KR102065576B1 - Switching dc-dc converter, circuit and method to convert voltage thereof - Google Patents

Abstract

The present invention discloses a switching DC-DC converter for switching the input voltage to convert it into an output voltage. The switching DC-DC converter performs an overvoltage protection operation in response to the output voltage entering the overvoltage, and the output voltage and the output current can be stabilized by maintaining the feedback loop in the overvoltage protection operation period in which the overvoltage occurs in the output voltage. . The switching DC-DC converter includes a voltage converting circuit, and the voltage converting circuit receives an output voltage and performs an operation of switching driving the input voltage, and the feedback of the output voltage can be made differently according to the normal mode and the overvoltage mode.

Description

Switching DC-DC converter, its voltage conversion circuit and voltage conversion method {SWITCHING DC-DC CONVERTER, CIRCUIT AND METHOD TO CONVERT VOLTAGE THEREOF}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switching DC-DC converter, and more particularly, to a switching DC-DC converter, a voltage conversion circuit and a voltage conversion method thereof, which perform DC-DC voltage conversion by a switching method and have an overvoltage protection function. .

In general, a power management integrated circuit (hereinafter, referred to as a PMIC) is designed to perform an over-voltage protection operation that limits an output voltage when the output voltage enters an overvoltage.

The PMIC may be implemented as a switching DC-DC converter, and the switching DC-DC converter is designed to perform the above overvoltage protection operation.

The switching DC-DC converter stops the switching operation when the output voltage exceeds the overvoltage protection set voltage and performs the overvoltage protection operation, and performs the switching operation again when the output voltage falls below the overvoltage protection set voltage.

When the conventional switching DC-DC converter performs the overvoltage protection operation in response to the overvoltage, a large ripple appears in the output voltage compared to the normal state. In this case, a larger fluctuation occurs in the input voltage and the input current than in the normal state.

The above phenomenon can be a serious problem in an application of a system in which the input voltage is low or the output ripple voltage is important. For example, the above problem may occur in a notebook application.

That is, when the overvoltage protection operation is performed as the output voltage enters the overvoltage, the feedback loop of the conventional switching DC-DC converter may be broken, and the switching DC-DC converter is operated in the intermittent mode, thereby causing excessive inductor current variation. May occur. As a result, large ripples may occur in the output voltage of the switching DC-DC converter, and large variations may occur in the input voltage of the switching DC-DC converter.

Therefore, it is necessary to present a switching DC-DC converter in which the input voltage and the output voltage can be stabilized in the overvoltage protection operation section even when overvoltage protection is performed corresponding to the overvoltage of the output voltage.

An object of the present invention is to provide a switching DC-DC converter and a voltage conversion circuit and method thereof in which an output voltage can be stabilized by maintaining a feedback loop in an overvoltage protection operation section in which an overvoltage occurs.

In addition, an object of the present invention is to provide a switching DC-DC converter and a voltage conversion circuit and method thereof in which an input voltage can be stabilized by regulating an output voltage in a feedback operation in an overvoltage prevention operation section in which an overvoltage occurs.

The voltage conversion circuit of the switching DC-DC converter according to the present invention controls the switching of the input voltage to the output voltage.

The voltage conversion circuit of the switching DC-DC converter may include: a switching circuit which performs the switching driving to drive the input voltage by a driving pulse; A pulse generation circuit for providing the drive pulse at a pulse width corresponding to a drive voltage; And a feedback path for feeding back the output voltage to provide the driving voltage, and providing the feedback path with a first feedback path for providing the driving voltage by a first reference voltage when the output voltage corresponds to a normal mode. And a feedback circuit providing a second feedback path for providing the driving voltage to the feedback path when the output voltage corresponds to an overvoltage mode.

In addition, in the voltage conversion method of the switching DC-DC converter according to the present invention, when the first feedback voltage with respect to the output voltage is greater than the first reference value by a predetermined first offset value or more, the normal mode is determined and the second feedback voltage is a constant voltage. Determining an overvoltage mode when the second reference voltage is greater than or equal to a second offset value. Selecting the first feedback voltage as a feedback voltage in response to the normal mode and selecting the second feedback voltage as the feedback voltage in response to the overvoltage mode; Selecting the first reference voltage as a reference voltage in response to the normal mode and selecting the second reference voltage as the reference voltage in response to the overvoltage mode; Generating a driving voltage by comparing the feedback voltage with the reference voltage; And controlling the switching driving of the input voltage in response to the driving voltage.

In addition, the switching DC-DC converter according to the present invention for switching the input voltage to the output voltage by switching, the first feedback path for feeding back a first feedback voltage corresponding to the output voltage and the first corresponding to the output voltage A second feedback path for feeding back a feedback voltage is selectively provided as a feedback path corresponding to a normal mode and an overvoltage mode, switching the input voltage with a driving voltage output from the feedback path, and the second feedback voltage is When the first offset value is greater than or equal to a second reference voltage having a constant voltage, the controller is determined to be in the overvoltage mode. When the first feedback voltage is greater than or equal to a second offset value, which is preset than the first reference voltage, the controller is determined to be the normal mode. A voltage conversion circuit for controlling the selection of the path; A first feedback voltage providing circuit for providing the first feedback voltage; And a first reference voltage providing circuit providing the first reference voltage.

In addition, a switching DC-DC converter according to the present invention for converting an input voltage into an output voltage by switching driving provides a first feedback path corresponding to a normal mode and corresponds to the output voltage by the first feedback path. A first feedback circuit performing switching driving of the input voltage using the first feedback voltage; And a second feedback circuit providing a second feedback path corresponding to an overvoltage mode and performing switching driving of the input voltage by using the second feedback voltage corresponding to the output voltage by the second feedback path. The normal mode and the overvoltage mode are determined according to the state of the output voltage, and the feedback function is maintained by either the first feedback path or the second feedback path.

In addition, the power conversion method of the switching DC-DC converter according to the present invention comprises the steps of determining the normal mode and the overvoltage mode according to the state of the output voltage; Providing a first feedback path corresponding to the normal mode to perform switching driving of an input voltage using the first feedback voltage corresponding to the output voltage; And providing a second feedback path corresponding to the overvoltage mode to perform switching driving of the input voltage using the second feedback voltage corresponding to the output voltage.

Therefore, according to the present invention, the switching DC-DC converter can maintain a feedback loop in response to the output voltages of the steady state and the overvoltage state, thereby improving the ripple in the output voltage.

Further, according to the present invention, the feedback of the output voltage is maintained in the overvoltage protection operation section corresponding to the overvoltage of the output voltage, so that the output voltage of the switching DC-DC converter is stably regulated. Therefore, there is an effect that the input voltage of the switching DC-DC converter can be stabilized.

Further, according to the present invention, even if the overvoltage protection operation corresponding to the overvoltage of the output voltage is performed as described above, the output voltage and the input voltage can be stabilized, thereby ensuring the reliability of the switching DC-DC converter.

1 is a circuit diagram showing a preferred embodiment of a switching DC-DC converter according to the present invention.
FIG. 2 is a waveform diagram illustrating the operation of FIG. 1. FIG.
3 is a circuit diagram illustrating a modification of FIG. 1.
4 is a circuit diagram illustrating another modified example of FIG. 1.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. The terms used in the present specification and claims are not to be construed as being limited to ordinary or dictionary meanings, but should be interpreted as meanings and concepts corresponding to the technical matters of the present invention.

The embodiments described in the specification and the configuration shown in the drawings are preferred embodiments of the present invention, and do not represent all of the technical idea of the present invention, various equivalents and modifications that can replace them at the time of the present application are There may be.

An embodiment according to the present invention discloses a switching DC-DC converter included in a PMIC, and the switching DC-DC converter is implemented to have a configuration for performing an overvoltage prevention operation.

1 illustrates a switching DC-DC converter including a voltage conversion circuit 10.

Referring to FIG. 1, an input voltage Vin of a DC component is transmitted through an inductor L, and a voltage Vx means an inductor voltage driven by the switch SW1. Hereinafter, the voltage Vx is referred to as an input driving voltage, and the inductor current is described as 'IL'.

The input driving voltage Vx is transmitted to the output voltage Vo through the diode SW2. The output voltage Vo is equivalently expressed as being output through a circuit including the capacitor Co and the current source Io.

The voltage conversion circuit 10 controls switching of the direct current input voltage Vin to be converted to the direct current output voltage Vo.

To this end, the voltage conversion circuit 10 includes a switching circuit, a controller 12, a feedback voltage providing circuit, a reference voltage providing circuit, an error amplifier EA, and a mode determination unit. The voltage conversion circuit 10 may be implemented with one chip.

The switching circuit may include a switching device SW1 and a gate driver GD.

The switching element SW1 may be configured as an NMOS transistor and input-drive an input voltage Vin applied to the inductor L by a driving pulse PWM of the controller 12 transmitted through the gate driver GD. A switching operation of driving the voltage Vx is performed. The gate driver GD transfers the driving pulse PWM output from the controller 12 to the switching device SW1, and may be configured as a C-MOS transistor that normally performs pull-up and pull-down operations.

1 includes a pulse generation circuit that generates a driving pulse PWM in response to a direct current driving voltage Vc, which may be illustrated by the controller 12.

The controller 12 generates and outputs a driving pulse PWM having a pulse width corresponding to the DC level of the driving voltage Vc. The controller 12 may output a driving pulse PWM having a high duty ratio when the level of the driving voltage Vc is high, and output a driving pulse PWM having a small duty ratio when the level of the driving voltage Vc is low. The driving pulse PWM has a wide pulse width when the duty ratio is large and a narrow pulse width when the duty ratio is small.

Meanwhile, the present invention uses the first feedback voltage Vfbo, the second feedback voltage Vfbi, the first reference voltage Vrefo, and the second reference voltage Vrefi to form a feedback loop, and the second feedback voltage. Vfbi may be set to have a level lower than the first feedback voltage Vfbo, and the second reference voltage Vrefi may also be set to have a level lower than the first reference voltage Vrefo.

Here, the first feedback voltage Vfbo and the second feedback voltage Vfbi may be generated by dividing the output voltage Vo. The first feedback voltage Vfbo and the second feedback voltage Vfbi may be output from different voltage dividers dividing the output voltage Vo or different voltage divider resistance values of the same voltage divider dividing the output voltage Vo. Can be output from the tap.

The embodiment according to the present invention illustrates that the voltage conversion circuit 10 is configured to receive the voltage obtained by dividing the output voltage Vo from the voltage divider Fo configured as an external source as the first feedback voltage Vfbo. In addition, the embodiment according to the present invention illustrates that the voltage conversion circuit 10 is configured to receive a voltage obtained by dividing the output voltage Vo from the voltage divider Fi configured therein as the second feedback voltage Vfbi.

In addition, the embodiment according to the present invention illustrates that the first reference voltage Vrefo is provided from a voltage source configured outside the voltage conversion circuit 10. In addition, an embodiment according to the present invention illustrates that the second reference voltage Vrefi is provided from a voltage source configured inside the voltage conversion circuit. Here, the second reference voltage Vrefi is preferably provided as a constant voltage.

According to an embodiment of the present invention, the first feedback voltage Vfb0 and the first reference voltage Vrefo are provided outside the voltage conversion circuit 10, and the second feedback voltage Vfbi and the second reference voltage Vrefi are provided. Although illustrated as being provided inside the voltage conversion circuit 10, the present invention is not limited thereto and may be variously implemented according to the intention of the manufacturer.

The voltage divider Fo that provides the first feedback voltage Vfbo may include a plurality of resistors that divide the output voltage Vo. In addition, the first reference voltage Vrefo may be changed because an external external environment (temperature, etc.) affects the voltage source.

For example, the first reference voltage Vrefo may have a value representing a temperature change outside the voltage conversion circuit 10. That is, the level of the first reference voltage Vrefo may increase when the external temperature of the voltage conversion circuit 10 increases, and the level may decrease when the external temperature decreases.

The voltage conversion circuit 10 may receive the first reference voltage Vrefo to the multiplexer MUX2 through the voltage converter Kv, and the voltage converter Kv is a kind of transformer for adjusting the range of voltage. It may be configured as a transducer. The voltage converter Kv configured as an embodiment according to the present invention is illustrated as being configured inside the voltage conversion circuit 10, but may be configured externally without being limited thereto.

The voltage converting circuit 10 may include a multiplexer MUX1 as a feedback voltage providing circuit that selects and provides the first feedback voltage Vfbo and the second feedback voltage Vfbi.

The multiplexer MUX1 is provided by the first feedback voltage Vfbo provided by the voltage divider Fo external to the voltage conversion circuit 10 and the voltage divider Fi inside the voltage conversion circuit 910 by the mode signal SFP. Any one of the second feedback voltages Vfbi may be selected and output as the feedback voltage Vfb.

By the mode signal SFP, the multiplexer MUX1 selects the first feedback voltage Vfbo in the normal mode and outputs it as the feedback voltage Vfb, and selects the second feedback voltage Vfbi in the overvoltage mode. Output at voltage Vfb.

In addition, the voltage conversion circuit 10 may include a multiplexer MUX2 as a reference voltage providing circuit that selects and provides the first reference voltage Vrefo and the second reference voltage Vrefi described above.

The multiplexer MUX2 is provided by a first reference voltage Vrefo of an external voltage source and an internal constant voltage source provided through the voltage converter KV external to the voltage conversion circuit 10 by the mode signal SFP. Any one of the provided second reference voltages Vrefi may be selected and output as the reference voltage Vref.

By the mode signal SFP, the multiplexer MUX2 selects the first reference voltage Vrefo in the normal mode and outputs it as the reference voltage Vref, and outputs the second reference voltage Vrefi having a constant voltage in the overvoltage mode. Select and output to the reference voltage (Vref).

In addition, the voltage conversion circuit 10 includes an error amplifier EA for forming a feedback path.

The error amplifier EA receives the feedback voltage Vfb output from the multiplexer MUX1 to the negative terminal (-) and the reference voltage Vref output from the multiplexer MUX2 to the positive terminal (+). . The error amplifier EA outputs a result of comparing the feedback voltage Vfb and the reference voltage Vref as the driving voltage Vc, and the driving voltage Vc is provided to the controller 12.

In addition, the voltage conversion circuit 10 includes a mode determination unit that provides a mode signal SFP. The mode determination unit may include a comparison amplifier COM1, a comparison amplifier COM2, and an RS flip-flop 14, and determine a normal mode and an overvoltage mode to output a mode signal SFP.

The normal mode corresponds to the case where the output voltage Vo is maintained below the overvoltage prevention set voltage, and the overvoltage mode corresponds to the case where the output voltage Vo is maintained above the overvoltage prevention set voltage.

In the embodiment according to the present invention, the state entering the overvoltage mode in the normal mode may be determined by the comparison amplifier COM1, and the state entering the normal mode in the overvoltage mode may be determined by the comparison amplifier COM2. . In an embodiment according to the present invention, the second reference voltage Vrefi may be set to have a constant voltage corresponding to the overvoltage prevention set voltage.

The comparison amplifiers COM1 and COM2 may be configured to have hysteresis characteristics on the input to ensure stable operating characteristics. The comparison amplifiers COM1 and COM2 have offset values of several mV to several tens of mV with respect to the input, and thus the hysteresis characteristics may be set. The comparison amplifier COM1 has a configuration in which an additional offset voltage Vosr is applied to the first reference voltage Vrefo, and the comparison amplifier COM2 has a configuration in which an additional offset voltage Voss is applied to the second reference voltage Vrefi. Have

The comparison amplifier COM1 compares the first feedback voltage Vfbo applied to the positive terminal (+) and the first reference voltage Vrefo applied to the negative terminal (−).

The comparison amplifier COM1 outputs a high level normal flag NOM when the first feedback voltage Vfbo is higher than the offset voltage Vosr compared with the first reference voltage Vrefo, and outputs the first flag NOM. When the voltage Vfbo has a difference within the offset voltage range compared to the first reference voltage Vrefo, the low level normal flag NOM is output. In this case, the offset voltage Vosr may be set to have a value adjusted from several mV to several tens mV.

The comparison amplifier COM2 compares the second feedback voltage Vfbi applied to the positive terminal (+) and the second reference voltage Vrefi applied to the negative terminal (−).

The comparison amplifier COM2 outputs a high-level overvoltage flag OVP when the second feedback voltage Vfbi is higher than the offset voltage Oss compared to the second reference voltage Vrefi, and outputs a second overvoltage flag OVP. When the voltage Vfbi has a difference within the offset voltage range compared to the second reference voltage Vrefi, the low-voltage overvoltage flag OVP is output. In this case, the offset voltage Voss may be set to have a value adjusted from several mV to several tens mV.

The RS flip-flop 14 may be configured as a mode signal output unit, and the RS flip-flop 14 is configured to output the mode signal SFP in synchronization with the overvoltage flag OVP and the normal flag NOM.

The RS flip-flop 14 receives an overvoltage flag OVP, which is the output of the comparison amplifier COM2, as a set (S) signal, and a normal flag NOM, which is the output of the comparison amplifier COM1, as a reset (R) signal. Receive.

The RS flip-flop 14 corresponds to the normal mode and the overvoltage mode at different levels of the mode signal SFP in synchronization with the overvoltage flag OVP, which is the set (S) signal, and the normal flag NOM, which is the reset (R) signal. To print. The mode signal SFP is output as a high level in response to the normal mode and is output as a low level in response to the overvoltage mode.

The RS flip-flop 14 changes the mode signal SFP from a high level to a low level in synchronization with the time when the overvoltage flag OVP, which is a set (S) signal, transitions to high, and the normal flag, which is a reset (R) signal. The mode signal SFP may be configured to change from the low level to the high level in synchronization with the time point when NOM transitions to the high level.

As described above, in the embodiment of FIG. 1, a feedback loop in which the first feedback voltage Vfbo is selected in the normal mode and a feedback loop in which the second feedback voltage Vfbi is selected in the overvoltage mode are formed. .

In the description of the embodiment of FIG. 1, the overvoltage protection operation period means a period from when the overvoltage flag OVP transitions high until the normal flag NOM transitions high. Yes.

In the embodiment of FIG. 1, since the normal feedback loop is formed and maintained in the overvoltage protection operation period, that is, the overvoltage mode, the output voltage may be stabilized.

The operation of the embodiment of FIG. 1 described above will be described in more detail with reference to FIG. 2.

In response to the normal mode, the multiplexer MUX1 selects the first feedback voltage Vfbo and outputs it as the feedback voltage Vfb, and the multiplexer MUX2 selects the first reference voltage Vrefo to select the reference voltage (Vrefo). Vref).

The error amplifier EA compares the first feedback voltage Vfbo and the first reference voltage Vrefo to output the driving voltage Vc, and the controller 12 drives the driving pulse PWM corresponding to the driving voltage Vc. ) And the switching element SW1 performs a switching operation by the driving pulse PWM.

According to an embodiment of the present invention, the output voltage Vo is controlled by performing a voltage regulation operation of the input voltage Vin corresponding to the driving voltage Vc.

In the normal mode, the second feedback voltage Vfbi at a level lower than the first feedback voltage Vfbo is lower than the second reference voltage Vrefi, and the comparison amplifier COM2 has a low level overvoltage flag OVP. Keep it.

In addition, in the normal mode, the first feedback voltage Vfbo maintains a high or low state within the offset range compared to the second reference voltage Vrefo, and the comparison amplifier COM1 sets the low level normal flag NOM. Keep it.

As described above, in the normal mode, the feedback loop may be formed by regulating the output voltage Vo by switching the input voltage Vin using the first feedback voltage Vfbo.

In the embodiment according to the present invention, the first reference voltage Vrefo may increase in response to the increase in the external temperature while the normal mode is maintained.

When the first reference voltage Vrefo increases, the output voltage Vo increases due to a voltage regulating operation, and the first feedback voltage Vfbo also increases while maintaining a difference within the offset range from the first reference voltage Vrefo.

In the embodiment according to the present invention, when the first reference voltage Vrefo is maintained as described above, the output voltage Vo may increase to a level exceeding the overvoltage prevention set voltage.

The increase in the output voltage Vo is accompanied by the increase in the second feedback voltage Vfbi.

When the output voltage Vo rises above the overvoltage protection set voltage, the second feedback voltage Vfbi rises to have a greater difference than the offset voltage Voss compared to the second reference voltage Vrefi which is a constant voltage. do. As a result, the comparison amplifier COM2 outputs the overvoltage flag OVP at a high level.

The RS flip-flop 14 is switched to the set state in synchronization with the high level overvoltage flag OVP and outputs a low level mode signal SFP. That is, the normal mode is switched to the overvoltage mode.

When the embodiment is switched to the overvoltage mode as described above, the multiplexer MUX1 selects the second feedback voltage Vfbi and outputs the feedback voltage Vfb, and the multiplexer MUX2 receives the second reference voltage Vrefi. Select and output as the reference voltage (Vref).

In response, the error amplifier EA compares the second feedback voltage Vfbi and the second reference voltage Vrefi and outputs the driving voltage Vc. According to the exemplary embodiment of the present invention, the output voltage Vo is caused by the driving pulse PWM corresponding to the driving voltage Vc generated as a result of comparing the second feedback voltage Vrefi and the second reference voltage Vrefi. Perform a controlled voltage regulation operation.

That is, in the embodiment according to the present invention, a feedback loop for switching and driving the input voltage Vin is formed by using the second feedback voltage Vfbi in the overvoltage mode, and the input voltage Vin is regulated by the feedback loop. The output voltage Vo may be output.

In the overvoltage mode, the error amplifier EA compares the second feedback voltage Vfbi and the second reference voltage Vrefi of the constant voltage to output the driving voltage Vc. In an initial stage of the overvoltage mode, the second feedback voltage Vfbi has a high level with a difference greater than or equal to the offset voltage Voss range compared to the second reference voltage Vrefi.

The feedback loop of the overvoltage mode compares the second feedback voltage Vfbi with the second reference voltage Vrefi as a constant voltage, and as a result, the output voltage Vo is gradually stabilized based on the second reference voltage Vrefi. That is, since the second feedback voltage Vfbi is controlled by the second reference voltage Vrefi in the overvoltage mode, the output voltage Vo is not affected by the fluctuation of the first reference voltage Vrefo and the second reference voltage V Vrefi).

When the level of the output voltage Vo drops while the overvoltage mode is maintained as described above, the second feedback voltage Vfbi has a difference within the offset voltage Voss range compared to the second reference voltage Vrefi. At this time, the overvoltage flag MON is shifted to the low level.

Even when the level of the output voltage Vo is stabilized by the second reference voltage Vrefi in the state where the overvoltage mode is maintained as described above, when the first reference voltage Vrefo remains high, the comparison amplifier COM1 is normal. Keep the flag MON low. That is, the overvoltage mode is maintained while the first reference voltage Vrefo is high.

In the state where the overvoltage mode is maintained as described above, the first reference voltage Vrefo may be transitioned to a low level in response to stabilization of the external temperature.

In the overvoltage mode, the first feedback voltage Vfbo linked to the output voltage Vo stabilized by the second reference voltage Vrefi is compared with the first reference voltage Vrefo. When the first reference voltage Vrefo is sufficiently lowered due to stabilization of the external temperature, the first feedback voltage Vfbo and the first reference voltage Vrefo may have a difference greater than or equal to the offset voltage Vosr range. At this time, the comparison amplifier COM1 outputs a high level normal flag MON.

When the high level normal flag MON is output, the mode signal SFP output from the RS flip-flop 14 is changed to correspond to the normal mode. Accordingly, the embodiment according to the present invention switches to the normal mode and forms an feedback loop by the first feedback voltage Vfbo described above to regulate the output voltage Vo.

According to the embodiment of the present invention, as described above, the feedback loop may be continuously maintained even when the normal mode and the overvoltage mode are switched.

Therefore, in the embodiment according to the present invention, the feedback path is maintained in the overvoltage mode so that the output voltage Vo is stably maintained, and as a result, the driving voltage Vc can be set to the normal operating region. Therefore, the switching operation of the switching element SW1 is stabilized so that the inductor current IL and the input driving voltage Vx can be stabilized, and eventually the input voltage Vin can be stabilized.

In addition, in the embodiment according to the present invention, the feedback loop is continuously maintained as described above, and the second feedback voltage Vfbi having a level lower than the first feedback voltage Vfbo applied to the normal mode is applied to the overvoltage mode. Excessive ripple in the output voltage Vo can be eliminated.

As described above, according to the embodiment of the present invention, excessive ripple may be prevented from occurring in the output voltage Vo and large fluctuations in the input voltage Vin may be prevented.

As described above, the embodiment of the present invention maintains the overvoltage mode until the first reference voltage Vrefo is stabilized, and the feedback path using the second feedback voltage Vfbi is stably maintained in response to the overvoltage mode. The regulating operation can be performed stably.

Meanwhile, the embodiment according to the present invention may be modified as shown in FIG. 3 or 4 according to the intention of the manufacturer.

3 has a configuration in which the voltage converter Kv is removed and a low pass filter LPF is added as a delay circuit in the embodiment of FIG. 1, and the same components as those of the embodiment of FIG. Overlapping configuration and operation descriptions of components are omitted.

FIG. 3 corresponds to setting the gain factor of the voltage converter Kv of the embodiment of FIG. 1 to '1'.

The low pass filter LPF of FIG. 3 may be implemented as a logic counter or an analog delay cell.

Here, the low pass filter LPF is to apply the delay time when entering the normal mode from the overvoltage mode so that the normal mode can be performed in a stable state. The low pass filter LPF is for reinforcing the hysteresis characteristics of the comparison amplifier COM1.

4 is a configuration in which the offset voltage Voss of the second reference voltage Vrefi input to the voltage converter Kv and the comparison amplifier COM2 is removed in the embodiment of FIG. 1, and another voltage converter Kr is applied. 1, the same components as those of the embodiment of FIG. 1 are denoted by the same reference numerals, and redundant descriptions and operations of the same components will be omitted.

FIG. 4 corresponds to setting the gain factor of the voltage converter Kv of the embodiment of FIG. 1 to '1'.

In addition, in FIG. 4, the other voltage converter Kr is configured with a gain factor for differently setting the feedback resistance voltage division ratio in order to provide a stable padback path corresponding to overvoltage.

As described above, even when the overvoltage protection corresponding to the overvoltage of the output voltage of the DC-DC converter is performed, the output voltage and the input voltage can be stabilized, thereby ensuring reliability.

10: voltage conversion circuit 12: controller
14: RS flip flop

Claims (22)

In the voltage conversion circuit of a switching DC-DC converter for controlling the switching of the input voltage to the output voltage by driving switching,
A switching circuit for performing the switching driving to drive the input voltage by a driving pulse;
A pulse generation circuit for providing the drive pulse at a pulse width corresponding to a drive voltage; And
A feedback path providing a driving voltage by feeding back an output voltage, and selecting and comparing a first feedback voltage and a first reference voltage when the output voltage corresponds to a normal mode to provide the driving voltage. Providing a path to the feedback path, and when the output voltage corresponds to an overvoltage mode, selecting and comparing a second feedback voltage and a second reference voltage of a constant voltage to provide the driving voltage as the feedback path. Including a feedback circuit;
The first feedback voltage and the second feedback voltage are voltages obtained by dividing the output voltage.
The second feedback voltage is lower than the first feedback voltage,
And the second reference voltage is lower than the first reference voltage. The method of claim 1, wherein the feedback circuit,
A feedback voltage providing circuit configured to provide a first feedback voltage as a feedback voltage in response to the normal mode and provide the second feedback voltage as the feedback voltage in response to the overvoltage mode by mode determination;
A reference voltage providing circuit configured to provide a first reference voltage as a reference voltage in response to the normal mode and provide the second reference voltage as the reference voltage in response to the overvoltage mode;
An error amplifier comparing the feedback voltage with the reference voltage to provide the driving voltage; And
Providing the feedback voltage by comparing the first feedback voltage and the first reference voltage to detect entering the normal mode and comparing the second feedback voltage and the second reference voltage to enter the overvoltage mode. And a mode determination unit controlling the mode determination of the circuit and the reference voltage providing circuit.
The method of claim 2,
And at least one of a voltage converter for adjusting a voltage range of the first reference voltage and a voltage divider for dividing the output voltage to provide the second feedback voltage.
The method of claim 2, wherein the mode determination unit,
A first comparison amplifier configured to output a normal flag indicating to enter the normal mode when a difference between the first feedback voltage and the first reference voltage is equal to or greater than a first offset value preset;
A second comparison amplifier configured to output an overvoltage flag indicating to enter the overvoltage mode when the difference between the second feedback voltage and the second reference voltage is equal to or greater than a preset second offset value; And
And a mode signal output unit configured to output a mode signal for determining the mode by using the normal flag and the overvoltage flag.
The method of claim 4, wherein
And the first comparison amplifier and the second comparison amplifier have hysteresis characteristics.
The method of claim 4, wherein
And a delay circuit for delaying the normal flag of the first comparison amplifier and providing the delayed signal to the mode signal output unit.
The method of claim 6,
The delay circuit is a voltage conversion circuit of a switching DC-DC converter composed of a low pass filter.
The method of claim 4, wherein the mode signal output unit,
And an RS flip-flop configured to receive the overvoltage flag as a set signal and output the mode signal by receiving the normal flag signal as a reset signal.
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