KR101379375B1 - Mode selectable dc-dc converter apparatus of dual output type - Google Patents

Abstract

A dual output type DC-DC converter device comprises: a mode control unit which selects either one of a dual inductor mode or a signal inductor mode according to a mode setting value; a first PWM control unit which generates a first PWM control signal for a boost operation under the control of the mode control unit; a second PWM control unit which generates a second PWM control signal for a buck-boost operation under the control of the mode control unit; a switching unit which controls the supply of input power by the first and the second PWM control signals; and an output unit which is connected to the switching unit. The mode control unit differently controls the operation state of the first and the second PWM control units by mode. Therefore, the dual output type DC-DC converter device selectively uses dual/single inductor structures with a single device, flexibly handles according to the need of a designer, a loading condition, and a situational change, and can easily satisfy characteristics such as performance, size, costs, and expandability, which are considered to be important for different uses. [Reference numerals] (110) Mode control unit; (121,122) PWM control unit

Description

Mode selectable dual output type DC-DC converter device {MODE SELECTABLE DC-DC CONVERTER APPARATUS OF DUAL OUTPUT TYPE}

The present invention relates to a DC-DC converter device, and more particularly, to a dual output type DC-DC converter device for generating a positive voltage and a negative voltage.

The dual output DC-DC converter is a power supply that converts DC input power into two polarity output voltages. For example, the liquid crystal display panel drives a gate line by generating a positive voltage and a negative voltage through a dual output DC-DC converter device.

1 and 2 are schematic configuration diagrams of a general dual output DC-DC converter device.

Typical structures of a dual output DC-DC converter device for implementing dual outputs of positive and negative voltages include a dual inductor structure (see FIG. 1) and a single inductor structure (see FIG. 2).

The dual inductor structure is configured to include a boost topology as shown in FIG. 1A and a buck-boost topology as shown in FIG. 1B.

This dual inductor structure uses two inductors 10 and 20, driving one inductor 10 through a boost topology to supply a positive voltage (e.g. 4 to 6V) and the other through a buck-boost topology. The inductor 20 is driven to supply a negative voltage (for example, -4 to -6V).

In comparison, the single inductor structure illustrated in FIG. 2 removes the two inductors 10 and 20 described above in the structure of FIG. 1, and then arranges one inductor 30 between two nodes N1 and N2. Two output terminals (DDVDH, DDVDL) allow two output voltages.

As a similar example, US Patent No. 8,232,790 described in Patent Document 1 describes a dual output regulator having a single inductor structure.

Applying the dual inductor structure has the advantage of achieving the most stable and maximum efficiency and performance. However, the use of two inductors increases the number of external components and increases the mounting area.

In the case of the single inductor structure, only one inductor is used, which reduces the number of external components, reduces the mounting area, and lowers the manufacturing cost, thereby increasing productivity, and is weaker than the dual inductor structure in terms of stability, performance, and efficiency.

As such, the dual / single inductor structure described above has its advantages and disadvantages.

However, since the conventional dual inductor structure or the single inductor structure is implemented exclusively as different devices, it is difficult to flexibly cope with the needs of various designers, mounting conditions, usage environments, etc., and in terms of performance, size, cost, scalability, etc. Among the elements of the problem is that it is difficult to easily satisfy the characteristics that are important for each use.

U.S. Patent No. 8,232,790, Designation: Architecture For Controlling A Dual Polarity, Single Inductor Boost Regulator Used As A Dual Polarity Supply In A Hard Disk Drive Dual Stage Actuator (DSA) Device

The present invention has been proposed to solve the problems of the prior art as described above, and proposes an effective configuration that enables the selective use of the dual / single inductor structure, and is therefore flexible according to the designer's needs, mounting conditions, and usage environment. The purpose of the present invention is to provide a dual output DC-DC converter device that can easily cope with, and can easily satisfy characteristics that are important for each application among factors such as performance, size, cost, and scalability in application.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the precise form disclosed. There will be.

A dual output DC-DC converter device according to the present invention for achieving the above object, the mode control unit for selecting any one of the dual inductor mode or single inductor mode according to the mode setting value; A first PWM controller generating a first PWM control signal for a boost operation of generating a positive voltage from an input power under the control of the mode controller; A second PWM controller configured to generate a second PWM control signal for a buck-boost operation to generate a negative voltage from an input power under the control of the mode controller; A switching unit connected to the first PWM control unit and the second PWM control unit to control switching of input power by switching by a first PWM control signal and a second PWM control signal; And an output connected to the switching unit. Here, the mode controller controls the operation states of the first PWM controller and the second PWM controller differently for each mode.

In the dual inductor mode, the mode control unit activates the first PWM control unit and the second PWM control unit together in parallel driving, and in the single inductor mode, the first PWM control unit and the second PWM control unit alternately activate the time division driving. It can be configured to.

The mode controller outputs a boost set signal for controlling whether the first PWM controller is activated and a buck-boost set signal for controlling whether the second PWM controller is activated according to the selected mode, but in the dual inductor mode, the boost set signal is output. The signal and the buck-boost set signal may be output in the form of two synchronized clock pulses, and in the single inductor mode, the boost set signal and the buck-boost set signal may be output in the form of two phase shifted clock pulses.

The mode controller outputs a boost set signal and a buck-boost set signal having the same frequency and phase in the dual inductor mode for each first period, and in the single inductor mode, the boost set signal and the buck having the 180 ° phase difference in the same frequency. The boost set signal may be configured to be output every second period, wherein the second period may have a value twice as long as the first period.

When the mode control unit is set to the dual inductor mode, the dual output DC-DC converter device according to the present invention includes a first inductor connected between an input power source and a first node of the switching unit, a second node of the switching unit, and a ground. It may further include a second inductor connected therebetween. In this case, the first PWM controller may drive the first inductor in an activated state, and the second PWM controller may drive the second inductor in an activated state to implement dual output using two inductors.

When the mode control unit is set to the single inductor mode, the dual output DC-DC converter device according to the present invention may further include a common inductor connected between the first node and the second node of the switching unit. In this case, the first PWM control unit and the second PWM control unit may be alternately activated to drive the common inductor to implement dual output using one inductor.

The mode controller may be configured to be set to the single inductor mode when the mode setting value is high, and to the dual inductor mode when the mode setting value is low.

According to the dual output DC-DC converter device of the present invention, it is possible to select and use dual / single inductor structure as a single device, thereby flexibly coping with the designer's needs, mounting conditions, and situational changes. As a result, it is possible to easily satisfy characteristics that are important for each use among factors such as performance, size, cost, and scalability.

1 and 2 are schematic configuration diagrams of a general dual output DC-DC converter device.
Figure 3 is a schematic diagram of a mode selectable dual output type DC-DC converter device according to an embodiment of the present invention.
4 is an exemplary use state diagram when the dual output DC-DC converter device of FIG. 3 is set to the dual inductor mode.
5 is an exemplary use state diagram when the dual output DC-DC converter device of FIG. 3 is set to the single inductor mode.
FIG. 6 is an exemplary waveform diagram when the dual output DC-DC converter device of FIG. 3 operates in dual inductor mode. FIG.
FIG. 7 is an exemplary waveform diagram when the dual output DC-DC converter device of FIG. 3 operates in single inductor mode. FIG.

Hereinafter, with reference to the accompanying drawings will be described in detail the mode selectable dual output type DC-DC converter device according to an embodiment of the present invention.

3 is a schematic configuration diagram of a mode selectable dual output type DC-DC converter device according to an embodiment of the present invention.

Referring to FIG. 3, a dual output type DC-DC converter device according to an embodiment of the present invention includes a mode controller 110, a first pulse width modulation (PWM) controller 121, a second PWM controller 122, It includes a switching unit (131, 132), and an output unit (141, 142), it is configured to support both a dual inductor structure and a single inductor structure is possible to select and use the desired structure as needed.

The designer selects the dual inductor mode or the single inductor mode by the mode control unit 110, and uses two inductors L1 and L2 according to the selected mode, or one common inductor L. have.

Inductors L, L1, and L2 are not installed in an initial state so that a desired one of the dual / single inductor modes may be adopted.

For example, when the characteristics such as stability and high performance are more important, the designer installs two inductors L1 and L2 to perform the boost operation and the buck-boost operation as separate inductors, respectively. Can be used as On the other hand, when miniaturization or cost reduction is more important, the designer may install only one inductor L instead of two inductors L1 and L2 to perform the boost operation and the buck-boost operation with one shared inductor. The device in 3 is available in a single inductor structure.

The mode controller 110 selectively sets one of the dual inductor mode and the single inductor mode according to the mode setting value.

In one embodiment, the mode may be determined according to the mode setting value of the external selection pin (SIMO). For example, if the selection pin SIMO is connected to an input power source and the mode setting becomes high, the device of FIG. 3 operates in single inductor mode. When the select pin (SIMO) is connected to ground (GND) and the mode setting is low, the device of Figure 3 operates in dual inductor mode.

The first PWM controller 121 generates a first PWM control signal for a boost operation for generating a positive voltage of positive polarity from the input power under the control of the mode controller 110 and outputs the first PWM control signal to the first switching unit 131. do.

The second PWM controller 122 generates a second PWM control signal for the buck-boost operation of generating a negative voltage having a negative polarity from the input power under the control of the mode controller 110. Will output

The switching units 131 and 132 are connected to the first PWM control unit 121 and the second PWM control unit 122 and are switched by the first PWM control signal and the second PWM control signal output therefrom to supply the input power. To control. The switching units 131 and 132 are connected to the first PWM control unit 121 to control the supply of input power, and are connected to the second PWM control unit 122 to control the supply of input power. The second switching unit 132 is included.

In an embodiment, the switching elements S1 to S4 constituting the switching units 131 and 132 are illustrated as MOSFETs.

The first switching unit 131 is a third switching device S3 connected to the ground at the first node SW_P, and a fourth switching device S4 connected between the first node SW_P and the high side output terminal OUT_P. It includes. The second switching unit 132 includes a first switching device S1 connected between the input terminal PVIN and the second node SW_N, and a second switching connected between the second node SW_N and the low side output terminal OUT_N. An element S2 is included.

The switching elements S3 and S4 of the first switching unit 131 are on-off by the first PWM control signal output from the first PWM controller 121 to perform a boost operation for the positive voltage output. The switching elements S1 and S2 of the second switching unit 132 are turned on and off by a second PWM control signal output from the second PWM controller 122 to perform a buck-boost operation for negative voltage output. do.

In the boost operation, after the third switching device S3 is turned on to charge the inductor L1 or L as a charging switching device, the fourth switching device S4 operates as an output switching device so that the inductor L1 or L The output voltage is boosted by adding the discharged voltage at the output side to the high output terminal OUT_P.

In the buck-boost operation, the first switching element S1 operates as a charging switching element to charge the inductor L2 or L, and then the second switching element S2 is turned on to output the inductor L2 as an output switching element. Alternatively, L) is discharged to reduce the output voltage of the low output terminal OUT_N.

The output units 141 and 142 may include a first output unit 141 including a first output capacitor C1 connected between a high side output terminal OUT_P for a positive voltage output and a ground, and a low output terminal for a negative voltage output. And a second output unit 142 including a second output capacitor C2 connected between OUT_N and ground.

The first output unit 141 is connected to the first switching unit 131 and outputs a positive voltage boosted by the input power supplied by the first switching unit 131 to the high output terminal OUT_P. The second output unit 142 is connected to the second switching unit 132 and outputs a negative voltage obtained by depressurizing the input power supplied by the second switching unit 132 to the low output terminal OUT_N.

In such a configuration, the mode controller 110 controls the operation states of the first PWM controller 121 and the second PWM controller 122 differently according to the selected mode.

First, the mode controller 110 is set to the dual inductor mode, the first inductor L1 is connected between the input power supply and the first node SW_P of the switching units 131 and 132, and the second inductor L2. Is connected between the second node SW_N of the switching units 131 and 132 and ground, the first PWM controller 121 and the second PWM controller 122 separately drive the two inductors L1 and L2 in parallel. To perform a first operation of generating dual outputs of positive and negative voltages.

In the dual inductor mode, two inductors L1 and L2 are provided, so there is no need to share a single inductor during the boost operation and the buck-boost operation. Therefore, the mode controller 110 periodically activates the first PWM controller 121 and the second PWM controller 122 together and drives them in parallel. The first PWM controller 121 generates a positive voltage by driving the first inductor L1 in an activated state to perform a boost operation, and the second PWM controller 122 drives the second inductor L2 in an activated state. By performing a buck-boost operation to generate a negative voltage, dual outputs using two inductors (L1, L2) are realized.

Meanwhile, the mode control unit 110 is set to the single inductor mode, and the common inductor L replaces the two inductors L1 and L2 so that the first node SW_P and the second node of the switching units 131 and 132 ( When connected between SW_N), the first PWM controller 121 and the second PWM controller 122 time-divisionally drive one common inductor L to perform a second operation of generating dual outputs of positive and negative voltages. do.

In the single inductor mode, a single inductor must be shared to perform a boost operation and a buck-boost operation. Therefore, the mode controller 110 divides one period into a first section and a second section to form a first inductor. By assigning each section to the two PWM control sections 122, time-division driving for alternately activating the two PWM control sections 121 and 122 is realized for each section.

The first PWM control unit 121 and the second PWM control unit 122 are alternately activated and share a common inductor L to perform a boost operation and a buck-boost operation in sequence for one period, thereby dual output using one inductor. Will be implemented.

In addition, although not shown, an anti-ringing control circuit for reducing inductor ringing, a feedback control circuit for stabilizing the output voltage, an overcurrent protection circuit, and a shutdown control circuit for completely discharging the output in shutdown are provided. Additional functions may optionally be grafted according to embodiments.

4 is an exemplary use state diagram when the dual output DC-DC converter device of FIG. 3 is set to the dual inductor mode.

The designer may select the dual inductor mode by setting the selection pin SIMO of the mode controller 110 to a low level. As described above, the first inductor L1 is externally connected so as to be connected in series between the input power source VBAT and the first node SW_P of the switching units 131 and 132, and the second inductor L2 is connected to the switching unit ( It is externally connected to be connected between the second node SW_N of the first and second terminals 131 and 132.

FIG. 5 is an exemplary use state diagram when the dual output DC-DC converter device of FIG. 3 is set to the single inductor mode.

The designer may select the single inductor mode by connecting the selection pin SIMO of the mode controller 110 to the input power VBAT and setting it high. As described above, the common inductor L is sheathed so as to be connected in series between the first node SW_P and the second node SW_N of the switching units 131 and 132.

FIG. 6 is an exemplary waveform diagram when the dual output DC-DC converter device of FIG. 3 operates in the dual inductor mode.

According to an embodiment, the mode controller 110 controls the activation of the first PWM controller 121 and the boost set signal SET_P and the second PWM controller 122 according to a selected mode among the dual / single inductor modes. The buck-boost set signal SET_N for controlling whether to activate is outputted.

In the dual inductor mode, the boost set signal SET_P and the buck-boost set signal SET_N may be generated in the form of two clock pulses synchronized. In an exemplary embodiment, as shown in FIG. 6, the mode controller 110 outputs the boost set signal SET_P and the buck-boost set signal SET_N having the same frequency and phase for each first period T1.

When the boost set signal SET_P outputs high, the first PWM controller 121 outputs the first PWM control signal PWM_Boost for the boost operation in response to the switching elements of the first switch 131. S3, S4) are operated on-off.

In this case, a boost operation during one period T1 is described using a change in the inductor current IL_Boost flowing in the first inductor L1 as follows.

In the boost operation, the inductor current IL_Boost flows into the first inductor L1 during the on time of the third switching device S3 to charge the electric energy. Thereafter, when the third switching device S3 is turned off, the electric energy charged in the first inductor L1 is transferred to the load through the fourth switching device S4, and the positive voltage higher than the input power is supplied to the high side output terminal OUT_P. Is output. Thereafter, in order to reduce switching loss by zero current switching, both the third switching device S3 and the fourth switching device S4 are turned off.

In the dual inductor mode, the second inductor L2 is also driven during the period T1 in which the first inductor L1 is driven to perform a buck-boost operation.

When the buck-boost set signal SET_N having the same frequency and phase as the boost set signal SET_P outputs high, the second PWM controller 122 responds with a second PWM control signal for buck-boost operation. PWM_BuckBoost) is output. The switching elements S1 and S2 of the second switching unit 132 are turned on and off according to the second PWM control signal PWM_BuckBoost to output a negative voltage lower than the input power to the low output terminal OUT_N. do.

FIG. 7 is an exemplary waveform diagram when the dual output DC-DC converter device of FIG. 3 operates in the single inductor mode.

In the single inductor mode, the mode control unit 110 divides one cycle T2 into two sections T21 and T22 to alternately activate the first PWM controller 121 and the second PWM controller 122 for each section. The signal SET_P and the buck-boost set signal SET_N may be output in the form of two phase shifted clock pulses.

In an exemplary embodiment, as shown in FIG. 7, the mode controller 110 generates a boost set signal SET_P and a buck-boost set signal SET_N having the same frequency but having a 180 ° phase difference for each second period T2. Output At this time, the boost period and the buck-boost operation should be alternately performed with one common inductor L during one period T2, so that the second period T2 is 2 than the first period T in the dual inductor mode. The ship will be longer.

The boost set signal SET_P is output high in the first section T21 to activate the first PWM controller 121, and the buck-boost set signal SET_N is output high in the second section T22. 2 PWM controller 122 is activated.

According to the boost set signal SET_P and the buck-boost set signal SET_N, the first PWM control signal PWM_Boost, the second PWM control signal PWM_BuckBoost, and the buck during the first period T21 for the boost operation. To illustrate the change of the first PWM control signal PWM_Boost, the second PWM control signal PWM_BuckBoost, and the inductor current IL_SIMO flowing through the common inductor L during the second period T22 for the boost operation, Same as FIG. 7.

The configuration of the mode-selectable dual output type DC-DC converter device according to the present invention is not limited to the above-described embodiments, and may be modified in various ways within the scope of the technical idea of the present invention.

110: mode control unit
121, 122: PWM control
131, 132: switching unit
141, 142: output unit
L, L1, L2: Inductors

Claims (7)

A mode controller configured to select one of the dual inductor mode and the single inductor mode according to the mode setting value;
A first PWM controller generating a first PWM control signal for a boost operation of generating a positive voltage from an input power under the control of the mode controller;
A second PWM controller configured to generate a second PWM control signal for a buck-boost operation to generate a negative voltage from an input power under the control of the mode controller;
A switching unit connected to the first PWM control unit and the second PWM control unit to control switching of input power by switching by a first PWM control signal and a second PWM control signal; And
Including an output connected to the switching unit,
The mode control unit is a dual output type DC-DC converter, characterized in that for controlling the operation state of the first PWM control unit and the second PWM control unit for each mode.
The method of claim 1, wherein the mode control unit,
In the dual inductor mode, the first PWM control unit and the second PWM control unit are activated together in parallel driving, and in the single inductor mode, the first PWM control unit and the second PWM control unit are alternately activated to time-division drive. Dual output DC-DC converter device.
The method of claim 1, wherein the mode control unit,
A boost set signal for controlling whether the first PWM controller is activated and a buck-boost set signal for controlling the activation of the second PWM controller are output according to the selected mode. In the dual inductor mode, a boost set signal and a buck-boost signal are output. And outputting the set signal in the form of two synchronized clock pulses, and outputting the boost set signal and the buck-boost set signal in the form of two phase shifted clock pulses in the single inductor mode.
The method of claim 3, wherein the mode control unit,
In the dual inductor mode, a boost set signal and a buck-boost set signal having the same frequency and phase are output for each first period.In the single inductor mode, a boost set signal and a buck-boost set signal having the same frequency but having a 180 ° phase difference are output. And outputting every second period, wherein the second period is twice as long as the first period.
The method of claim 1,
The mode control unit is set to the dual inductor mode,
A first inductor connected between an input power source and a first node of the switching unit, and a second inductor connected between a second node of the switching unit and ground;
Wherein the first PWM controller drives the first inductor in an activated state, and the second PWM controller drives the second inductor in an activated state, thereby implementing dual output using two inductors. Type DC-DC converter device.
The method of claim 1,
The mode control unit is set to the single inductor mode,
Further comprising a common inductor connected between the first node and the second node of the switching unit,
And the first PWM controller and the second PWM controller are alternately activated to drive the common inductor to implement dual output using one inductor.
The method of claim 1, wherein the mode control unit,
The dual output type DC-DC converter device is set to the single inductor mode when the mode setting value is high, and set to the dual inductor mode when the mode setting value is low.

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