KR102428555B1 - Dc-dc converting apparatus for fast wake-up in electronic device and operation method thereof - Google Patents

Abstract

An embodiment of the present invention provides a DC-DC converter for high-speed wake-up of an electronic device and an operating method thereof. A DC-DC converter according to an embodiment of the present invention includes a buck converter circuit for outputting an output DC voltage of a level lower than an input DC voltage to an output terminal, and a buck converter circuit when the state of the buck converter circuit is an operation mode. a first reference voltage supply unit for supplying one reference voltage to the buck converter circuit; and a second reference voltage supply unit designed to operate with a lower power than that of the first reference voltage supply unit; and a second reference voltage supply unit for supplying a voltage to the output terminal. According to an embodiment of the present invention, a high-speed wake-up of the DC-DC converter is possible by maintaining a predetermined level of voltage at the output terminal using a low current when the DC-DC converter is in the standby mode.

Description

DC-DC CONVERTING APPARATUS FOR FAST WAKE-UP IN ELECTRONIC DEVICE AND OPERATION METHOD THEREOF

The present invention relates to a DC-DC converter for high-speed wake-up of an electronic device and a method for operating the same It relates to a device and a method of operating a DC-DC converter.

On the other hand, the present invention is derived from research conducted as part of the WC300 project technology development support project of the Ministry of Trade, Industry and Energy and the Korea Institute of Industrial Technology Promotion [task management number: S2435123, task name: 55nm or less for smart home and Internet of Things services Development and development of ultra-low-power Smart MCU platform using low-voltage circuit technology of 0.6V or less].

Recently, with the development of portable devices, battery usage time and low-power and high-speed wake-up time have become major issues. Recently, devices using portable batteries require optimizing power consumption for normal operation and optimizing power consumption for standby operation, and also require a high-speed wake-up time when returning from standby operation to normal operation. Accordingly, a DC-DC converter suitable for a sub-micron process and having high efficiency is used in order to optimize power consumption during normal operation.

In the case of the DC-DC converter, since power consumption is relatively large, it is not used in the standby operation period to increase the total battery usage time. However, when the DC-DC converter transitions to the wake-up operation after the standby operation, the settling time of the Bandgap Reference (BGR) circuit and the Low Dropout (LDO) circuit used inside the DC-DC converter ( settling time) or a settling time of the DC-DC converter, there is a problem that the time for wake-up becomes long.

Accordingly, in the normal operation section, the DC-DC converter is used to maximize voltage efficiency, and in the standby operation, the DC-DC converter is turned off to operate at low power, and a fast wake-up time is obtained when returning to the normal operation from the standby operation. There is a need for a method and apparatus having

The present invention was devised to solve the above problems, and the embodiment of the present invention maximizes voltage efficiency by using a DC-DC converter in the normal operation section, and turns off the DC-DC converter in standby operation to reduce power consumption. Provided are a DC-DC converter for high-speed wake-up of an electronic device having a fast wake-up time when returning to a normal operation from a standby operation while operating as a DC-DC converter and an operating method thereof.

The problems to be solved of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

A DC-DC converter for high-speed wake-up according to an embodiment of the present invention includes a buck converter circuit that outputs an output DC voltage of a lower level than an input DC voltage to an output terminal, and the state of the buck converter circuit a first reference voltage supply unit for supplying a first reference voltage to the buck converter circuit when is in the operation mode and a second reference voltage supply unit for supplying a second reference voltage to the output terminal to the output terminal.

In an embodiment, the DC-DC converter may further include a reference voltage switch that outputs one of the first reference voltage or the second reference voltage as a reference voltage based on a regulator enable signal.

In one embodiment, the DC-DC converter includes a controller outputting the regulator enable signal and a switch enable signal based on a standby mode signal indicating that the state of the buck converter circuit is a standby mode, and the regulator in The apparatus may further include a regulator that down-converts the reference voltage to output an output voltage based on an enable signal, and a retention switch that outputs the output voltage to the output terminal based on a switch enable signal.

In one embodiment, when the buck converter circuit is switched to the standby mode, the controller turns on the high-speed wakeup regulator enable signal at a first timing, and a first continuous mode standby period from the first timing At a subsequent second timing, the high-speed wake-up switch enable signal may be turned on.

In one embodiment, the controller, when the state of the buck converter circuit is switched from the standby mode to the operation mode, the standby mode signal is turned off from a third timing after the second continuous mode standby period fourth The switch enable signal and the regulator enable signal may be turned off at timing.

In one embodiment, when the state of the buck converter circuit is switched from the standby mode to the operation mode, the controller constants the regulator enable signal FW_REG_EN at a first timing when the voltage of the output terminal is less than or equal to a reference value It may be turned on for a period of time, and the switch enable signal may be turned on for a predetermined time at a second timing after the discontinuous mode standby period from the first timing.

In one embodiment, when the state of the buck converter circuit is switched from the standby mode to the operation mode, the controller turns on the regulator enable signal for a predetermined time at the rising timing of the clock signal, and the rising timing At a second timing after the switching mode standby period, the switch enable signal may be turned on for a predetermined time.

The method of operating a DC-DC converter for high-speed wake-up of an electronic device according to an embodiment of the present invention outputs an output DC voltage of a lower level than an input DC voltage input to a buck converter circuit to an output terminal. and supplying a first reference voltage output from a first reference voltage supply unit to the buck converter when the state of the buck converter circuit is in an operation mode, and when the state of the buck converter circuit is in a standby mode and supplying a second reference voltage output from a second reference voltage supply unit designed to operate at a power lower than that of one reference voltage supply unit to the output terminal.

In an embodiment, the supplying of the first reference voltage to the buck converter may include outputting the first reference voltage output from the first reference voltage supply unit as a reference voltage by turning off a regulator enable signal. may include.

In an embodiment, the step of supplying the second reference voltage to the output terminal includes outputting the second reference voltage output from the second reference voltage supply unit as a reference voltage by turning on a regulator enable signal. may include

In one embodiment, the supplying of the second reference voltage to the output terminal comprises outputting the regulator enable signal and the switch enable signal based on a standby mode signal indicating that the state of the buck converter circuit is a standby mode. The method may include converting the reference voltage to output an output voltage based on the regulator enable signal, and outputting the output voltage to the output terminal based on a switch enable signal.

In an embodiment, the outputting of the regulator enable signal and the switch enable signal FW_SW_EN may include turning on the regulator enable signal at a first timing when the buck converter circuit is switched to the standby mode. and turning on the switch enable signal at a second timing after the first continuous mode standby period from the first timing.

In an embodiment, the outputting of the regulator enable signal and the switch enable signal FW_SW_EN may include, when the state of the buck converter circuit is switched from the standby mode to the operation mode, the standby mode signal turns- The method may further include turning off the switch enable signal and the regulator enable signal at a fourth timing after the second continuous mode standby period from the third timing to be turned off.

In one embodiment, the outputting of the regulator enable signal and the switch enable signal may include, when the state of the buck converter circuit is switched from the standby mode to the operation mode, the voltage of the output terminal is less than or equal to a reference value. turning on the regulator enable signal for a predetermined time at one timing, and turning on the switch enable signal FW_SW_EN for a predetermined time at a second timing after the discontinuous mode standby period from the first timing may include steps.

In an embodiment, the outputting of the regulator enable signal and the switch enable signal may include enabling the regulator at a rising timing of a clock signal when the state of the buck converter circuit is switched from the standby mode to the operation mode. It may include turning on the signal for a predetermined time, and turning on the switch enable signal for a predetermined time at a second timing after the switching mode standby period from the rising timing.

A DC-DC converter for high-speed wake-up of an electronic device according to another embodiment of the present invention includes a power supply for supplying an input DC voltage, a first switch connected to the power supply, and a second switch connected to the first switch a switch, an inductor connected to a terminal between the first switch and the second switch, a capacitor connected to the other end of the inductor, and a switching signal generator configured to output a switching signal to the first switch and the second switch; a first reference voltage supply unit for supplying a first reference voltage to the switching signal generator when the current mode is an operation mode a second reference voltage supply unit for supplying a second reference voltage to the output terminal, and a reference voltage switch for outputting one of the first reference voltage BGR_OUT and the second reference voltage as a reference voltage based on a regulator enable signal may include.

According to an embodiment of the present invention, a high-speed wake-up of the DC-DC converter is possible by maintaining a predetermined level of voltage at the output terminal using a low current when the DC-DC converter is in the standby mode.

Effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a diagram showing an example of a conventional DC-DC converter.
2 is a diagram illustrating a low-power high-speed wake-up DC-DC converter according to an embodiment of the present invention.
3 is a timing diagram illustrating an operation of a conventional DC-DC converter.
4 is a timing diagram illustrating a continuous mode operation of a DC-DC converter for high-speed wake-up according to an embodiment of the present invention.
5 is a timing diagram illustrating a discontinuous mode operation of a DC-DC converter for high-speed wake-up according to an embodiment of the present invention.
6 is a timing diagram illustrating a switching mode operation of a DC-DC converter for high-speed wake-up according to an embodiment of the present invention.
7 is a flowchart illustrating an example of a method of operating a low-power high-speed wake-up DC-DC converter according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar elements throughout the specification.

In addition, in various embodiments, components having the same configuration will be described using the same reference numerals only in the representative embodiment, and only configurations different from the representative embodiment will be described in other embodiments.

Throughout the specification, when a part is "connected (or coupled)" with another part, it is not only "directly connected (or coupled)" but also "indirectly connected (or connected)" with another member therebetween. combined)" is also included. In addition, when a part "includes" a certain component, this means that other components may be further included, rather than excluding other components, unless otherwise stated.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

1 is a diagram showing an example of a conventional DC-DC converter. Referring to FIG. 1 , an input DC voltage VBAT is supplied from a power source, and an output voltage BUCK_OUT (output DC voltage) of a level lower than the input DC voltage is output to the output terminal. More specifically, the conventional DC-DC converter includes a buck converter circuit (or DC-DC buck converter) 100 , a band gap reference (BGR) circuit 105 providing a reference voltage, and the BGR and a low drop-out (LDO) circuit 110 for down-converting the reference voltage provided from the circuit and outputting it to the buck converter circuit 100 .

The schematic operation of the buck converter circuit 100 is as follows. The first switch PMOS1 is turned on during a first switching period in one switching period by the first switching signal HIGH_S, and is turned off during the remaining period of one switching period do. Energy is supplied and stored in the inductor L ₁ from the input DC voltage VBAT provided from the power source during the first switching period in which the first switch PMOS1 is turned on. Here, the first switching signal HISH_S is turned on after the second switching signal LOW_S is turned off.

The second switch NMOS1 is turned on by the second switching period in one switching period by the second switching signal LOW_S, and is turned off during the remaining period of the one switching period. During the period in which the second switch NMOS1 is turned on, the inductor L1 may be electrically connected to the ground terminal VSS. Here, the second switching signal LOW_S is turned on after the first switching signal HISH_S is turned off.

That is, every switching period is a first switching period in which the first switching signal HIGH_S is turned on and the second switching signal LOW_S is turned off, and the first switching signal HIGH_S is turned off and the second switching period is turned off. It may include a second switching period in which the signal LOW_S is turned on, and a common blocking period in which both the first switching signal HIGH_S and the second switching signal LOW_S are turned off. In the buck converter circuit 100, energy is charged from the power source to the inductor L1 in the first switching period of each switching period, the power is cut off in the second switching period, and energy is transferred from the inductor L1 to the capacitor C1 is charged

The buck converter circuit 100 may operate in either a continuous current mode (CCM) or a discontinuous current mode (DCM). The continuous mode is an efficient mode with respect to a high load impedance. The frequency of the switching signal (pulse) applied to the first switch PMOS1 and the second switch NMOS1 is fixed, and the width of the switching signal is adjusted according to the load voltage. . The discontinuous mode is an efficient mode with respect to a low load impedance. The width of the switching signal (pulse) applied to the first switch PMOS1 and the second switch NMOS1 is fixed, and the frequency of the switching signal is adjusted according to the load voltage. . The mode of the buck converter circuit 100 is determined according to the current flowing between the node between the first switch PMOS1 and the second switch NMOS1 and the output terminal, and the current for determining the operation mode is the current sensing block (Current sensing). block). The CCM/DCM controller determines the operation mode of the buck converter circuit 100 from the signal V _SENSE for the measured current and outputs a signal MODE_SEL indicating the operation mode.

One of the signals output from the CCM mode controller PWM or the DCM mode controller PFM by the multiplexer MUX according to the signal MODE_SEL indicating the operation mode of the buck converter circuit 100 is a switching signal may be input to the generator. In the present specification, the switching signal generator is a module that outputs a switching signal to the first switch PMOS1 and the second switch NMOS1, and includes a deadtime generator, a gate driver controller, and a gate driver. driver) and a zero crossing detector (ZCD). Deadtime Generator is a state in which both the first switching signal (HIGH_S) and the second switching signal (LOW_S) are turned on in the pulse signal input from the CCM mode controller (PWM) or the DCM mode controller (PFM) The first dead time pulse PP and the second dead time pulse NN to which the dead time for preventing is reflected are output to the gate driver controller. In consideration of the first dead time pulse (PP), the second dead time pulse (NN), and the zero crossing in which a reverse current occurs at the output terminal when the switching signal is turned off, the gate driver controller is configured for switching. A first driving signal P_DRV and a second driving signal N_DRV are generated. Here, the signal for zero crossing (V _ZCD ) may be provided from the zero crossing detector (ZCD). The first driving signal P_DRV and the second driving signal N_DRV provided from the gate driver controller are transmitted to the first switch PMOS1 and the second switch NMOS1 through the gate driver. The switching signal HISH_S and the second switching signal LOW_S are provided. The gate driver may operate as a buffer and, if necessary, boost the first driving signal P_DRV or the second driving signal N_DRV to use the first switch PMOS1 and the second switch NMOS1. A first switching signal HISH_S and a second switching signal LOW_S may be output.

2 is a diagram illustrating a DC-DC converter for low-power and high-speed wake-up according to an embodiment of the present invention.

Referring to FIG. 2 , the DC-DC converter for high-speed wake-up includes a buck converter circuit 100 and a wake-up circuit 200 for high-speed wake-up of the buck converter circuit 100 . can 1, the buck converter circuit 100 includes a first switch PMOS1, a second switch NMOS1, a capacitor C1, an inductor L1, a continuous mode controller (CCM Mode Controller), and a discontinuous mode controller. (DCM Mode Controller), a deadtime generator (Deadtime Generator), a gate driver controller (Gate Driver Controller), may include a gate driver (Gate Driver). Additionally, an LDO for supplying power to the buck converter circuit 100 is provided.

The high-speed wake-up circuit 200 includes a first reference voltage supply unit BGR (or a first BGR circuit) that supplies a reference voltage (a first reference voltage BGR_OUT) for an operation of a module in the buck converter circuit 100 . ) (205), a second reference voltage supply unit (FW BGR) (or a second BGR circuit) for supplying a reference voltage (a second reference voltage (FW_BGR_OUT)) for high-speed wake-up ( 210 ), a first reference voltage ( BGR_OUT) or the second reference voltage FW_BGR_OUT as the reference voltage REF_OUT, the reference voltage switch Ref. SW 215 and the buck converter circuit 100 according to the mode of the regulator enable signal FW_REG_EN and a controller FW controller 220 outputting a switch enable signal FW_SW_EN, and a regulator FW outputting an output voltage FW_OUT by down-converting the reference voltage REF_OUT based on the regulator enable signal FW_REG_EN. Regulator) 225 and a retention switch (Ret. SW) 230 for outputting the output voltage FW_OUT to the output terminal of the buck converter circuit 100 based on the switch enable signal FW_SW_EN.

According to the present invention, when the state of the buck converter circuit 100 is the operation mode, the first reference voltage BGR_OUT of the first reference voltage supply unit 205 is supplied to the buck converter circuit 100 . When the state of the buck converter circuit 100 is the standby mode, the second reference voltage FW_BGT_OUT of the second voltage supply unit 210 is supplied to the output terminal of the buck converter circuit 100 .

Here, the second voltage supply unit 210 is designed to operate with lower power than the first voltage supply unit 205 . In general, the reference voltage supply unit (BGR circuit) is composed of elements for supplying a constant voltage with respect to temperature. It can be constructed by combining elements having a characteristic that the voltage decreases with temperature. At this time, the performance and power consumption of the BGR circuit have an inverse relationship. In order to increase the performance of the BGR circuit (eg voltage accuracy, uniformity, settling time), many devices and current are required, so the power consumption is low. The performance of the BGR circuit (eg voltage accuracy, uniformity, settling time) deteriorates when a small current is used to increase the power consumption of the BGR circuit and reduce the power consumption of the BGR circuit. Thus, when the state of the buck converter circuit 100 is in the operation mode, the first reference voltage supply unit 205 consuming relatively high power is used to supply an accurate and uniform reference, and the state of the buck converter circuit 100 is used. In the standby mode, the second reference voltage supply unit 210 that outputs a relatively inaccurate and non-uniform second reference voltage but consumes low power may be used. This is because when the state of the buck converter circuit 100 is in the standby mode, it is sufficient if a voltage of a certain level is supplied to the output terminal of the buck converter circuit 100, but does not require that the corresponding output voltage be accurate to a high level.

The reference voltage switch 215 receives the first reference voltage BGR_OUT from the first reference voltage supply 205 or the second reference voltage supply 210 according to the regulator enable signal FW_REG_EN provided from the controller 220 . One of the second reference voltages FW_BGR_OUT is output as the reference voltage REF_OUT. For example, when the regulator enable signal FW_REG_EN is turned off, the first reference voltage BGR_OUT is output as the reference voltage REF_OUT, and when the regulator enable signal FW_REG_EN is turned on, the second reference voltage BGR_OUT is turned on. The reference voltage FW_BGR_OUT is output as the reference voltage REF_OUT.

The controller 220 outputs a control signal for controlling a module in the high-speed wake-up circuit 200 based on a signal related to the buck converter circuit 100 . For example, the controller 220 may include a signal (STAND_BY_MODE) indicating whether the operation state of the buck converter circuit 100 is a standby mode, a power enable signal (DCDC_PEN) of the buck converter circuit 100, and a clock signal 32K CLK), the mode signal FW_MODE instructing the mode of the buck converter circuit 100, and the reference voltage REF_OUT are input to output a regulator enable signal FW_REG_EN and a switch enable signal FW_SW_EN.

The regulator 225 down-converts the reference voltage REF_OUT output from the reference voltage switch 215 based on the regulator enable signal FW_REG_EN to output the output voltage FW_OUT. For example, when the regulator enable signal FW_REG_EN is turned on, the down-converted output voltage FW_OUT is output, and when the regulator enable signal FW_REG_EN is turned off, no voltage is output. The regulator 225 may be configured as an LDO circuit.

The retention switch 230 outputs or blocks the output voltage FW_OUT output from the regulator 225 to the output terminal of the buck converter circuit 100 based on the switch enable signal FW_SW_EN. For example, when the switch enable signal FW_SW_EN is turned on, the output voltage FW_OUT is output to the output terminal of the buck converter circuit 100 , and when the switch enable signal FW_SW_EN is turned off, the output voltage (FW_OUT) is blocked.

As described above, when the state of the buck converter circuit 100 is the standby mode, the fast wake-up circuit 200 uses the regulator enable signal FW_REG_EN and the switch enable signal FW_SW_EN to activate the buck converter circuit ( 100), the voltage of the output terminal can be adjusted. Here, the high-speed wake-up circuit 200 may operate in one of three operation modes. The first is a continuous mode, the second is a discontinuous mode, and the third is a switching mode.

When the buck converter circuit 100 is in the operation mode, the power enable signal DCDC_PEN is turned on, the standby mode signal STAND_BY_MODE is turned off, and when the buck converter circuit 100 is in the standby mode, the power enable signal is (DCDC_PEN) is turned off, and the standby mode signal (STAND_BY_MODE) is turned on.

In the continuous mode, the mode signal (FW_MODE<N:0>) is set to the first bit value corresponding to the continuous mode, and when the operation mode is converted to the standby mode, the regulator enable signal (FW_REG_EN) is turned on. The regulator 225 outputs the down-converted output voltage FW_OUT. After a predetermined time (the first continuous mode standby period), when the switch enable signal FW_SW_EN provided to the retention switch 230 is turned on, the output voltage FW_OUT is output as the output voltage BUCK_OUT of the output terminal. do. The reason that the switch enable signal (FW_SW_EN) is turned on after the second continuous mode standby period is that the retention switch 230 is momentarily cut off so that a high presence occurs in the output terminal from the viewpoint of the regulator 225 . This is to quickly increase the voltage at the output stage by causing the At this time, as the power enable signal DCDC_PEN is turned off, the buck converter circuit 100 is turned off, the voltage output through the buck converter circuit 100 does not occur, and the regulator is turned on. An output voltage is generated at the output terminal of the buck converter circuit 100 through only 225 . By maintaining the output voltage BUCK_OUT through the second reference voltage supply unit 205 , the regulator 225 , and the controller 220 designed with low power, a high-speed wake-up is possible after switching to the operation mode.

When the standby mode is switched to the operation mode, the standby mode signal (STAND_BY_MODE) is turned off, and the switch enable signal (FW_SW_EN) and the regulator enable signal (FW_REG_EN) are also turned-off after a predetermined time (second continuous mode standby period). goes off The reason that the switch enable signal FW_SW_EN and the regulator enable signal FW_REG_EN are turned off after the second continuous mode standby period from the time when the standby mode signal STAND_BY_MODE is turned off is the output terminal of the buck converter circuit 100 . This is to prevent the voltage supply from being cut off. As the power enable signal DCDC_PEN is turned on, a settling time of the buck converter circuit 100 is required for a predetermined time, and after a predetermined time, the switch enable signal FW_SW_EN and the regulator enable signal FW_REG_EN is turned off, high-speed wake-up is possible.

Since the continuous mode operates continuously in the standby mode, power consumption increases compared to the discontinuous mode and the switching mode.

In the discontinuous mode, the mode signal (FW_MODE<N:0>) is set to the second bit value corresponding to the discontinuous mode, and when the operation mode is switched to the standby mode, the output voltage (BUCK_OUT) of the output terminal in the controller 220 When the output voltage BUCK_OUT of the output terminal falls below the reference value by comparing the reference value with the reference value (eg, REF_OUT), the regulator enable signal FW_REG_EN is turned on. As for the switch enable signal FW_SW_EN, after the regulator enable signal FW_REG_EN is turned on, the regulator enable signal FW_REG_EN is turned on after a predetermined time (discontinuous mode standby period). The reason why a certain time (discontinuous mode standby period) exists between the turn-on time of the regulator enable signal FW_REG_EN and the turn-on time of the switch enable signal FW_SW_EN is that after the regulator 225 is turned on This is to quickly increase the output voltage by blocking the retention switch 230 during the settling time of , so that the impedance of the output terminal appears to be very large. When both the regulator enable signal FW_REG_EN and the switch enable signal FW_SW_EN are turned on, the output voltage FW_OUT output through the regulator 225 is output as the output voltage BUCK_OUT of the output terminal. At this time, as the power enable signal DCDC_PEN is turned off, the buck converter circuit 100 is also turned off, and the time during which the regulator enable signal FW_REG_EN and the switch enable signal FW_SW_EN are turned on. A voltage is output to the output terminal through only the regulator 2250, not the buck converter circuit 100. As the output voltage BUCK_OUT is maintained through the second reference voltage supply unit 210 , the regulator 225 , and the controller 220 designed with low power, a high-speed wake-up is possible when the operation mode is switched.

When the buck converter circuit 100 is switched to the operation mode after the standby mode, the standby mode signal STAND_BY_MODE is turned off, and the regulator enable signal FW_SW_EN and the switch enable signal FW_SW_EN are turned off after a predetermined time. becomes Accordingly, while the power enable signal DCDC_PEN is turned on, the buck converter circuit 100 wakes up after a settling time for a predetermined time to operate.

According to the discontinuous mode, since the operation is performed by comparing the output voltage BUCK_OUT and a reference value (eg, the reference voltage REF_OUT) in the standby mode, lower power consumption may be consumed compared to the continuous mode.

In the switching mode, the mode signal FW_MODE<N:0> is set to the third bit value corresponding to the switching mode, and when the operation mode is switched to the standby mode, the regulator enable signal FW_REG_EN is the clock signal 32K CLK) repeats the turn-on and turn-off operations for a certain period of time according to the cycle. Similarly, the switch enable signal FW_SW_EN is turned on after a predetermined time after the regulator enable signal FW_REG_EN according to the clock signal 32K CLK, and is turned off at the same time as the regulator enable signal FW_REG_EN. The reason that a certain time exists between the turn-on times of FW_REG_EN and FW_SW_EN is due to the settling time of the FW Regulator. When both FW_REG_EN and FW_SW_EN are turned on, a voltage is output to the output voltage BUCK_OUT through the FW regulator. At this time, as the power enable signal DCDC_PEN is turned off, the buck converter circuit 100 is turned off. At this time, no voltage is output to the output terminal through the buck converter circuit 100 , and the output of the output terminal through the regulator 225 during a time during which the regulator enable signal FW_REG_EN and the switch enable signal FW_SW_EN are turned on. voltage occurs. By maintaining the output voltage BUCK_OUT through the second reference voltage supply unit 210 , the regulator 225 , and the controller 220 designed for low power, a high-speed wake-up is possible when the operation mode is switched.

When the standby mode is switched to the operation mode, the standby mode signal STAND_BY_MODE is turned off, and after a predetermined time, the regulator enable signal FW_REG_EN and the switch enable signal FW_SW_EN are turned off. Thus, as the power enable signal DCDC_PEN is turned on, a high-speed wake-up is performed after the settling time of the buck converter circuit 100 for a predetermined time. Since the switching mode operates only for a certain period of time even in the standby mode, it can be operated with low power compared to the continuous mode and the discontinuous mode.

3 is a timing diagram illustrating an operation of a conventional DC-DC converter. Referring to Figure 3, when the operation mode (Operation region) is switched to the standby mode (Stand-by region), the buck converter circuit 100 is turned off as the power enable signal (DCDC_PEN) is turned-off, The first switching signal HIGH_S and the second switching signal LOW_S are both turned off, and the output voltage BUCK_OUT gradually decreases due to a leakage current. When the standby mode (Stand-by region) is switched to the operation mode (Operation region), the first switching signal (HIGH_S) and the second switching signal (LOW_S) is turned on and the output voltage (BUCK_OUT) for a certain settling time is will rise In the case of a conventional DC-DC buck converter, a high-speed wake-up operation is difficult because a long settling time is required.

4 is a timing diagram illustrating a continuous mode operation of a DC-DC converter for high-speed wake-up according to an embodiment of the present invention. When the operation mode is switched to the standby mode (Stand-by region) after the operation mode (Stand-by region), as the buck converter circuit 100 is turned off, the power enable signal (DCDC_PEN) is turned off, the first switching signal ( HIGH_S) and the second switching signal LOW_S are turned off, and the standby mode signal STAND_BY_MODE is turned on. The regulator enable signal FW_REG_EN is turned on at the turn-on time of the standby mode signal STAND_BY_MODE, and the switch enable signal FW_SW_EN turns on after a predetermined time (the first continuous mode standby period) Δtc1 - come The first continuous mode standby period Δtc1 may be set in consideration of the settling time of the regulator 225 . When the standby mode (Stand-by region) is switched to the operation mode (Operation region), the standby mode signal (STAND_BY_MODE) is turned off. The regulator enable signal FW_REG_EN and the switch enable signal FW_SW_EN are turned off after a predetermined time (second continuous mode standby period Δtc2). The second continuous mode standby period Δtc2 may be set in consideration of the settling time of the buck converter circuit 100 . Thus, compared to the conventional operation as shown in FIG. 3 , the buck converter circuit 100 can wake-up quickly and operates with low standby power in the standby mode.

5 is a timing diagram illustrating a discontinuous mode operation of a DC-DC converter for high-speed wake-up according to an embodiment of the present invention. When the operation mode is switched to the standby mode (Stand-by region) after the operation mode (Stand-by region), the buck converter circuit 100 is turned off while the power enable signal (DCDC_PEN) is turned off, the first switching signal (HIGH_S) ) and the second switching signal LOW_S are turned off, and the standby mode signal STAND_BY_MODE is turned on. By comparing the output voltage BUCK_OUT and a reference value (eg, REF_OUT) through the controller 220 , when the output voltage BUCK_OUT decreases below the reference value, the regulator enable signal FW_REG_EN is turned on and constant After a time (discontinuous mode standby period) (Δtdc1), the switch enable signal FW_SW_EN is turned on. In this case, the turn-on time of the regulator enable signal FW_REG_EN and the switch enable signal FW_SW_EN is a time in which the operation time of the internal circuit and the additional delay are reflected. When the standby mode is switched from the standby mode to the operation region, the standby mode signal STAND_BY_MODE is turned off, and after a predetermined time Δtdc2, the regulator enable signal FW_REG_EN and the switch enable signal are turned off. (FW_REG_EN) is also turned off. The predetermined time Δtdc2 may be set in consideration of the settling time of the buck converter circuit 100 . Thus, faster wake-up is possible compared to the conventional method. In addition, the high-speed wake-up circuit 200 operating in the discontinuous mode may reduce power consumed in the standby mode and may operate with lower power compared to the continuous mode.

6 is a timing diagram illustrating a switching mode operation of a DC-DC converter for high-speed wake-up according to an embodiment of the present invention. When the operation mode is switched to the standby mode after the operation region, the buck converter circuit 100 is turned off and the power enable signal DCDC_PEN is turned off, and the first switching signal HIGH_S ) and the second switching signal LOW_S are turned off, and the standby mode signal STAND_BY_MODE is turned on.

The regulator enable signal FW_REG_EN is turned on according to the rising edge of the clock signal 32K_CLK through the controller 220, and the switch enable signal FW_SW_EN is turn-on. In this case, the turn-on time of the regulator enable signal FW_REG_EN and the switch enable signal FW_SW_EN is a time in which a predetermined time delay of the internal circuit is reflected. When the standby mode is switched from the standby mode (Stand-by region) to the operation mode (Operation region), the standby mode signal (STAND_BY_MODE) is turned off, and after a predetermined time (Δts2), the switch enable signal (FW_SW_EN) and the regulator enable signal (FW_REG_EN) is also turned off. The predetermined time Δts2 may be set in consideration of the settling time of the buck converter circuit 100 . Thus, faster wake-up is possible compared to the conventional method. In addition, the high-speed wake-up circuit 200 operating in the discontinuous mode may reduce power consumed in the standby mode and may operate with lower power compared to the continuous mode. 6 shows an example of a case in which a clock signal of 32 KHz is applied, but the frequency of the clock signal may be changed according to an embodiment.

7 is a flowchart illustrating an example of a method of operating a low-power high-speed wake-up DC-DC converter according to an embodiment of the present invention. Referring to FIG. 7 , in step S705 , the standby mode signal STAND_BY_MODE is turned on in the controller 220 of the DC-DC converter for low-power and high-speed wake-up. Thereafter, the fast wake-up circuit 200 may operate in a different manner according to the operation mode of the fast wake-up circuit 200 . Steps S710 to S713 indicate an operation method in a continuous mode, operations S720 to S725 indicate an operation method in a discontinuous mode, and operations S730 to S735 indicate an operation method in a switching mode. An operation mode may be determined according to the mode signal FW_MODE<N:0>.

In the case of the continuous mode, the mode signal FW_MODE<N:0> is set to indicate the continuous mode in step S710. In step S711 , the second reference voltage FW_BGR_OUT is output through the regulator 225 while the regulator enable signal FW_REG_EN is turned on. As the regulator enable signal FW_REG_EN is turned on, the second reference voltage FW_BGR_OUT output from the second reference voltage supply unit 210 is input to the regulator 225 through the reference voltage switch 215 . That is, the reference voltage switch 215 outputs the second reference voltage FW_BGR_OUT as the reference voltage REF_OUT. In step S712, the regulator enable signal FW_REG_EN is turned on and after a predetermined time (the first continuous mode standby period), the switch enable signal FW_SW_EN is turned on and the down-converted second reference voltage FW_BGR_OUT It is output as the output voltage BUCK_OUT of the output terminal through the retention switch 230 . In step S713, step S712 is maintained until the standby mode signal STAND_BY_MODE to the controller 220 is turned off.

In the case of the discontinuous mode, the mode signal FW_MODE<N:0> is set to indicate the discontinuous mode in step S720. In step S721 , the controller 220 compares the output voltage BUCK_OUT with a reference value (eg, the reference voltage REF_OUT). When the output voltage BUCK_OUT decreases below the reference value, the regulator enable signal FW_REG_EN is turned on. In step S722 , as the regulator enable signal FW_REG_EN is turned on, the second reference voltage FW_BGR_OUT that is the output of the second reference voltage supply unit 210 is input to the regulator 225 through the reference voltage switch 215 and , the regulator 225 converts the second reference voltage FW_BGR_OUT to output the output voltage FW_OUT. In step S723, the regulator enable signal FW_REG_EN is turned on and after a predetermined time (discontinuous mode standby period), the switch enable signal FW_SW_EN is turned on and the second reference voltage FW_BGR_OUT is changed to the retention switch ( 230) through the output terminal. In step S724, after a predetermined time, the regulator enable signal FW_REG_EN and the switch enable signal FW_SW_EN of the controller 220 are turned off, and the output voltage BUCK_OUT decreases according to the load current. . In step S725 , the controller 220 compares the output voltage BUCK_OUT with a reference value (eg, the reference voltage REF_OUT) and repeats the operation. The repetition is performed until the standby mode signal STAND_BY_MODE is turned off.

In the case of the switching mode, the mode signal FW_MODE<N:0> is set to indicate the switching mode in step S730. In step S731 , the controller 220 turns on the regulator enable signal FW_REG_EN for a predetermined time by receiving the clock signal 32K_CLK as an input. In step S732 , when the regulator enable signal FW_REG_EN is turned on, the second reference voltage FW_BGR_OUT provided from the second reference voltage supply unit 210 is input to the regulator 225 through the reference voltage switch 215 and , the regulator 225 converts the second reference voltage and outputs it as the output voltage FW_OUT. In step S733, the regulator enable signal FW_REG_EN is turned on and after a predetermined time, the switch enable signal FW_SW_EN is turned on and the second reference voltage converted through the retention switch 230 is converted to the output voltage ( BUCK_OUT). In step S734, after a predetermined time, the regulator enable signal FW_REG_EN and the switch enable signal FW_SW_EN are turned off, and the output voltage BUCK_OUT decreases according to the load current. In step S735 , the controller 220 repeatedly performs turn-on and turn-off operations of the regulator enable signal FW_REG_EN and the switch enable signal FW_SW_EN through the clock signal 32K_CLK. This is repeated until the standby mode signal STAND_BY_MODE is turned off.

This embodiment and the drawings attached to this specification merely clearly show some of the technical ideas included in the present invention, and those skilled in the art can easily infer within the scope of the technical ideas included in the specification and drawings of the present invention. It will be apparent that all possible modifications and specific embodiments are included in the scope of the present invention.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the claims to be described later, but also all those with equivalent or equivalent modifications to the claims will be said to belong to the scope of the spirit of the present invention. .

Claims (20)

A DC-DC converter for high-speed wake-up of an electronic device, comprising:
a buck converter circuit that outputs an output DC voltage of a level lower than the input DC voltage to an output stage;
a first reference voltage supply unit for supplying a first reference voltage to the buck converter circuit when the state of the buck converter circuit is an operation mode; and
a second reference voltage supply unit designed to operate with lower power than the first reference voltage supply unit and supplying a second reference voltage to the output terminal when the state of the buck converter circuit is a standby mode;
a reference voltage switch outputting one of the first reference voltage and the second reference voltage as a reference voltage based on a regulator enable signal;
a controller outputting the regulator enable signal and the switch enable signal based on a standby mode signal indicating that the state of the buck converter circuit is a standby mode;
a regulator for outputting an output voltage by down-converting the reference voltage based on the regulator enable signal; and
A retention switch for outputting the output voltage to the output terminal based on a switch enable signal,
When the buck converter circuit is switched to the standby mode, the controller turns on the regulator enable signal at a first timing, and at a second timing after a first continuous mode standby period from the first timing, the switch DC-DC converter, characterized in that it turns on the enable signal.
delete delete delete According to claim 1,
The controller is
When the state of the buck converter circuit is switched from the standby mode to the operation mode, the switch enable signal and the DC-DC converter, characterized in that turning off the regulator enable signal.
According to claim 1,
The controller is
When the state of the buck converter circuit is switched from the standby mode to the operation mode, the regulator enable signal is turned on for a predetermined time at a first timing when the voltage of the output terminal is less than or equal to a reference value;
DC-DC converter according to claim 1, wherein the switch enable signal is turned on for a predetermined time at a second timing after the discontinuous mode standby period from the first timing.
According to claim 1,
The controller is
When the state of the buck converter circuit is switched from the standby mode to the operation mode, the regulator enable signal is turned on for a predetermined time at the rising timing of the clock signal,
DC-DC converter according to claim 1, wherein the switch enable signal is turned on for a predetermined time at a second timing after the switching mode standby period from the rising timing.
A method of operating a DC-DC converter for high-speed wake-up of an electronic device, comprising:
outputting an output DC voltage of a level lower than the input DC voltage input to the buck converter circuit to an output terminal;
supplying a first reference voltage output from a first reference voltage supply unit to the buck converter when the state of the buck converter circuit is an operation mode; and
and supplying a second reference voltage output from a second reference voltage supply unit designed to operate with lower power than the first reference voltage supply unit to the output terminal when the state of the buck converter circuit is a standby mode,
The step of supplying the first reference voltage to the buck converter comprises outputting the first reference voltage output from the first reference voltage supply unit as a reference voltage by turning off a regulator enable signal,
The supplying of the second reference voltage to the output terminal includes outputting the second reference voltage output from the second reference voltage supply unit as a reference voltage by turning on the regulator enable signal,
Outputting the second reference voltage comprises:
outputting the regulator enable signal and the switch enable signal based on a standby mode signal indicating that the state of the buck converter circuit is a standby mode;
converting the reference voltage based on the regulator enable signal to output an output voltage; and
outputting the output voltage to the output terminal based on a switch enable signal;
The step of outputting the regulator enable signal and the switch enable signal comprises:
turning on the regulator enable signal at a first timing when the buck converter circuit is switched to the standby mode; and
and turning on the switch enable signal at a second timing after the first continuous mode standby period from the first timing.
delete delete delete delete 9. The method of claim 8,
The step of outputting the regulator enable signal and the switch enable signal comprises:
When the state of the buck converter circuit is switched from the standby mode to the operation mode, the switch enable signal and the DC-DC converter operating method, characterized in that it further comprises the step of turning off the regulator enable signal.
9. The method of claim 8,
The step of outputting the regulator enable signal and the switch enable signal comprises:
turning on the regulator enable signal for a predetermined time at a first timing when the voltage of the output terminal is less than or equal to a reference value when the state of the buck converter circuit is switched from the standby mode to the operation mode; and
and turning on the switch enable signal for a predetermined time at a second timing after the discontinuous mode standby period from the first timing.
9. The method of claim 8,
The step of outputting the regulator enable signal and the switch enable signal comprises:
turning on the regulator enable signal for a predetermined time at a rising timing of a clock signal when the state of the buck converter circuit is switched from the standby mode to the operation mode; and
and turning on the switch enable signal for a predetermined time at a second timing after the switching mode standby period from the rising timing.
A DC-DC converter for high-speed wake-up of an electronic device, comprising:
a power supply supplying the input DC voltage;
a first switch connected to the power source;
a second switch connected to the first switch;
an inductor connected to a terminal between the first switch and the second switch;
a capacitor connected to the other end of the inductor; and
a switching signal generator outputting a switching signal to the first switch and the second switch;
a first reference voltage supply unit for supplying a first reference voltage to the switching signal generator when the current mode is an operation mode;
a second reference voltage supply unit designed to operate at a lower power than that of the first reference voltage supply unit and supplying a second reference voltage to an output terminal when the current mode is a standby mode;
a reference voltage switch outputting one of the first reference voltage and the second reference voltage as a reference voltage based on a regulator enable signal;
a controller outputting the regulator enable signal and the switch enable signal based on a standby mode signal indicating that the current mode is a standby mode;
a regulator for outputting an output voltage by down-converting the reference voltage based on the regulator enable signal; and
A retention switch for outputting the output voltage to the output terminal based on a switch enable signal,
The controller is
When the current mode is switched to the standby mode, the regulator enable signal is turned on at a first timing, and the switch enable signal is turned on at a second timing after the first continuous mode standby period from the first timing - Bring it on,
When the current mode is switched from the standby mode to the operation mode, the switch enable signal and the regulator enable signal at a fourth timing after a second continuous mode standby period from a third timing at which the standby mode signal is turned off DC-DC converter, characterized in that the signal is turned off.
delete delete 17. The method of claim 16,
When the current mode is switched from the standby mode to the operation mode, the regulator enable signal is turned on for a predetermined time at a first timing when the voltage of the output terminal is less than or equal to a reference value, and the discontinuous mode standby from the first timing DC-DC converter, characterized in that the switch enable signal is turned on for a predetermined time at a second timing after the section.
17. The method of claim 16,
When the current mode is switched from the standby mode to the operation mode, the regulator enable signal is turned on for a predetermined time at the rising timing of the clock signal, and at a second timing after the switching mode standby period from the rising timing. DC-DC converter, characterized in that the switch enable signal is turned on for a predetermined time.

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