KR102382987B1 - Power supply circuit - Google Patents

Abstract

The present invention relates to a power supply circuit in which a switched capacitor converter and a 3-level buck converter are integrated. As a power supply circuit that receives power from an external charger and provides power to a battery and/or electronic device system, one aspect of the present invention is a power supply circuit comprising: a converter selectively operating in either a charge pump mode or a buck mode according to an on/off switching operation of a plurality of transistors, wherein at least a part of the transistors performs a switching operation in both the charge pump mode and the buck mode; and a controller for controlling the switching operations of the transistors. Accordingly, the size and loss of an inductor can be reduced.

Description

Power supply circuit {POWER SUPPLY CIRCUIT}

The present invention relates to a power supply circuit. Specifically, the present invention relates to a power supply circuit in which a switched capacitor converter and a three-level buck converter are integrated.

The power supply circuit may be used as a voltage regulator performing functions such as charging a battery in an electronic device or converting a voltage received from an external charging device.

For example, a device commonly referred to as a power management integrated circuit (PMIC) is included in a mobile electronic device, such as a mobile phone or a tablet, to manage power inside the electronic device. To this end, the power management integrated circuit requires a voltage regulator that performs functions such as battery charging, conversion of voltage received from an external charging device, and power selection. It can be used as a voltage regulator.

Recently, as chargers (TA) for externally charging mobile electronic devices have been diversified, various charging methods such as a method in which the voltage provided by an external charger is fixed, such as 5V or 9V, and a method that can be varied in the range of 3V to 11V or 3V to 20V, etc. method is being used. For example, a USB-PD PPS (USB Power Delivery Programmable Power Supply) type external charger may provide a voltage required by the electronic device through communication with the electronic device by adjusting the voltage in the range of 3V to 20V in 20mV increments. That is, the electronic device can be charged with high speed and high efficiency by requesting an optimal voltage from an external charger according to its state.

Due to such various charging methods, the power supply circuit used in the voltage regulator needs to operate optimally in consideration of the situation in which the voltage provided from the external charger may be fixed to a predetermined value or may be varied in various voltage ranges. .

One object of the present invention is, according to an embodiment, a power supply capable of charging a battery at high speed and high efficiency or providing power to a system inside an electronic device in a situation in which a voltage provided from an external charger may be fixed or variable to provide a circuit.

One object of the present invention is, according to an embodiment, a switched capacitor converter mode (charge pump mode) and a 3-level buck converter mode ( By providing a power supply circuit that can selectively operate in the buck mode), it is possible to effectively operate for various external charging methods, as well as reduce the number of elements and reduce the size and loss of an inductor.

One aspect of the present invention is a power supply circuit that receives power from an external charger and provides power to a battery and/or an electronic device system, and is selected from a charge pump mode or a buck mode according to on/off switching operations of a plurality of transistors. a converter in which at least some of the plurality of transistors are switched in both the charge pump mode and the buck mode; and a controller controlling the switching operation of the plurality of transistors.

In the power supply circuit, the converter comprises: a first transistor connected between a first node and a second node (Q _CH ); a second transistor connected between the second node and the third node (Q _DH1 ); a third transistor (Q _CL1 ) connected between the third node and the fourth node; a fourth transistor connected between the fourth node and the fifth node (Q _DL ); a fifth transistor (Q _DH2 ) connected between the second node and the sixth node; a sixth transistor Q _CL2 connected between the sixth node and the fourth node; a flying capacitor connected between the second node and the fourth node; and an inductor connected between the sixth node and the seventh node, wherein the first node is connected to the input voltage, the third node is connected to the battery voltage, and the fifth node is connected to the reference voltage (PGND), The seventh node may be connected to a system voltage.

In the power supply circuit, the converter may further include a seventh transistor (Q _BAT ) connected between the third node and the seventh node.

In the power supply circuit, the converter is configured to have a substantially 2:1 relationship between the input voltage and the battery voltage by the switching operation of the first to fourth transistors in the charge pump mode. In the buck mode, the system voltage is lower than the input voltage by the switching operation of the first transistor, the fourth transistor, the fifth transistor, and the sixth transistor and the inductor, and the input voltage VIN ) and the system voltage VSYS can be varied.

In the power supply circuit, in the charge pump mode, the first transistor and the third transistor are simultaneously turned on/off with a duty of substantially 0.5, and the second transistor and the fourth transistor are substantially may be turned on/off opposite to that of the first transistor.

In the power supply circuit, in the charge pump mode, the current supplied from the third node to the battery may not pass through the transistor.

In the power supply circuit, in the buck mode, the first transistor is turned on/off with a first duty, and the fifth transistor has a 180 degree phase with substantially the same duty as the first transistor. It is turned on/off in a shifted form, the sixth transistor may be turned on/off opposite to the fifth transistor, and the fourth transistor may be turned on/off opposite to the first transistor.

In the power supply circuit, the controller may control the ratio of the input voltage to the system voltage by adjusting the first duty.

In the power supply circuit, a current ripple frequency of the inductor may be twice a switching frequency of the first transistor.

In the power supply circuit, in the charge pump mode, the fifth transistor and the sixth transistor may not perform an on/off operation.

In the power supply circuit, in the charge pump mode, the fifth transistor and the sixth transistor may also perform a switching operation.

In the power supply circuit, the fifth transistor may be turned on/off in the same manner as the second transistor, and the sixth transistor may be turned on/off in the same manner as the third transistor.

In the power supply circuit, the input voltage to which the first node is connected may be an intermediate bus voltage generated from a voltage provided from the external charger.

In the power supply circuit, an input transistor Q _RB may be further included between the first node and the node connected to the external charger.

In the power supply circuit, the second transistor, the third transistor, and the seventh transistor may be transistors capable of bidirectional control.

According to the present invention, according to an embodiment, it is possible to charge a battery or provide power to an electronic device system at high speed and high efficiency in a situation in which the voltage provided from the charger may be fixed or variable.

According to the present invention, according to an embodiment, a switched capacitor converter mode (charge pump mode) and a 3-level buck converter mode (buck mode) are used using a single circuit having a simple structure. ), it is possible to effectively operate for various external charging methods, as well as reduce the number of elements and reduce the size and loss of the inductor.

1 illustrates a power supply circuit according to an embodiment of the present invention.
2 to 4 exemplarily describe a case in which the power supply circuit according to the embodiment of FIG. 1 operates in a switched capacitor converter mode.
5 to 9 exemplarily describe a case in which the power supply circuit according to the embodiment of FIG. 1 operates in a 3-level buck converter mode with a duty greater than 0.5.
10 to 12 exemplarily describe a case in which the power supply circuit according to the embodiment of FIG. 1 operates at a duty of 0.5 in a 3-level buck converter mode.
13 to 17 exemplarily describe a case in which the power supply circuit according to the embodiment of FIG. 1 operates with a duty of less than 0.5 in a 3-level buck converter mode.
18 and 19 exemplarily describe a case in which the power supply circuit according to the embodiment of FIG. 1 operates in a manner different from that of FIGS. 4 to 5 in a switched capacitor converter mode.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the elements from other elements, and the essence, order, or order of the elements are not limited by the terms. When it is described that a component is “connected”, “coupled” or “connected” to another component, the component may be directly connected or connected to the other component, but another component is formed between each component. It should be understood that elements may also be “connected,” “coupled,” or “connected.”

1 illustrates a power supply circuit according to an embodiment of the present invention.

Referring to FIG. 1 , the power supply circuit may include a controller 110 , an integrated circuit 100 including a plurality of transistors, and peripheral elements (inductors, capacitors, etc.) of the integrated circuit 100 . In FIG. 1 , elements (transistors, buffers, inductors, capacitors, etc.) other than the controller 110 and the battery 10 may be understood as constituting a converter. That is, the power supply circuit may be understood to include a converter including a plurality of transistors and passive elements and the controller 110 . The battery 10 is generally viewed as a configuration outside the power supply circuit, but the battery 10 can also be considered to be included in the power supply circuit depending on circumstances.

The power supply circuit may receive power from an external charger TA and provide power to a battery and/or an electronic device system. For example, the power supply circuit may be used inside a mobile electronic device such as a mobile phone or tablet to perform functions such as charging a battery, converting a voltage received from an external charging device, and selecting power. Illustratively, the power supply circuit may be used as a voltage regulator inside a power management integrated circuit (PMIC) within the mobile electronic device or as a voltage regulator that cooperates with a power management integrated circuit (PMIC) outside the power management integrated circuit (PMIC). there is.

The power supply circuit may be connected to an external charger TA through an input port (not shown). The input port may be connected to a charger TA external to the electronic device to receive power from the external charger TA. The voltage provided from the external charger TA may be a fixed voltage, such as 5V or 9V, or a voltage variable in the range of 3V to 11V or 3V to 20V. For example, the input port may be a USB A-type or a USB C-type, but is not limited thereto.

The bus capacitor C _VBUS may be connected between the bus voltage terminal VBUS and the reference voltage PGND. The bus capacitor C _VBUS may be selectively used as needed to stabilize the bus voltage V _BUS .

The input transistor Q _RB may be connected between the bus voltage V _BUS and the intermediate bus voltage V _MID . The input transistor Q _RB may be selectively used as needed to perform a function of transferring the bus voltage V _BUS to the intermediate bus voltage V _MID . For example, the input terminal transistor Q _RB may perform a current regulation function for preventing an excessive current from flowing in an initial operation or a transient state of the power supply circuit. For example, when the current and/or the battery current of the VBUS terminal are detected and the current flows more than the set current, the input transistor Q _RB may perform a regulating function for the current and/or the battery current of the VBUS terminal. In addition, according to an embodiment, when the measured battery voltage V _BAT becomes higher than the set voltage, a function of adjusting the battery voltage V _BAT may be performed by using the input terminal transistor Q _RB . In this case, the input stage transistor (Q _RB ) controls the intermediate bus voltage (V _MID ) in such a way that, when transferring the bus voltage (V _BUS ) to the intermediate bus voltage (V _MID ), the voltage is lowered to transfer the battery voltage (V _BAT ) can perform a function to control For example, the input transistor Q _RB may perform a function of blocking the transfer of the bus voltage V _BUS to the intermediate bus voltage V _MID in an abnormal state. For example, in a normal operating state, the input terminal transistor Q _RB may be conductive to transfer the bus voltage V _BUS as the intermediate bus voltage V _MID without any special processing. In this case, the intermediate bus voltage V _MID may be substantially equal to the bus voltage V _BUS .

The intermediate bus capacitor C _MID may be connected between the intermediate bus voltage V _MID and the reference voltage PGND. The intermediate bus capacitor C _MID may optionally be used as needed to stabilize the intermediate bus voltage V _MID .

The battery 10 may store power provided from the external charger TA and provide the stored power to the system voltage terminal VSYS_PWR of the electronic device as needed. Illustratively, the battery 10 may be a lithium-ion battery mainly used in mobile electronic devices, but is not limited thereto. According to an embodiment, a signal provided from the voltage sensing terminals S+ and S- of the battery 10 may be provided to the controller 110 through the battery voltage detecting terminals BATSNSP and BATSNSN of the integrated circuit 100 . . The battery voltage detection terminals BATSNSP and BATSNSN may be selectively used as necessary to precisely detect the voltage of the battery 10 without being affected by the operating condition of the power supply circuit.

Next, a converter circuit configuration between the intermediate bus voltage (V _MID ), the battery voltage (V _BAT ), and the system voltage (V _SYS ) will be described. In the embodiment of FIG. 1 , since the intermediate bus voltage V _MID can be viewed as an input voltage of the converter, the intermediate bus voltage V _MID can be expressed as the input voltage V _IN . The intermediate bus voltage V _MID is generated from the voltage provided from the external charger TA. When the input stage transistor Q _RB is fully conducted, the input voltage V _IN is the bus voltage provided from the external charger TA. (V _BUS ) may be substantially the same.

The converter includes a first transistor (Q _CH ) connected between the first node (N1) and the second node (N2), a second transistor (Q _DH1 ) connected between the second node (N2) and the third node (N3) , a third transistor (Q _CL1 ) connected between the third node (N3) and the fourth node (N4), a fourth transistor (Q _DL ) connected between the fourth node (N4) and the fifth node (N5), the first A fifth transistor Q _DH2 connected between the second node N2 and the sixth node N6, a sixth transistor Q _CL2 connected between the sixth node N6 and the fourth node N4, the second node It may include a flying capacitor C _FLY connected between N2 and the fourth node N4 and an inductor L connected between the sixth node N6 and the seventh node N7 . According to an embodiment, the converter may further include a seventh transistor Q _BAT connected between the seventh node N7 and the third node N3 .

Here, the first node N1 may be connected to the input voltage V _IN , and the third node N3 may be connected to the battery voltage V _BAT through the first output voltage terminal VOUT1 . The fifth node N5 may be connected to the reference voltage PGND, and the seventh node N7 may be connected to the system voltage V _SYS through the system voltage terminal VSYS.

If necessary, a system voltage capacitor C _VSYS may be connected between the system voltage V _SYS and the reference voltage PGND to stabilize the system voltage V _SYS .

If necessary, a battery voltage capacitor C _VBAT may be connected between the battery voltage V _BAT and the reference voltage PGND to stabilize the battery voltage V _BAT .

The controller 110 may perform overall control of the power supply circuit. According to an embodiment, the controller 110 may communicate with a power management integrated circuit (not shown) that manages power of the electronic device system and may transmit/receive information for controlling the power supply circuit. Exemplarily, the controller 110 controls on/off switching operations of a plurality of transistors in the power supply circuit to supply at least one of voltage, current, and power to the battery voltage terminal VBAT and the system voltage terminal VSYS. can be adjusted. To this end, if necessary, the controller 110 may acquire information on at least one of a voltage and a current of the battery 10 . For example, the controller 110 may acquire battery voltage information through the battery voltage detection terminals BATSNSP and BATSNSN. For example, the controller 110 may acquire battery current information detected using a current detection resistor or a current transformer (CT) through a battery current detection terminal. When the external charger (TA) can vary the voltage, the controller 110 directly requests information about the voltage to be provided from the external charger (TA) to the external charger (TA) or the external charger through the power management integrated circuit (TA) can be requested.

The power supply circuit may include a plurality of buffers BF as illustrated in FIG. 1 . Each buffer BF may be selectively used as needed to receive a signal provided by the controller 110 for driving a transistor and apply an appropriate driving signal to a corresponding transistor. For example, the buffer BF may be used to amplify a current applied to a gate terminal of the transistor, amplify a voltage, or drive a transistor in a floating state. When the controller 110 can directly drive the transistor, the buffer BF for driving the transistor may not be used.

The power supply circuit configured as described above may selectively operate among two operation modes as needed. One of the two operating modes is a switched capacitor converter (SCC) mode, and the other is a three-level buck converter (3-level Buck converter) mode. The switched capacitor converter mode may be referred to as a 'charge pump mode'. The 3-level buck converter mode will be briefly referred to as 'buck mode' if there is no confusion.

That is, the converter in the power supply circuit may selectively operate in the charge pump mode or the buck mode according to on/off switching operations of the plurality of transistors. In this case, at least some of the plurality of transistors in the converter may be configured to perform a switching operation in both the charge pump mode and the buck mode. In other words, in the power supply circuit according to the embodiment of the present invention, both the operation of the charge pump circuit and the operation of the 3-level buck circuit corresponding to different operation methods are possible using one circuit, and the charge pump circuit and the three It can be understood as a new circuit in which the -level buck circuit is merged into one.

In the converter, in the charge pump mode, the ratio of the input voltage V _IN to the battery voltage V _BAT is substantially 2:1 by the switching operation of the first transistor Q _CH to the fourth transistor Q _DL . It can operate to have . In the charge pump mode, the fifth transistor Q _DH2 and the sixth transistor Q _CL2 may selectively operate as needed. The charge pump mode is mainly performed when the ratio of the first node (N1) voltage (ie, the input voltage (V _IN )) to the third node (N3) voltage (ie, the battery voltage (V _BAT )) has a relationship of 2:1. It can be used to deliver power with high efficiency.

The converter, in the buck mode, the switching operation of the first transistor (Q _CH ), the fourth transistor (Q _DL ), the fifth transistor (Q _DH2 ) and the sixth transistor (Q _CL2 ) and the system voltage by the inductor (L) While (V _SYS ) is lower than the input voltage (V _IN ), the ratio of the input voltage (V _IN ) to the system voltage (V _SYS ) may be varied. In the buck mode, if necessary, the second transistor Q _DH1 and the third transistor Q _CL1 may maintain an off state. In the buck mode, the ratio (voltage conversion ratio) of the seventh node N7 voltage (ie, the system voltage V _SYS ) to the first node N1 voltage (ie, the input voltage V _IN ) is the first transistor (Q _CH ), the fourth transistor (Q _DL ), the fifth transistor (Q _DH2 ), and the sixth transistor (Q _CL2 ) may be controlled through control. Therefore, the buck mode can effectively operate in a situation where the ratio of the voltage of the first node (N1) to the voltage of the seventh node (N7) is not 2:1, that is, in a situation where various voltage conversion ratios are required.

The seventh transistor Q _BAT may selectively transmit current in either direction between the system voltage node VSYS_PWR and the battery voltage node VBAT in either direction as needed. That is, the seventh transistor Q _BAT transfers a current from the system voltage node VSYS_PWR to the battery voltage node VBAT to charge the battery 10 or from the battery voltage node VBAT to the system voltage node VSYS_PWR. The energy stored in the battery 10 may be supplied to the system by passing a current. This operation of the seventh transistor Q _BAT may be selectively performed as needed in any mode of the charge pump mode and the buck mode.

Specific operations in the charge pump mode and the buck mode will be described in detail below with reference to the drawings.

In FIG. 1 , the controller 110, transistors, and buffers are included in the integrated circuit 100 and passive elements (capacitors, inductors, etc.) are exemplified as being disposed outside the integrated circuit 100, but the integrated circuit 100 The elements disposed therein may be variously changed. For example, some of the transistors and buffers may be disposed outside the integrated circuit 100 and/or some of the passive components may be disposed within the integrated circuit 100 .

2 to 4 exemplarily describe a case in which the power supply circuit according to the embodiment of FIG. 1 operates in a switched capacitor converter mode (charge pump mode).

FIG. 2 illustrates on/off operations and main waveforms V _CP , V _OUT1 , and V _CN of the first transistor Q _CH to the fourth transistor Q _DL in the charge pump mode. V _CP is the voltage of the second node N2 , V _OUT1 is the voltage of the third node N3 , and V _CN is the voltage of the fourth node N4 .

Referring to FIG. 2 , the first transistor Q _CH and the third transistor Q _CL1 are turned on/off at the same time with a duty of substantially 0.5, and the second transistor Q _DH1 and the fourth transistor (Q CL1 ) Q _DL ) may be turned on/off substantially opposite to that of the first transistor Q _CH . Here, the duty may be defined as a ratio of the on period to the switching period (the sum of the on period and the off period).

In the charge pump mode, the fifth transistor Q _DH2 and the sixth transistor Q _CL2 may maintain an off state. However, depending on the embodiment, the fifth transistor Q _DH2 and the sixth transistor Q _CL2 may also perform an on/off switching operation in the charge pump mode. For this part, refer to FIGS. 18 and 19 , to be described later.

FIG. 3 exemplarily describes operations in the ON period of the first transistor Q _CH and the third transistor Q _CL1 . The CP node connected to the second node N2 is connected to the input voltage V _IN through the first transistor Q _CH , and the CN node connected to the fourth node N4 is connected to the third transistor Q _CL1 through the third transistor Q CL1 . It is connected to the battery voltage (V _BAT ). Therefore, the input voltage (V _IN ) is equal to the sum of the voltage (V _CFLY ) across the flying capacitor and the battery voltage (V _BAT ).

FIG. 4 exemplarily describes operations in the ON period of the second transistor Q _DH1 and the fourth transistor Q _DL . The CP node connected to the second node N2 is connected to the battery voltage V _BAT through the second transistor Q _DH1 , and the CN node connected to the fourth node N4 is connected to the fourth transistor Q _DL through the It is connected to the reference voltage PGND. Accordingly, the flying capacitor voltage V _CFLY and the battery voltage V _BAT are equal to each other.

As such, the flying capacitor voltage (V _CFLY ) and the battery voltage (V _BAT ) are equal to each other, and the input voltage (V _IN ) is equal to the sum of the flying capacitor voltage (V _CFLY ) and the battery voltage (V _BAT ), as a result, The flying capacitor voltage V _CFLY and the battery voltage V _BAT are each half of the input voltage V _IN . Accordingly, the ratio of the input voltage V _IN which is the voltage of the first node N1 to the battery voltage V _BAT which is the voltage of the third node N3 has a relationship of 2:1.

In the charge pump mode according to the present embodiment, the current supplied from the third node N3 to the battery 10 is directly supplied without passing through the transistor. That is, in the charge pump mode, the current for charging the battery 10 may be supplied from the third node N3 to the battery 10 without passing through the transistor, thereby reducing loss and operating with high efficiency. When the power supply circuit operates in the charge pump mode, the loss due to the inductor (L) is eliminated or reduced, so it can operate with higher current and higher efficiency than the buck mode using the inductor. Therefore, the charge pump mode is mainly used in situations where a large current or large power is transmitted, such as fast charging or super fast charging. According to this embodiment, when the battery is charged in the charge pump mode, the efficiency can be increased.

In the charge pump mode, power supplied from the third node N3 to the battery voltage terminal VBAT may be supplied to the system voltage node VSYS_PWR through the seventh transistor Q _BAT as needed.

5 to 9 illustrate a case in which the power supply circuit according to the embodiment of FIG. 1 operates with a duty (D) greater than 0.5 in a 3-level buck converter mode (buck mode). explain negatively.

5 is a buck mode (D > 0.5) in the first transistor (Q _CH ), the fourth transistor (Q _DL ), the fifth transistor (Q _DH2 ) and the sixth transistor (Q _CL2 ) on/off operation and main waveforms (V _CP , V _OUT2 , V _{CN ,} I _L ) is illustrated. V _OUT2 is the voltage of the sixth node (N6), and the current I _L is the current of the inductor (L).

Referring to FIG. 5 , the first transistor Q _CH may be repeatedly turned on/off with an adjustable duty. The duty may be defined as a ratio of the on period to the switching period (the sum of the on period and the off period). For convenience of description, the duty in the buck mode is defined as the duty of the first transistor Q _CH . For example, the duty of the first transistor (Q _CH ) is to be understood as the ratio of the sum of the lengths of the ①, ② and ④ sections (the ON section of the first transistor (Q _CH )) to the sum of the lengths of the sections ① to ④ can The fifth transistor Q _DH2 has the same duty as the first transistor Q _CH , but may be turned on/off in a substantially 180 degree phase shifted form. The sixth transistor Q _CL2 may be turned on/off substantially opposite to that of the fifth transistor Q _DH2 . The fourth transistor Q _DL may be turned on/off substantially opposite to that of the first transistor Q _CH .

In the buck mode (D>0.5), the second transistor Q _DH1 and the third transistor Q _CL1 may maintain an off state, but the present embodiment is not limited thereto.

FIG. 6 exemplarily describes the operation in the period ① of FIG. 5 , that is, the ON period of the first transistor Q _CH and the sixth transistor Q _CL2 . The CP node connected to the second node N2 is connected to the input voltage V _IN through the first transistor Q _CH , and the CN node connected to the fourth node N4 is connected to the sixth transistor Q _CL2 through the It is connected to the second output voltage (V _OUT2 ) and one end of the inductor (L). The other end of the inductor L may be connected to the system voltage V _SYS and may be selectively connected to the battery voltage V _BAT through the seventh transistor Q _BAT if necessary. At this time, a voltage (ie, Vin/2) obtained by subtracting the flying capacitor voltage V _CFLY from the input voltage V _IN is applied to the second output voltage V _OUT2 to which one end of the inductor L is connected, and the inductor ( A system voltage (V _SYS ) is applied to the other end of L), and when the duty is greater than 0.5, the system voltage (V _SYS ) is greater than half of the input voltage (V _IN ) as will be described later, so the inductor current (I _L ) decreases.

FIG. 7 exemplarily describes the operation in the period ② of FIG. 5 , that is, the ON period of the first transistor Q _CH and the fifth transistor Q _DH2 . The CP node connected to the second node N2 is connected to the input voltage V _IN through the first transistor Q _CH and the second output voltage V _OUT2 and the inductor L through the fifth transistor Q _DH2 . ) is connected to one end of The CN node connected to the fourth node N4 is in a floating state. The other end of the inductor L may be connected to the system voltage V _SYS and may be selectively connected to the battery voltage V _BAT through the seventh transistor Q _BAT if necessary. At this time, the input voltage V _IN is applied to the second output voltage V _OUT2 to which one end of the inductor L is connected, and the system voltage V _SYS is applied to the other end of the inductor L, the input voltage ( Since V _IN ) is higher than the system voltage (V _SYS ), the inductor current (I _L ) increases.

FIG. 8 exemplarily describes the operation in the period ③ of FIG. 5 , that is, the ON period of the fifth transistor Q _DH2 and the fourth transistor Q _DL . The CP node connected to the second node N2 is connected to the second output voltage V _OUT2 and one end of the inductor L through the fifth transistor Q _DH2 . The CN node connected to the fourth node N4 is connected to the reference voltage PGND through the fourth transistor Q _DL . The other end of the inductor L may be connected to the system voltage V _SYS and may be selectively connected to the battery voltage V _BAT through the seventh transistor Q _BAT if necessary. At this time, the flying capacitor voltage V _CFLY is applied to the second output voltage V _OUT2 to which one end of the inductor L is connected, and the system voltage V _SYS is applied to the other end of the inductor L. The system voltage Since (V _SYS ) is higher than the flying capacitor voltage (V _CFLY ) (= V _IN /2), the inductor current (I _L ) decreases.

FIG. 9 exemplarily describes the operation in the period ④ of FIG. 5 , that is, the ON period of the first transistor Q _CH and the fifth transistor Q _DH2 . Since the operation in section ④ is similar to the operation in section ②, a detailed description will be omitted.

When the duty is greater than 0.5 in the buck mode, the operation of sections ① to ④ of FIG. 5 is repeated, and the second output voltage V _OUT2 is applied to one end of the inductor L and the system voltage V _SYS is applied to the other end of the inductor L. ) is approved. At this time, half of the input voltage (V _IN ) is applied to the second output voltage (V _OUT2 ) in sections ① and ③, and the input voltage V _IN is applied in sections ② and ④. Since the capacitance of the system input stage is usually sufficiently large, it can be assumed that the system voltage (V _SYS ) has a constant value without change within one switching period. In the steady-state, the average of the voltages applied to one end and the other end of the inductor L are equal to each other, so the system voltage V _SYS is higher than half of the input voltage V _IN , and the input voltage V _IN ) will have a lower value than The ratio of the system voltage (V _SYS ) to the input voltage (V _IN ) can be controlled by adjusting the ratio of the sum of sections ① and ③ or the ratio of the sum of sections ② and ④ with respect to the switching period. That is, the ratio of the system voltage V _SYS to the input voltage V _IN may be adjusted through the duty of the first transistor Q _CH (for convenience of description, the duty of the first transistor Q _CH is representative For example, it can also be understood as being adjusted according to the duty of other transistors).

10 to 12 exemplarily illustrate a case in which the power supply circuit according to the embodiment of FIG. 1 operates at a duty (D) of 0.5 in a 3-level buck converter mode (buck mode). explained as

10 is a buck mode (D = 0.5) in the first transistor (Q _CH ), the fourth transistor (Q _DL ), the fifth transistor (Q _DH2 ) and the sixth transistor (Q _CL2 ) on/off operation and main waveforms (V _CP , V _OUT2 , V _{CN ,} I _L ) is illustrated.

Referring to FIG. 10 , the first transistor Q _CH may be repeatedly turned on/off with a duty of substantially 0.5. The fifth transistor Q _DH2 has the same duty as the first transistor Q _CH , but may be turned on/off in a substantially 180 degree phase shifted form. The sixth transistor Q _CL2 may be turned on/off substantially opposite to that of the fifth transistor Q _DH2 . The fourth transistor Q _DL may be turned on/off substantially opposite to that of the first transistor Q _CH .

FIG. 11 exemplarily describes the operation in the period ① of FIG. 10 , that is, the ON period of the first transistor Q _CH and the sixth transistor Q _CL2 . The CP node connected to the second node N2 is connected to the input voltage V _IN through the first transistor Q _CH , and the CN node connected to the fourth node N4 is connected to the sixth transistor Q _CL2 through the It is connected to the second output voltage (V _OUT2 ) and one end of the inductor (L). The other end of the inductor L may be connected to the system voltage V _SYS and may be selectively connected to the battery voltage V _BAT through the seventh transistor Q _BAT if necessary. At this time, a voltage (ie, Vin/2) obtained by subtracting the flying capacitor voltage V _CFLY from the input voltage V _IN is applied to the second output voltage V _OUT2 to which one end of the inductor L is connected, and the inductor ( The system voltage V _SYS is applied to the other end of L), and when the duty is 0.5, the system voltage V _SYS becomes half of the input voltage V _IN , as will be described later, so the inductor current I _L is substantially (Actually, there may be a slight increase or decrease in the inductor current (I _L ) due to the duty not being exactly 0.5 or the effect of parasitics, etc.).

FIG. 12 exemplarily describes the operation in the period ② of FIG. 10 , that is, the on period of the fifth transistor Q _DH2 and the fourth transistor Q _DL . The CP node connected to the second node N2 is connected to the second output voltage V _OUT2 and one end of the inductor L through the fifth transistor Q _DH2 . The CN node connected to the fourth node N4 is connected to the reference voltage PGND through the fourth transistor Q _DL . The other end of the inductor L may be connected to the system voltage V _SYS and may be selectively connected to the battery voltage V _BAT through the seventh transistor Q _BAT if necessary. At this time, the flying capacitor voltage V _CFLY is applied to the second output voltage V _OUT2 to which one end of the inductor L is connected, and the system voltage V _SYS is applied to the other end of the inductor L. The system voltage Since (V _SYS ) is substantially equal to the flying capacitor voltage (V _CFLY ) (= V _IN /2), the inductor current (I _L ) does not substantially increase or decrease.

When the duty is 0.5 in the buck mode, the operations of sections ① and ② of FIG. 10 are repeated. At this time, half of the input voltage V _IN is commonly applied to the second output voltage V _OUT2 in the section ① and section ②. In a steady-state, the average of the voltages across the inductor L is equal to each other, so the system voltage V _SYS is also half of the input voltage V _IN .

13 to 17 exemplarily illustrate a case in which the power supply circuit according to the embodiment of FIG. 1 operates with a duty of less than 0.5 in a 3-level buck converter mode (buck mode). Explain.

13 is a buck mode (D < 0.5) of the first transistor (Q _CH ), the fourth transistor (Q _DL ), the fifth transistor (Q _DH2 ), and the sixth transistor (Q _CL2 ) on/off operation and main waveforms (V _CP , V _OUT2 , V _{CN ,} I _L ) is illustrated.

Referring to FIG. 13 , the first transistor Q _CH may be repeatedly turned on/off with an adjustable duty. The duty may be defined as a ratio of the on period to the switching period (the sum of the on period and the off period). For convenience of description, the duty in the buck mode is defined as the duty of the first transistor Q _CH . For example, the duty of the first transistor Q _CH may be understood as a ratio of the length of the section ① (the ON section of the first transistor Q _CH ) to the sum of the lengths of sections ① to ④. The fifth transistor Q _DH2 has substantially the same duty as the first transistor Q _CH , but may be turned on/off in a 180 degree phase shifted form. The sixth transistor Q _CL2 may be turned on/off substantially opposite to that of the fifth transistor Q _DH2 . The fourth transistor Q _DL may be turned on/off substantially opposite to that of the first transistor Q _CH .

In the buck mode (D<0.5), the second transistor Q _DH1 and the third transistor Q _CL1 may maintain an off state, but the present embodiment is not limited thereto.

FIG. 14 exemplarily describes the operation in the period ① of FIG. 13 , that is, the ON period of the first transistor Q _CH and the sixth transistor Q _CL2 . The CP node connected to the second node N2 is connected to the input voltage V _IN through the first transistor Q _CH , and the CN node connected to the fourth node N4 is connected to the sixth transistor Q _CL2 through the It is connected to the second output voltage (V _OUT2 ) and one end of the inductor (L). The other end of the inductor L may be connected to the system voltage V _SYS and may be selectively connected to the battery voltage V _BAT through the seventh transistor Q _BAT if necessary. At this time, a voltage (ie, Vin/2) obtained by subtracting the flying capacitor voltage V _CFLY from the input voltage V _IN is applied to the second output voltage V _OUT2 to which one end of the inductor L is connected, and the inductor ( A system voltage (V _SYS ) is applied to the other end of L), and when the duty is less than 0.5, the system voltage (V _SYS ) becomes less than half of the input voltage (V _IN ) as will be described later, so the inductor current (I _L ) is increased

FIG. 15 exemplarily describes the operation in the period ② of FIG. 13 , that is, the on period of the sixth transistor Q _CL2 and the fourth transistor Q _DL . The CP node connected to the second node N2 is in a floating state. The CN node connected to the fourth node N4 is connected to the second output voltage V _OUT2 and one end of the inductor L through the sixth transistor Q _CL2 and the reference voltage (Q _DL ) through the fourth transistor (Q DL ) PGND). The other end of the inductor L may be connected to the system voltage V _SYS and may be selectively connected to the battery voltage V _BAT through the seventh transistor Q _BAT if necessary. At this time, the reference voltage PGND is applied to the second output voltage V _OUT2 to which one end of the inductor L is connected, and the system voltage V _SYS is applied to the other end of the inductor L, so the inductor current I _L ) decreases.

FIG. 16 exemplarily illustrates the operation in section ③ of FIG. 13 , that is, in the ON section of the fifth transistor Q _DH2 and the fourth transistor Q _DL . The CP node connected to the second node N2 is connected to the second output voltage V _OUT2 and one end of the inductor L through the fifth transistor Q _DH2 . The CN node connected to the fourth node N4 is connected to the reference voltage PGND through the fourth transistor Q _DL . The other end of the inductor L may be connected to the system voltage V _SYS and may be selectively connected to the battery voltage V _BAT through the seventh transistor Q _BAT if necessary. At this time, the flying capacitor voltage V _CFLY is applied to the second output voltage V _OUT2 to which one end of the inductor L is connected, and the system voltage V _SYS is applied to the other end of the inductor L. The system voltage Since (V _SYS ) is less than the flying capacitor voltage (V _CFLY ) (= V _IN /2), the inductor current (I _L ) increases.

FIG. 17 exemplarily describes the operation in section ④ of FIG. 13 , that is, in the ON section of the sixth transistor Q _CL2 and the fourth transistor Q _DL . Since the operation in section ④ is similar to the operation in section ②, a detailed description will be omitted.

When the duty is less than 0.5 in the buck mode, the operations of sections ① to ④ of FIG. 13 are repeated. At this time, half of the input voltage V _IN is applied to the second output voltage V _OUT2 in sections ① and ③, and the reference voltage PGND (ie, 0V) is applied in sections ② and ④. In the steady-state, the averages of the voltages across the inductor L are equal to each other, so the system voltage V _SYS has a value lower than half of the input voltage V _IN . The ratio (ie, voltage conversion ratio) of the system voltage V _SYS to the input voltage V _IN may be controlled by adjusting the ratio (ie, duty) of the sum of sections ① and ③ for the switching period.

5, 10 and 13 , the first transistor Q _CH is turned on/off with a first _duty , and the fifth transistor Q _DH2 is substantially is turned on/off in a ₁₈₀ -degree phase- _shifted form while having the same _duty as It is the same in that it is turned on/off opposite to the transistor Q _CH . That is, the switching sequence of the first transistor (Q _CH ), the fourth transistor (Q _DL ), the fifth transistor (Q _DH2 ), and the sixth transistor (Q _CL2 ) in the buck mode, regardless of the duty, a common method is applied In addition, the ratio of the system voltage (V _SYS ) to the input voltage (V _IN ) (ie, voltage conversion ratio) may be varied in a wide range while theoretically having a value between 0 and 1 according to the duty. In actual implementation, the duty may be varied in a predetermined range, for example, in the range of 0.1 to 0.9. The controller may control the ratio (voltage conversion ratio) of the input voltage V _IN to the system voltage V _SYS by adjusting the duty (eg, the first duty) of the transistors.

In addition, as can be seen from FIGS. 5 and 13 , the current ripple frequency of the inductor L may be doubled the switching frequency of the transistor (eg, the first transistor Q _CH ). 5 and 13 , the switching period of the first transistor Q _CH is the sum of sections ① to ④, but the current ripple period of the inductor L is the sum of sections ① and ② (or ③ and ④ sum of the sections) becomes half of the switching period of the first transistor (Q _CH ). In this case, since the inductance of the inductor L can be reduced, the size and loss of the inductor L can be reduced.

In the buck mode according to the present embodiment, the current supplied through the inductor L may be supplied to the system voltage node VSYS_PWR without passing through an additional transistor. Therefore, buck mode can be effectively used to power the system. When the battery needs to be charged in the buck mode, at least a portion of the current supplied to the system voltage node VSYS_PWR through the inductor L may be supplied to the battery 10 through the seventh transistor Q _BAT .

As such, the power supply circuit according to the present embodiment can selectively operate in the charge pump mode and the buck mode using one circuit having a simple structure, so that the voltage provided from the external charger can be fixed or variable. In addition to being able to operate effectively in the charge pump mode, the current for charging the battery 10 in the charge pump mode can be supplied to the battery 10 from the third node N3 without going through the transistor, thereby charging the battery 10 with high efficiency. In the buck mode, the current supplied to the system can be supplied from the inductor (L) to the system voltage node (VSYS_PWR) without going through the transistor, thereby increasing the efficiency when supplying power to the system.

18 and 19 exemplarily describe a case in which the power supply circuit according to the embodiment of FIG. 1 operates in a switched capacitor converter mode (charge pump mode) in a manner different from that of FIGS. 4 to 5 . .

In the operation of the charge pump mode according to the embodiment of FIGS. 18 and 19 , the on/off operation of the first transistor Q _CH to the fourth transistor Q _DL and the main waveforms V _CP , V _OUT1 , V _CN ) may be similar to that illustrated in FIG. 2 . That is, the first transistor Q _CH and the third transistor Q _CL1 are turned on/off simultaneously with a duty of substantially 0.5, and the second transistor Q _DH1 and the fourth transistor Q _DL are It may be turned on/off substantially opposite to that of the first transistor Q _CH . However, the embodiment of FIGS. 18 and 19 is different from the method illustrated in FIGS. 3 and 4 in that the fifth transistor Q _DH2 and the sixth transistor Q _CL2 also perform the switching operation. Specifically, the fifth transistor Q _DH2 may be turned on/off in the same manner as the second transistor Q _DH1 , and the sixth transistor Q _CL2 may be turned on/off in the same manner as the third transistor Q _CL1 . .

18 exemplarily describes operations in the ON period of the first transistor Q _CH , the third transistor Q _CL1 , and the sixth transistor Q _CL2 . The CP node connected to the second node N2 is connected to the input voltage V _IN through the first transistor Q _CH , and the CN node connected to the fourth node N4 is connected to the third transistor Q _CL1 through the third transistor Q CL1 . It is connected to the battery voltage (V _BAT ). Accordingly, the input voltage V _IN is equal to the sum of the flying capacitor voltage V _CFLY and the battery voltage V _BAT . At this time, since the sixth transistor Q _CL2 is also in an on state, the CN node is connected to the second output voltage V _OUT2 and one end of the inductor L through the sixth transistor Q _CL2 . Accordingly, a path for supplying current to the system voltage node (VSYS_PWR) through the inductor (L) is additionally created in the CN node. The current supplied to the system voltage node VSYS_PWR through the inductor L may be transferred to the battery 10 through the seventh transistor Q _BAT depending on circumstances to be used to charge the battery 10 .

19 exemplarily describes operations in the ON period of the second transistor Q _DH1 , the fourth transistor Q _DL , and the fifth transistor Q _DH2 . The CP node connected to the second node N2 is connected to the battery voltage V _BAT through the second transistor Q _DH1 , and the CN node connected to the fourth node N4 is connected to the fourth transistor Q _DL through the It is connected to the reference voltage PGND. Accordingly, the flying capacitor voltage V _CFLY and the battery voltage V _BAT are equal to each other. At this time, since the fifth transistor Q _DH2 is also in an on state, the CP node is connected to the second output voltage V _OUT2 and one end of the inductor L through the fifth transistor Q _DH2 . Accordingly, a path for supplying current to the system voltage node (VSYS_PWR) through the inductor (L) is additionally created in the CP node. The current supplied to the system voltage node VSYS_PWR through the inductor L may be transferred to the battery 10 through the seventh transistor Q _BAT depending on circumstances to be used to charge the battery 10 .

In the embodiments of FIGS. 18 and 19 , the voltage conversion ratio, which is the ratio of the battery voltage V _BAT to the input voltage V _IN , may be the same as in the embodiments of FIGS. 2 to 4 . However, in the embodiments of FIGS. 18 and 19 , as a current path supplied from the input voltage V _IN to the system voltage node VSYS_PWR and/or the battery voltage node VBAT, the battery through the third node N3 A path supplied to the voltage node VBAT and a path supplied to the system voltage node VSYS_PWR through the sixth node N6 and the inductor L may be formed together. The system voltage node VSYS_PWR and the battery voltage node VBAT may transfer current in either direction through the seventh transistor Q _BAT as needed. That is, a current is transferred from the system voltage node VSYS_PWR to the battery voltage node VBAT through the seventh transistor Q _BAT to charge the battery 10 or from the battery voltage node VBAT to the system voltage node VSYS_PWR. The energy stored in the battery 10 may be supplied to the system by transferring the current to the system. As such, when a plurality of current paths supplied from the input voltage V _IN to the system voltage node VSYS_PWR and/or the battery voltage node VBAT are formed, the effective impedance on the current path is lowered to reduce losses and increase efficiency. There is this. This advantage according to the embodiment of Figs. 18 and 19 may be more effective, especially in situations where large currents or powers are processed, such as fast charging or super fast charging.

In the above-described embodiments, the controller 110 may be implemented in software and stored in a computer-readable storage medium (memory, etc.), and may perform its function by an arithmetic device such as a CPU. According to an embodiment, the controller 110 may be implemented as hardware such as an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA), or the like.

In addition, a transistor capable of unidirectional control may be used for the first transistor Q _CH , the fourth transistor Q _DL , the fifth transistor Q _DH2 , and the sixth transistor Q _CL2 , and the second transistor Q _DH1 ), the third transistor Q _CL1 , the seventh transistor Q _BAT , and the input terminal transistor Q _RB , a transistor capable of bidirectional control may be used. As an example of a transistor capable of bidirectional control, a back-gate control MOSFET or a back-to-back MOSFET may be used.

Terms such as "include", "comprise" or "have" described above mean that the corresponding component may be embedded unless otherwise stated, so it does not exclude other components. It should be construed as being able to further include other components. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs, unless otherwise defined. Terms commonly used, such as those defined in the dictionary, should be interpreted as being consistent with the meaning of the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present invention.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Claims (15)

A power supply circuit that receives power from an external charger and provides power to a battery and/or electronic device system, comprising:
a converter selectively operating in a charge pump mode or a buck mode according to an on/off switching operation of a plurality of transistors, wherein at least some of the plurality of transistors perform a switching operation in both the charge pump mode and the buck mode; and
a controller controlling a switching operation of the plurality of transistors;
A power supply circuit comprising a. The method according to claim 1, The converter,
a first transistor connected between the first node and the second node (Q _CH );
a second transistor connected between the second node and the third node (Q _DH1 );
a third transistor (Q _CL1 ) connected between the third node and the fourth node;
a fourth transistor connected between the fourth node and the fifth node (Q _DL );
a fifth transistor (Q _DH2 ) connected between the second node and the sixth node;
a sixth transistor Q _CL2 connected between the sixth node and the fourth node;
a flying capacitor connected between the second node and the fourth node; and
Including; an inductor connected between the sixth node and the seventh node,
The first node is connected to the input voltage,
The third node is connected to the battery voltage,
The fifth node is connected to the reference voltage PGND,
The seventh node is connected to the system voltage, the power supply circuit. 3. The method according to claim 2,
The converter further comprises a seventh transistor (Q _BAT ) connected between the third node and the seventh node, the power supply circuit. 3. The method according to claim 2,
The converter is
In the charge pump mode, a ratio of the input voltage to the battery voltage is substantially 2:1 by switching operations of the first to fourth transistors;
In the buck mode, the system voltage is lower than the input voltage by the switching operation of the first transistor, the fourth transistor, the fifth transistor, and the sixth transistor and the inductor, and the input voltage and the system voltage are Power supply circuit with variable ratio. 5. The method according to claim 4,
In the charge pump mode,
The first transistor and the third transistor are turned on/off at the same time with a duty of substantially 0.5,
and the second transistor and the fourth transistor are turned on/off substantially opposite to the first transistor. 5. The method according to claim 4,
In the charge pump mode,
The current supplied to the battery from the third node does not pass through a transistor, a power supply circuit. 5. The method according to claim 4,
In the buck mode,
The first transistor is turned on/off with a first duty,
The fifth transistor is turned on/off in a 180 degree phase-shifted form while having substantially the same duty as the first transistor,
The sixth transistor is turned on/off opposite to the fifth transistor,
The fourth transistor is turned on/off opposite to the first transistor, the power supply circuit. 8. The method of claim 7,
and the controller controls the ratio of the input voltage and the system voltage by adjusting the first duty. 8. The method of claim 7,
The current ripple frequency of the inductor is twice the switching frequency of the first transistor, the power supply circuit. 5. The method according to claim 4,
In the charge pump mode, the fifth transistor and the sixth transistor do not perform an on/off operation, the power supply circuit. 5. The method according to claim 4,
In the charge pump mode, the fifth transistor and the sixth transistor also perform a switching operation, the power supply circuit. 12. The method of claim 11,
The fifth transistor is turned on/off substantially the same as the second transistor,
The sixth transistor is turned on/off substantially the same as that of the third transistor, the power supply circuit. 3. The method according to claim 2,
The input voltage to which the first node is connected is an intermediate bus voltage generated from a voltage provided from the external charger. 3. The method according to claim 2,
The input terminal transistor (Q _RB ) is further included between the node connected to the external charger and the first node, the power supply circuit. 4. The method according to claim 3,
The second transistor, the third transistor, and the seventh transistor are transistors capable of bidirectional control, a power supply circuit.

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