frequency lower than 1 / T1 which decreases, the control band ωvc that decreases from "Equation 2" is kept constant.

In the current mode control DC / DC converter according to the second aspect of the present invention, the current gain is switched by the current gain switching circuit at light load, and
When the current gain of the phase compensating capacitor of the error compensating amplifier in the voltage compensating circuit is switched and becomes large, a switch is used to increase the capacity of the switching capacitor, thereby increasing and decreasing T3 in "Equation 1". Set 1 / T3 to the frequency below / T1.

In the current mode control DC / DC converter according to the third aspect of the present invention, the current gain is switched by the current gain switching circuit at light load, and the current of the phase compensation resistor and the phase compensation capacitor of the error amplifier in the voltage compensation circuit is switched. When the gain is switched and becomes large, it is switched using a switch, and T3 in "Equation 1" is increased and reduced. 1 / T3 is set to a frequency not higher than 1 / T1 and control is performed to lower than "Equation 2". The resistance value and the capacitance of the capacitor are set so that the band ωvc is kept constant.

In the current mode control DC / DC converter according to the fourth aspect of the present invention, the current gain is switched by the light load current gain switching circuit, and
When the current gain is switched and the voltage detection resistance in the voltage compensation circuit becomes large, it is switched using a switch, and the resistance value is set so as to keep the control band ωvc lower than “Equation 2” constant.

In the current mode control DC / DC converter according to the fifth aspect of the present invention, the current gain is switched by the light load current gain switching circuit, and the voltage detection resistor, the phase compensation resistor and the phase compensation capacitor in the voltage compensation circuit are used. When the current gain is switched and becomes large, it is switched using a switch to increase T3 in "Equation 1" and set 1 / T3 to a frequency of 1 / T1 or lower, which decreases from "Equation 2". Control band ωvc
Set the resistance value and the capacitance of the capacitor so that is kept constant.

In the current mode control DC / DC converter according to the sixth aspect of the present invention, the current gain is switched by the light load current gain switching circuit, and
The voltage detection resistor and the phase compensation resistor in the voltage compensation circuit are switched using a switch when the current gain is switched and becomes large, and T3 in "Equation 1" is increased and decreased.
While setting 1 / T3 to the frequency below / T1,
The resistance value is set so as to keep the control band ωvc that is lower than “Equation 2” constant.

In the current mode control DC / DC converter according to the seventh aspect of the present invention, the current gain is switched by the current gain switching circuit at light load, and
The voltage detection resistor and the phase compensation capacitor in the voltage compensation circuit are switched by using a switch when the current gain is switched and becomes large, and T3 in "Equation 1" is increased to a frequency of 1 / T1 or less that decreases 1 / T3 is set, and the resistance value and the capacitance of the capacitor are set so as to keep the control band ωvc that is lower than "Equation 2" constant.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1. 1 is a schematic diagram showing a first embodiment of the present invention, in which 14 is a second phase compensation resistor,
Reference numeral 15 is a first voltage gain changeover switch, 16 is a current gain changeover circuit, 17 is a light load current gain, and 1 to 13 are as shown in FIG. The magnitude of the light load current gain 17 is set to be larger than that of the current gain 13, and the resistance value of the second phase compensation resistor 14 is set to be larger than that of the first phase compensation resistor 11.

Current mode control D shown in FIG.
The C / DC converter feeds the reactor current back to the current mode control control circuit 4 via the current gain 13 at the time of normal load by the current gain switching circuit 16, and at the time of light load, the current gain 1 for light load.
The reactor current is fed back to the current mode control control circuit 4 via 7 to increase the current gain at light load to maintain a good S / N ratio. Further, when the load is normal, the first voltage gain changeover switch 15
Is connected to the first phase compensation resistor 11, the voltage gain switching switch 15 is connected to the second phase compensation resistor 14 when the load is light, and the current gain 13 is switched to the light load current gain 17 when the load is light. When it is changed, the current gain becomes large, and the control band ωvc is prevented from being lowered from the "equation 2", and the open loop of the current mode control DC / DC converter is obtained from the "equation 1" at the time of the light load, from FIG. 8 and FIG. The break point frequency 1 / T1 of the gain characteristic T is prevented from decreasing and becoming lower than the break point frequency 1 / T3.

Embodiment 2. 2 is a schematic diagram showing a second embodiment of the present invention, in which 15 is a first voltage gain changeover switch, 16 is a current gain changeover circuit, 17 is a light load current gain, and 18 is a second phase. Compensation capacitors 1 to 13 are as shown in FIG. The magnitude of the light load current gain 17 is set to be larger than that of the current gain 13, and the capacitor capacity of the second phase compensation capacitor 18 is set to be larger than that of the first phase compensation capacitor 10.

The current mode control D shown in FIG.
The C / DC converter feeds the reactor current back to the current mode control control circuit 4 via the current gain 13 at the time of normal load by the current gain switching circuit 16, and at the time of light load, the current gain 1 for light load.
The reactor current is fed back to the current mode control control circuit 4 via 7 to increase the current gain at light load to maintain a good S / N ratio. Further, when the load is normal, the first voltage gain changeover switch 15
Is connected to the first phase compensating capacitor 10, the voltage gain changeover switch 15 is connected to the second phase compensating capacitor 18 at the time of a light load, and when the light load is "Equation 1", the current from FIG. 8 and FIG. It is prevented that the break point frequency 1 / T1 of the open loop gain characteristic T of the mode control DC / DC converter is lowered and the break point frequency 1 / T3 is lowered.

Embodiment 3 3 is a schematic diagram showing a third embodiment of the present invention, in which 15 is a first voltage gain changeover switch, 16 is a current gain changeover circuit, 17 is a light load current gain, and 19 is a third phase. Compensation capacitor, 20 is a third phase compensation resistor, 1
11 to 13 are as shown in FIG. The magnitude of the light load current gain 17 is set to be larger than that of the current gain 13, the third phase compensation resistor 20 is set to be larger than that of the first phase compensation resistor 11, and the third phase compensation capacitor is set. 19 is set so that the product with the third phase compensation resistor 20 is larger than T1 in "Equation 1".

Current mode control D shown in FIG.
The C / DC converter feeds the reactor current back to the current mode control control circuit 4 via the current gain 13 at the time of normal load by the current gain switching circuit 16, and at the time of light load, the current gain 1 for light load.
The reactor current is fed back to the current mode control control circuit 4 via 7 to increase the current gain at light load to maintain a good S / N ratio. Further, when the load is normal, the first voltage gain changeover switch 15
Is connected to the first phase compensating resistor 11 and the first phase compensating capacitor 10. When the load is light, the voltage gain switching switch 15 is connected to the third phase compensating resistor 20 and the third phase compensating capacitor 19. When the current gain 13 is connected and the current gain 13 is switched to the light load current gain 17 at the time of light load, the current gain becomes large and the control band ωvc is prevented from lowering from "Equation 2". ”, FIG. 8 and FIG. 9, current mode control D
This prevents the break point frequency 1 / T1 of the open-loop gain characteristic T of the C / DC converter from decreasing and becoming lower than the break point frequency 1 / T3.

Embodiment 4 4 is a schematic diagram showing Embodiment 4 of the present invention, in which 15 is a first voltage gain changeover switch, 16 is a current gain changeover circuit, 17 is a light load current gain, and 21 is a third voltage. A detection resistor, 22 is a fourth voltage detection resistor, and 1 to 13 are as shown in FIG. Note that the current gain for light load is 1
The magnitude of 7 is set to be larger than the current gain 13, and the third voltage detection resistor 21 and the fourth voltage detection resistor 22 are set to the third voltage detection resistor 21.
Is set so that the ratio of the voltage detection resistor 21 and the fourth voltage detection resistor 22 is equal to the ratio of the first voltage detection resistor 7 and the second voltage detection resistor 8, and the third voltage detection resistor 21 is It is set smaller than the first voltage detection resistor 7.

Current mode control D shown in FIG.
The C / DC converter feeds the reactor current back to the current mode control control circuit 4 via the current gain 13 at the time of normal load by the current gain switching circuit 16, and at the time of light load, the current gain 1 for light load.
The reactor current is fed back to the current mode control control circuit 4 via 7 to increase the current gain at light load to maintain a good S / N ratio. Further, when the load is normal, the first voltage gain changeover switch 15
Is connected to the contacts of the first voltage detection resistor 7 and the second voltage detection resistor 8, and the switch 15 for voltage gain changeover is connected to the third voltage detection resistor 21 and the fourth voltage detection resistor 22 when the load is light. Connected to contacts, current gain 1 at light load
When 3 is switched to the light load current gain 17, the current gain becomes large, and the control band ωvc of the current mode control DC / DC converter is prevented from lowering from "Equation 2".

Embodiment 5 FIG. 5 is a schematic diagram showing a fifth embodiment of the present invention, in which 15 is a first voltage gain changeover switch, 16 is a current gain changeover circuit, 17 is a light load current gain, and 19 is a third phase. Compensation capacitor, 20 is a third phase compensation resistor, 21 is a third voltage detection resistor, 22 is a fourth voltage detection resistor,
1 to 13 are as shown in FIG. The magnitude of the light load current gain 17 is set to be larger than that of the current gain 13, and the third phase compensation resistor 20 and the third voltage detection resistor 21 are connected to the third phase compensation resistor 20 and the third voltage detection resistor 21. The ratio of the resistor 21 is set to be larger than the ratio of the first phase compensation resistor 11 and the first voltage detection resistor 7, and the fourth voltage detection resistor 22 is set to the third voltage detection resistor 21 and the fourth voltage detection resistor 7. The ratio of the detection resistor 22 is set to be equal to the ratio of the first voltage detection resistor 7 and the second voltage detection resistor 8, and the third phase compensation capacitor 19 is the third phase compensation capacitor 1
The product of 9 and the third phase compensation resistor 20 is set to be larger than T1 in "Equation 1".

Current mode control D shown in FIG.
The C / DC converter feeds the reactor current back to the current mode control control circuit 4 via the current gain 13 at the time of normal load by the current gain switching circuit 16, and at the time of light load, the current gain 1 for light load.
The reactor current is fed back to the current mode control control circuit 4 via 7 to increase the current gain at light load to maintain a good S / N ratio. Further, when the load is normal, the first voltage gain changeover switch 15
Is connected to the contacts of the first voltage detection resistor 7 and the second voltage detection resistor 8, and the switch 15 for voltage gain switching is connected to the contacts of the third voltage detection resistor 21 and the fourth voltage detection resistor 22 when the load is light. It is connected. The second voltage gain changeover switch 23 is connected to the first phase compensation capacitor 10 and the first phase load compensation resistor 11 at the normal load, and the third phase compensation capacitor 19 and the third phase compensation capacitor 19 at the light load. It is connected to the phase compensating resistor 20 of No. 3 and prevents the current gain 13 from becoming large when the current gain 13 is switched to the light load current gain 17 at the time of a light load, and lowering the control band ωvc from "Equation 2". At the same time, when the light load is “Equation 1”, the break point frequency 1 / T1 of the open-loop gain characteristic T of the current mode control DC / DC converter decreases from FIG. 8 and FIG. 9 and becomes lower than the break point frequency 1 / T3. Prevent.

Embodiment 6 FIG. 6 is a schematic diagram showing a sixth embodiment of the present invention, in which 14 is a second phase compensation resistor, 15 is a first voltage gain changeover switch, 16 is a current gain changeover circuit, and 17 is a light load. Current gain, 21 is the third voltage detection resistor, 22 is the fourth voltage detection resistor, and 1 to 13 are as shown in FIG. The magnitude of the light load current gain 17 is set to be larger than that of the current gain 13, and the second phase compensation resistor 14
And the third voltage detection resistor 21 is the second phase compensation resistor 14
And the third voltage detection resistor 21 are set to be larger than the ratio of the second phase compensation resistor 11 and the first voltage detection resistor 7, and the fourth voltage detection resistor 22 is set to the third voltage detection resistor. The ratio of 21 to the fourth voltage detection resistor 22 is set to be equal to the ratio of the first voltage detection resistor 7 and the second voltage detection resistor 8.

Current mode control D shown in FIG.
The C / DC converter feeds the reactor current back to the current mode control control circuit 4 via the current gain 13 at the time of normal load by the current gain switching circuit 16, and at the time of light load, the current gain 1 for light load.
The reactor current is fed back to the current mode control control circuit 4 via 7 to increase the current gain at light load to maintain a good S / N ratio. Further, when the load is normal, the first voltage gain changeover switch 15
Is connected to the contacts of the first voltage detection resistor 7 and the second voltage detection resistor 8, and the switch 15 for voltage gain changeover is connected to the third voltage detection resistor 21 and the fourth voltage detection resistor 22 when the load is light. It is connected to the contact. The second voltage gain changeover switch 23 is connected to the first phase compensating resistor 11 at normal load, connected to the second phase compensating resistor 14 at light load, and the current gain 13 at light load.
When the current is switched to the light load current gain 17, the current gain becomes large, and the control band ωvc is prevented from decreasing from "Equation 2", and at the time of light load "Equation 1", the current from FIG. 8 and FIG. This prevents the break point frequency 1 / T1 of the open-loop gain characteristic T of the mode control DC / DC converter from decreasing and becoming lower than the break point frequency 1 / T3.

Embodiment 7 7 is a schematic diagram showing a seventh embodiment of the present invention, in which 15 is a first voltage gain changeover switch, 16 is a current gain changeover circuit, 17 is a light load current gain, and 18 is a second phase. Compensation capacitor, 21 is the third voltage detection resistor, 22 is the fourth
The voltage detection resistors of Nos. 1 to 13 are as shown in FIG. The magnitude of the light load current gain 17 is set larger than that of the current gain 13, and the second phase compensation capacitor 18 has a product of the first phase compensation resistor 11 and the second phase compensation capacitor 18 equal to 1 '', the third voltage detection resistor 21 is set to be smaller than the first voltage detection resistor 7, and the fourth voltage detection resistor 22 is set to the third voltage detection resistor 21 and the third voltage detection resistor 21. The ratio of the voltage detection resistor 22 of No. 4 is set to be equal to the ratio of the first voltage detection resistor 7 and the second voltage detection resistor 8.

Current mode control D shown in FIG.
The C / DC converter feeds the reactor current back to the current mode control control circuit 4 via the current gain 13 at the time of normal load by the current gain switching circuit 16, and at the time of light load, the current gain 1 for light load.
The reactor current is fed back to the current mode control control circuit 4 via 7 to increase the current gain at light load to maintain a good S / N ratio. Further, when the load is normal, the first voltage gain changeover switch 15
Is connected to the contacts of the first voltage detection resistor 7 and the second voltage detection resistor 8, and the switch 15 for voltage gain changeover is connected to the third voltage detection resistor 21 and the fourth voltage detection resistor 22 when the load is light. It is connected to the contact. Further, the second voltage gain changeover switch 23 is connected to the first phase compensating capacitor 10 at the time of normal load, and the second voltage gain changeover switch 23 at the time of light load.
Is connected to the phase compensating capacitor 18 and the current gain becomes large when the current gain 13 is switched to the switching current gain 17 at the time of light load, and the control band ω changes from “Equation 2”.
In addition to preventing vc from decreasing, the break point frequency 1 / T1 of the open loop gain characteristic T of the current mode control DC / DC converter decreases at the time of light load "Equation 1", FIG. 8 and FIG. It is prevented that the frequency becomes lower than 1 / T3.

[0031]

According to the first aspect of the invention, the current gain is switched at a light load to maintain a good S / N ratio, and the phase compensating resistor of the error amplifier in the voltage compensating circuit is switched and the current gain becomes large. In this case, by switching using a switch and increasing the resistance value, the control band ωvc that drops below Equation 2 is kept constant, and T3 during light load number 1 increases and drops below a frequency of 1 / T1 or below. 1 /
Set T3.

According to the second aspect of the invention, the current gain is switched at a light load to maintain a good S / N ratio, and the phase compensation capacitor of the error amplifier in the voltage compensation circuit is switched to a large current gain. At this time, change over using a switch to increase the capacitor capacity and increase and decrease T3 in the light load time 1/1 to a frequency below 1 / T1
Set T3.

According to the third aspect of the invention, the current gain is switched at a light load to maintain a good S / N ratio, and the current gain is set to the phase compensation capacitor and the phase compensation resistor of the error amplifier in the voltage compensation circuit. When it becomes large after switching, it is switched using a switch to keep the control band ωvc, which is lower than Equation 2, constant, and T3 during light load hour 1
1 / T3 is set to a frequency equal to or lower than 1 / T1 that increases and decreases.

According to the fourth aspect of the invention, the current gain is switched at a light load to maintain a good S / N ratio, and the voltage detection resistor in the voltage compensation circuit is used when the current gain is switched and becomes large. The control band ωvc, which is lower than that of the expression 2, is kept constant by switching the control band ωvc.

According to the fifth aspect of the invention, the current gain is switched at a light load to maintain a good S / N ratio, and the voltage detection resistor in the voltage compensation circuit, the phase compensation capacitor of the error amplifier and the phase compensation resistor are also provided. When the current gain is switched and becomes large, it is switched using a switch to keep the control band ωvc, which is lower than Equation 2, constant, and to increase T3 during light load number 1 to a frequency of 1 / T1 or less that is reduced. Set 1 / T3.

According to the sixth aspect of the invention, the current gain is switched at a light load to maintain a good S / N ratio, and the current gain is cut off the voltage detection resistor in the voltage compensation circuit and the phase compensation resistor of the error amplifier. Instead, when it becomes large, it is switched using a switch to keep the control band ωvc, which is lower than Equation 2, constant and to set 1 / T3 to a frequency of 1 / T1 or less, which is increased by increasing T3 in light load number 1. To do.

According to the seventh aspect of the invention, the current gain is switched at a light load to maintain a good S / N ratio, and the current gain is cut off in the voltage detection resistor in the voltage compensation circuit and the phase compensation capacitor of the error amplifier. Instead, when it becomes large, it is switched by using a switch, and the control band ωv is lower than that of the equation 2.
While keeping c constant, 1 / T3 is set to a frequency below 1 / T1 at which T3 during light load time 1 is increased and decreased.

[Brief description of drawings]

FIG. 1 is a diagram showing a first embodiment of a current mode control DC / DC converter according to the present invention.

FIG. 2 is a diagram showing a second embodiment of a current mode control DC / DC converter according to the present invention.

FIG. 3 is a diagram showing a third embodiment of a current mode control DC / DC converter according to the present invention.

FIG. 4 is a diagram showing a fourth embodiment of a current mode control DC / DC converter according to the present invention.

FIG. 5 is a diagram showing a fifth embodiment of a current mode control DC / DC converter according to the present invention.

FIG. 6 is a diagram showing a sixth embodiment of a current mode control DC / DC converter according to the present invention.

FIG. 7 is a diagram showing a seventh embodiment of a current mode control DC / DC converter according to the present invention.

FIG. 8 is an open loop gain characteristic of a current mode control DC / DC converter.

FIG. 9: Current mode control DC at light load
/ DC converter open loop gain characteristics.

FIG. 10 is a diagram showing the relationship between the reactor current detection signal and the amplitude of turn-on noise.

FIG. 11: Conventional current mode control DC /
It is a block diagram which shows a DC converter.

[Explanation of symbols]

1 switching regulator, 2 load, 3 reactor current detection circuit, 4 current mode control control circuit, 5 power supply, 6 error amplifier, 7 first voltage detection resistor, 8 second voltage detection resistor, 9 reference voltage source, 10
First voltage compensation capacitor, 11 first voltage compensation resistor, 12 voltage compensation circuit, 13 first current gain,
14 second voltage compensation resistor, 15 first switch,
16 current gain switching circuit, 17 second current gain, 18 second voltage compensation capacitor, 19 third voltage compensation capacitor, 20 third voltage compensation resistor,
21 3rd voltage detection resistance, 22 4th voltage detection resistance, 23 2nd switch.

Claims (7)

[Claims] 1. A first voltage detection resistor, one of which is connected to an output terminal of a switching regulator, and a second voltage detection resistor, one of which is connected to the other of the first voltage detection resistors and the other of which is connected to a ground potential. A resistor, an error amplifier having a first input end connected to a connection point between the first voltage detection resistor and the second voltage detection resistor, and a second input end connected to a reference voltage source. A first voltage compensating resistor, one of which is connected to a first input terminal, one of which is connected to the other of the first voltage compensating resistors, and the other of which is connected to the output terminal of the error amplifier. A voltage compensation circuit having a voltage compensation capacitor, a voltage input terminal connected to the input terminal of the switching regulator, a load connected to the output terminal of the switching regulator, and a load connected to the switching regulator. And a reactor current detection circuit for detecting a reactor current inside the switching regulator, a first current gain connected to the reactor current detection circuit, an output of an error amplifier in the first current gain and the voltage compensation circuit. In a current mode control DC / DC converter comprising a current mode control control circuit having an input terminal connected to an end and an output terminal connected to the switching regulator,
A current gain switching circuit is inserted between the reactor current detection circuit and the first current gain, and a second current gain having a gain different from the first current gain is connected in parallel with the first current gain. A means for switching the current gain by the current gain switching circuit and a second voltage compensating resistor having a resistance value different from that of the first voltage compensating resistor are connected in parallel to the first voltage compensating resistor in the voltage compensating circuit. And a means for switching the voltage compensating resistor by inserting a first switch between the first voltage compensating resistor and the second voltage compensating resistor and the first input terminal of the error amplifier. A current mode control DC / DC converter characterized by the above. 2. A first voltage detecting resistor, one of which is connected to an output terminal of a switching regulator, and a second voltage detecting resistor, one of which is connected to the other of the first voltage detecting resistors and the other of which is connected to a ground potential. A resistor, an error amplifier having a first input end connected to a connection point between the first voltage detection resistor and the second voltage detection resistor, and a second input end connected to a reference voltage source. A first voltage compensating resistor, one of which is connected to a first input terminal, one of which is connected to the other of the first voltage compensating resistors, and the other of which is connected to the output terminal of the error amplifier. A voltage compensation circuit having a voltage compensation capacitor, a voltage input terminal connected to the input terminal of the switching regulator, a load connected to the output terminal of the switching regulator, and a load connected to the switching regulator. And a reactor current detection circuit for detecting a reactor current inside the switching regulator, a first current gain connected to the reactor current detection circuit, an output of an error amplifier in the first current gain and the voltage compensation circuit. In a current mode control DC / DC converter comprising a current mode control control circuit having an input terminal connected to an end and an output terminal connected to the switching regulator,
A current gain switching circuit is inserted between the reactor current detection circuit and the first current gain, and a second current gain having a gain different from the first current gain is connected in parallel with the first current gain. A means for switching the current gain by the current gain switching circuit and a second voltage compensating capacitor having a capacitance different from that of the first voltage compensating capacitor are connected in parallel to the first voltage compensating capacitor in the voltage compensating circuit. And a means for switching the voltage compensating capacitor by inserting a first switch between the first voltage compensating capacitor and the second voltage compensating capacitor and the first voltage compensating resistor. Current mode control DC / DC converter characterized by: 3. A first voltage detection resistor, one of which is connected to the output terminal of the switching regulator, and a second voltage detection resistor, one of which is connected to the other of the first voltage detection resistors and the other of which is connected to the ground potential. A resistor, an error amplifier having a first input end connected to a connection point between the first voltage detection resistor and the second voltage detection resistor, and a second input end connected to a reference voltage source. A first voltage compensating resistor, one of which is connected to a first input terminal, one of which is connected to the other of the first voltage compensating resistors, and the other of which is connected to the output terminal of the error amplifier. A voltage compensation circuit having a voltage compensation capacitor, a voltage input terminal connected to the input terminal of the switching regulator, a load connected to the output terminal of the switching regulator, and a load connected to the switching regulator. And a reactor current detection circuit for detecting a reactor current inside the switching regulator, a first current gain connected to the reactor current detection circuit, an output of an error amplifier in the first current gain and the voltage compensation circuit. In a current mode control DC / DC converter comprising a current mode control control circuit having an input terminal connected to an end and an output terminal connected to the switching regulator,
A current gain switching circuit is inserted between the reactor current detection circuit and the first current gain, and the gain is different from the first current gain in parallel with the first current gain.
Means for switching the current gain by connecting the current gain switching circuit and the current gain switching circuit, and a second voltage compensating resistor in parallel with the first voltage compensating resistor and the first voltage compensating capacitor in the voltage compensating circuit. A second voltage compensation capacitor is connected to the first voltage compensation resistor and the second voltage compensation resistor.
A current mode, characterized in that a first switch is inserted between the voltage compensating resistor and the first input terminal of the error amplifier to switch the voltage compensating resistor and the voltage compensating capacitor. Control DC / DC converter. 4. A first voltage detection resistor, one of which is connected to an output terminal of a switching regulator, and a second voltage detection resistor, one of which is connected to the other of the first voltage detection resistors and the other of which is connected to a ground potential. A resistor, an error amplifier having a first input end connected to a connection point between the first voltage detection resistor and the second voltage detection resistor, and a second input end connected to a reference voltage source. A first voltage compensating resistor, one of which is connected to a first input terminal, one of which is connected to the other of the first voltage compensating resistors, and the other of which is connected to the output terminal of the error amplifier. A voltage compensation circuit having a voltage compensation capacitor, a voltage input terminal connected to the input terminal of the switching regulator, a load connected to the output terminal of the switching regulator, and a load connected to the switching regulator. And a reactor current detection circuit for detecting a reactor current inside the switching regulator, a first current gain connected to the reactor current detection circuit, an output of an error amplifier in the first current gain and the voltage compensation circuit. In a current mode control DC / DC converter comprising a current mode control control circuit having an input terminal connected to an end and an output terminal connected to the switching regulator,
A current gain switching circuit is inserted between the reactor current detection circuit and the first current gain, and the gain is different from the first current gain in parallel with the first current gain.
And a means for switching the current gain by a current gain switching circuit, and a third voltage detecting resistor and a fourth voltage detecting resistor in parallel with the first voltage detecting resistor and the second voltage detecting resistor in the voltage compensating circuit. The voltage detection resistor is connected to the first
Between the voltage detection resistor and the second voltage detection resistor connection point and between the third voltage detection resistor and the fourth voltage detection resistor connection point and the first input end of the error amplifier. A current mode control D, characterized in that it comprises means for inserting a switch and switching the voltage detection resistance.
C / DC converter. 5. A first voltage detection resistor, one of which is connected to the output terminal of the switching regulator, and a second voltage detection resistor, one of which is connected to the other of the first voltage detection resistors and the other of which is connected to the ground potential. A resistor, an error amplifier having a first input end connected to a connection point between the first voltage detection resistor and the second voltage detection resistor, and a second input end connected to a reference voltage source. A first voltage compensating resistor, one of which is connected to a first input terminal, one of which is connected to the other of the first voltage compensating resistors, and the other of which is connected to the output terminal of the error amplifier. A voltage compensation circuit having a voltage compensation capacitor, a voltage input terminal connected to the input terminal of the switching regulator, a load connected to the output terminal of the switching regulator, and a load connected to the switching regulator. And a reactor current detection circuit for detecting a reactor current inside the switching regulator, a first current gain connected to the reactor current detection circuit, an output of an error amplifier in the first current gain and the voltage compensation circuit. In a current mode control DC / DC converter comprising a current mode control control circuit having an input terminal connected to an end and an output terminal connected to the switching regulator,
A current gain switching circuit is inserted between the reactor current detection circuit and the first current gain, and the gain is different from the first current gain in parallel with the first current gain.
Means for switching the current gain of the current gain switching circuit and switching the current gain by the current gain switching circuit, and a third voltage detection resistor and a third voltage detection resistor in parallel with the first voltage detection resistor and the second voltage detection resistor in the voltage compensation circuit. Connect the voltage detection resistor of 4,
Between the connection point of the first voltage detection resistor and the second voltage detection resistor, the connection point of the third voltage detection resistor and the fourth voltage detection resistor, and the first input terminal of the error amplifier. A means for switching the voltage detection resistor by inserting a first switch into the first voltage compensation resistor, and further comprising a second voltage compensation resistor and a second voltage compensation resistor in parallel with the first voltage compensation resistor and the first voltage compensation capacitor. A voltage compensating capacitor is connected, and a second switch is inserted between the first voltage compensating resistor and the second voltage compensating resistor and the first input terminal of the error amplifier for voltage compensating. A current mode control DC / DC converter comprising means for switching between a resistance and a voltage compensating capacitor. 6. A first voltage detecting resistor, one of which is connected to an output terminal of a switching regulator, and a second voltage detecting resistor, one of which is connected to the other of the first voltage detecting resistors and the other of which is connected to a ground potential. A resistor, an error amplifier having a first input end connected to a connection point between the first voltage detection resistor and the second voltage detection resistor, and a second input end connected to a reference voltage source. A first voltage compensating resistor, one of which is connected to a first input terminal, one of which is connected to the other of the first voltage compensating resistors, and the other of which is connected to the output terminal of the error amplifier. A voltage compensation circuit having a voltage compensation capacitor, a voltage input terminal connected to the input terminal of the switching regulator, a load connected to the output terminal of the switching regulator, and a load connected to the switching regulator. And a reactor current detection circuit for detecting a reactor current inside the switching regulator, a first current gain connected to the reactor current detection circuit, an output of an error amplifier in the first current gain and the voltage compensation circuit. In a current mode control DC / DC converter comprising a current mode control control circuit having an input terminal connected to an end and an output terminal connected to the switching regulator,
A current gain switching circuit is inserted between the reactor current detection circuit and the first current gain, and the gain is different from the first current gain in parallel with the first current gain.
Means for switching the current gain of the current gain switching circuit and switching the current gain by the current gain switching circuit, and a third voltage detection resistor and a third voltage detection resistor in parallel with the first voltage detection resistor and the second voltage detection resistor in the voltage compensation circuit. Connect the voltage detection resistor of 4,
Between the connection point of the first voltage detection resistor and the second voltage detection resistor, the connection point of the third voltage detection resistor and the fourth voltage detection resistor, and the first input terminal of the error amplifier. And a means for switching a voltage detection resistance by inserting a first switch into the first voltage compensation resistance, and further connecting the second voltage compensation resistance in parallel with the first voltage compensation resistance, thereby providing the first voltage compensation resistance. And inserting a second switch between the second voltage compensating resistor and the first input terminal of the error amplifier,
A current mode control DC / DC converter comprising means for switching a voltage compensating resistor. 7. A first voltage detecting resistor, one of which is connected to an output terminal of a switching regulator, and a second voltage detecting resistor, one of which is connected to the other of the first voltage detecting resistors and the other of which is connected to a ground potential. A resistor, an error amplifier having a first input end connected to a connection point between the first voltage detection resistor and the second voltage detection resistor, and a second input end connected to a reference voltage source. A first voltage compensating resistor, one of which is connected to a first input terminal, one of which is connected to the other of the first voltage compensating resistors, and the other of which is connected to the output terminal of the error amplifier. A voltage compensation circuit having a voltage compensation capacitor, a voltage input terminal connected to the input terminal of the switching regulator, a load connected to the output terminal of the switching regulator, and a load connected to the switching regulator. And a reactor current detection circuit for detecting a reactor current inside the switching regulator, a first current gain connected to the reactor current detection circuit, an output of an error amplifier in the first current gain and the voltage compensation circuit. In a current mode control DC / DC converter comprising a current mode control control circuit having an input terminal connected to an end and an output terminal connected to the switching regulator,
A current gain switching circuit is inserted between the reactor current detection circuit and the first current gain, and the gain is different from the first current gain in parallel with the first current gain.
Means for switching the current gain of the current gain switching circuit and switching the current gain by the current gain switching circuit, and a third voltage detection resistor and a third voltage detection resistor in parallel with the first voltage detection resistor and the second voltage detection resistor in the voltage compensation circuit. Connect the voltage detection resistor of 4,
Between the connection point of the first voltage detection resistor and the second voltage detection resistor, the connection point of the third voltage detection resistor and the fourth voltage detection resistor, and the first input terminal of the error amplifier. A means for switching a voltage detection resistor by inserting a first switch into the first voltage compensation resistor, and further connecting a second voltage compensation capacitor in parallel with the first voltage compensation capacitor,
And a means for switching the voltage compensating capacitor by inserting a second switch between the second voltage compensating capacitor and the first voltage compensating resistor. Current mode control DC / DC converter.