KR20240044666A - Hybrid buck converter - Google Patents

Abstract

According to the present invention, in the hybrid buck converter, an inductor; a first capacitor connected to one end of the inductor; a second capacitor connected to the other end of the inductor; and a plurality of transistors connected to at least one of the inductor, the first capacitor, and the second capacitor and turned on or off by a gate voltage, and set according to a duty ratio when the hybrid buck converter operates in the second phase. In the first phase, the inductor is charged and the first capacitor and the second capacitor are discharged, and in the second phase set according to the duty ratio during the second phase operation, the inductor is discharged and the first capacitor and the second capacitor are discharged. 2 Capacitor is a hybrid buck converter that operates to charge.

Description

Hybrid buck converter {HYBRID BUCK CONVERTER}

The present invention relates to a hybrid buck converter.

The power circuit is the most basic component for driving various electronic devices. Recently, as the use of automotive semiconductors and mobile devices increases, the demand for high-efficiency direct current-direct current (DC-DC) converters is also increasing. For example, in the case of smartphones, as they drive and perform various applications, the demand for larger battery capacity and higher power efficiency is increasing, which requires a high-efficiency DC-DC converter.

However, a high-efficiency converter uses an inductor with low series resistance and a large area. In this case, the chip area becomes larger, making it difficult to construct a smartphone that emphasizes portability.

Additionally, as higher power is transmitted, the power applied to each switch included in the converter increases, which makes it difficult to construct a highly efficient converter.

Republic of Korea Patent Publication No. 10-2022-0054094 Republic of Korea Patent Publication No. 10-2020-0105202

The present invention is intended to solve the above-described problems, and the purpose of the present invention is to improve the chip area of a direct current-direct current (DC-DC) converter. The present invention can reduce the inductor current by forming an additional path through a capacitor, and a highly efficient step-down converter can be designed based on the reduced inductor current.

In addition, the converter has the problem that as higher power is transmitted, the power consumed in the switch also increases, making it difficult to construct a converter with high efficiency. However, the present invention reduces the gate voltage of the transistor, making it possible to construct a short-length transistor. As a result, it is possible to design with smaller resistance and thus construct a converter with high efficiency.

The present invention provides a hybrid buck converter, including an inductor; a first capacitor connected to one end of the inductor; a second capacitor connected to the other end of the inductor; and a plurality of transistors connected to at least one of the inductor, the first capacitor, and the second capacitor and turned on or off by a gate voltage, and set according to a duty ratio when the hybrid buck converter operates in the second phase. In the first phase, the inductor is charged and the first capacitor and the second capacitor are discharged, and in the second phase set according to the duty ratio during the second phase operation, the inductor is discharged and the first capacitor and the second capacitor are discharged. 2 The capacitor can be operated to charge.

In one embodiment of the present invention, the plurality of transistors include first to sixth transistors, and the hybrid buck converter converts the first transistor in the first phase set according to the duty ratio during the second phase operation. The transistor and the third to fifth transistors are turned on, the second transistor and the sixth transistor are turned off, and the hybrid buck converter operates in the second phase set according to the duty ratio during the second phase operation. The second transistor and the sixth transistor may be turned on, and the first transistor and the third to fifth transistors may be turned off.

In one embodiment of the present invention, the plurality of transistors include first to sixth transistors, and when the hybrid buck converter operates in the third phase in the first section when the voltage conversion rate is The inductor and the second capacitor are charged, the first capacitor is discharged, and when the voltage conversion rate operates in the third phase in the first section, the inductor and the first capacitor are charged in the 1-2 phase, and the first capacitor is discharged. 2 The capacitor is discharged, and when the voltage conversion rate operates in the third phase in the first section, the inductor is discharged in the 1-3 phase and the first capacitor and the second capacitor can be charged.

In one embodiment of the present invention, when the hybrid buck converter operates in the third phase in the first section of the voltage conversion rate, the first transistor, the third transistor, and the sixth transistor in the 1-1 phase. is turned on, the second transistor and the fourth to fifth transistors are turned off, and in the 1-2 phase, the second transistor and the fourth to fifth transistors are turned on, and the first transistor and the The third transistor and the sixth transistor may be turned off, and in the 1-3 phase, the second transistor and the sixth transistor may be turned on, and the first transistor and the third to fifth transistors may be turned off. there is.

In one embodiment of the present invention, the plurality of transistors include first to sixth transistors, and when the hybrid buck converter operates in the third phase in the second section at the voltage conversion rate, the The inductor is charged, the first capacitor and the second capacitor are discharged, and when the voltage conversion rate operates in the third phase in the second section, the inductor and the first capacitor are discharged in the 2-2 phase and the first capacitor is discharged. 2 The capacitor is charged, and when the third phase operates in the second section of the voltage conversion rate, the first capacitor is charged and the inductor and the second capacitor may be discharged in the 2-3 phase.

In one embodiment of the present invention, when the hybrid buck converter operates in the third phase in the second section of the voltage conversion rate, the first transistor and the third to fifth transistors are turned on in the 2-1 phase. The second transistor and the sixth transistor are turned off, and in the 2-2 phase, the first transistor, the third transistor, and the sixth transistor are turned on, and the second transistor and the fourth to fourth transistors are turned on. The fifth transistor may be turned off, and in the 2-3 phase, the second transistor and the fourth to fifth transistors may be turned on, and the first transistor, the third transistor, and the sixth transistor may be turned off. there is.

In one embodiment of the present invention, the plurality of transistors include first to sixth transistors, wherein one end of the first transistor is connected to a first node connected to the first capacitor and the other end is an input. It is connected to an input node where a voltage is input, one end of the second transistor is connected to a second node connected to the first capacitor, the other end is connected to ground connected to the ground, and the third transistor has one end connected to the ground. Connected to the second node, the other end is connected to the output node where the output voltage is output, the fourth transistor has one end connected to the third node connected to the inductor, and the other end is connected to the output node, , the fifth transistor has one end connected to the fourth node connected to the second capacitor, the other end connected to the ground connected to the ground, and the sixth transistor has one end connected to the fourth node and the other end A stage may be connected to the output node.

In one embodiment of the present invention, the first transistor, the third transistor, and the sixth transistor may be configured as PMOS transistors, and the second transistor and the fourth to fifth transistors may be configured as NMOS transistors. .

The electronic device of the present invention includes a hybrid buck converter that generates an output voltage by lowering the input voltage; A voltage converter connected to the hybrid buck converter and generating a regulated output voltage; a comparison unit connected to the voltage converter and generating a pulse width modulation signal by comparing the regulated output voltage and a reference voltage; a control unit that receives the pulse width modulation signal and applies a gate voltage to a plurality of transistors included in the hybrid buck converter for second or third phase operation of the hybrid buck converter; And it may include a mode selection unit that generates a mode selection signal corresponding to the second phase or the third phase operation.

In one embodiment of the present invention, the control unit includes a dead time generator and a gate driver that receives the pulse width modulation signal and the mode selection signal to generate a dead time signal and applies the gate voltage, and the gate The voltage may be applied to the plurality of transistors as a voltage corresponding to the length of the time domain defined.

In one embodiment of the present invention, the control unit may further include a signal copying unit that receives the dead time signal, copies the dead time signal, and transmits it to the dead time generator and the gate driver.

According to the present invention, a new hybrid buck converter method and a device supporting the same can be provided, and in order to reduce the current flowing in the inductor, which is the main cause of efficiency decline, the current flowing in the inductor flows through two capacitors to prevent a decline in circuit efficiency. can do.

In addition, the new hybrid buck converter can select a 2-phase or 3-phase mode depending on the purpose of use, improving the power efficiency of the buck converter.

In addition, the hybrid buck converter fixes the maximum voltage stress applied to a plurality of transistors to the output voltage, making it possible to construct transistors with shorter lengths than existing devices, which allows the construction of a circuit with a small area.

In addition, when the hybrid buck converter of the present invention operates in three-phase mode, it is possible to reduce the ripple voltage generated by some AC signals when generating direct current by rectifying AC power through repeated charging and discharging of two capacitors.

1 is a circuit diagram showing the structure of a hybrid buck converter according to an embodiment of the present invention.
Figure 2a is a circuit diagram showing the operation in the first phase during the second phase operation of the hybrid buck converter according to an embodiment of the present invention.
Figure 2b is a circuit diagram showing the operation in the second phase of the hybrid buck converter according to an embodiment of the present invention.
Figure 3 is a graph showing the states of elements during second-phase operation of a hybrid buck converter according to an embodiment of the present invention.
Figure 4a is a circuit diagram showing the operation in the 1-1 phase of the first section of the voltage conversion rate during the third phase operation of the hybrid buck converter according to an embodiment of the present invention.
Figure 4b is a circuit diagram showing the operation in the 1-2 phase of the first section of the voltage conversion rate during the third phase operation of the hybrid buck converter according to an embodiment of the present invention.
Figure 4c is a circuit diagram showing the operation in the 1st to 3rd phases of the first section of the voltage conversion rate during the 3rd phase operation of the hybrid buck converter according to an embodiment of the present invention.
Figure 5 is a graph showing the states of elements in the first section of the voltage conversion rate during third-phase operation of the hybrid buck converter according to an embodiment of the present invention.
Figure 6a is a circuit diagram showing the operation in the 2-1 phase of the second section of the voltage conversion rate during the third phase operation of the hybrid buck converter according to an embodiment of the present invention.
Figure 6b is a circuit diagram showing the operation in the 2-2 phase of the second section of the voltage conversion rate during the third phase operation of the hybrid buck converter according to an embodiment of the present invention.
Figure 6c is a circuit diagram showing the operation in the 2-3 phase of the second section of the voltage conversion rate during the third phase operation of the hybrid buck converter according to an embodiment of the present invention.
Figure 7 is a graph showing the states of elements in the second section of the voltage conversion rate during third-phase operation of the hybrid buck converter according to an embodiment of the present invention.
Figure 8 is a simplified diagram of an electronic device including a hybrid buck converter according to an embodiment of the present invention.
Figure 9 is a circuit showing the structure of a hybrid buck converter according to an embodiment of the present invention.
Figure 10 is a graph exemplarily showing the power conversion efficiency of a hybrid buck converter according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described clearly and in detail so that a person skilled in the art can easily practice the present invention.

1 is a circuit diagram showing the structure of a hybrid buck converter according to an embodiment of the present invention. Referring to FIG. 1, the hybrid buck converter 110 includes an inductor (L), a first capacitor (C _F1 ), a second capacitor (C _F2 ), and a plurality of transistors (TR _{1 to TR 6} ).

The hybrid buck converter 110 is a direct current-direct current (DC-DC) conversion circuit, and is a step-down conversion circuit used when an output voltage (V _OUT ) lower than the input voltage (V _IN ) is required.

In one embodiment, the hybrid buck converter 110 according to the present invention combines the above-described buck operation into a second phase operation including first to second phases, and a third phase operation including first to third phases. It may be performed based on at least one of the above operations.

The second phase operation may be composed of a first phase and a second phase in the time domain. The relationship between the first phase and the second phase can be defined as a duty ratio. For example, if the time domain length of the first phase is the duty ratio, the time domain length of the second phase may be defined as 1-D. Additionally, the time domain phase length of the illustrated second phase operation may not be limited thereto.

The third phase operation may consist of a first phase to a third phase in the time domain. The relationship between the first to third phases can be defined as a duty ratio. For example, if the time domain length of the first phase and the second phase is a duty ratio, the time domain length of the third phase may be defined as 1-2D. Additionally, if the time domain length of the first phase is the duty ratio, the time domain lengths of the second and third phases may be defined as (1-D)/2. Additionally, the time domain phase length of the illustrated third phase operation may not be limited thereto.

The inductor (L) has one end connected to the first node (N ₁ ) and the other end connected to the third node (N ₃ ). A first capacitor (C _F1 ) is connected to one end of the inductor (L), and a second capacitor (C _F2 ) is connected to the other end of the inductor (L). The inductor (L) may be charged or discharged with current depending on the turn on or turn off of the plurality of transistors (TR _{1 to TR 6} ).

A plurality of transistors (TR _{1 to 6} ) are connected to an inductor (L) or at least one of the first capacitor (C _F1 ) and the second capacitor (C _F2 ), and are turned on or turned on by the gate voltage (V _{SW1 to 6} ). It turns off.

The first capacitor (C _F1 ) is connected to the first node (N ₁ ) and the second node (N ₂ ). The first capacitor C _F1 may be charged or discharged according to the turn-on or turn-off of the plurality of transistors TR _{1 to TR 6} .

The second capacitor (C _F2 ) is connected to the third node (N ₃ ) and the fourth node (N ₄ ). The second capacitor C _F2 may be charged or discharged according to the turn-on or turn-off of the plurality of transistors TR _{1 to TR 6} .

One end of the first transistor (TR ₁ ) is connected to the first node (N ₁ ), and the other end is connected to the input node (N _IN ).

In one embodiment, if the first transistor (TR ₁ ) is a MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor), the source may be connected to the input node (N _IN ) and the drain may be connected to the first node (N ₁ ). there is. The first transistor TR ₁ may perform a switching operation according to the first gate voltage V _SW1 . For example, when the first transistor (TR ₁ ) is turned on according to the first gate (V _SW1 ) voltage, the input voltage (V _IN ) may be applied to the hybrid buck converter 110 .

One end of the second transistor TR ₂ is connected to the second node N ₂ and the other end is connected to ground.

In one embodiment, when the second transistor TR ₂ is a MOSFET, the source may be connected to ground and the drain may be connected to the second node N ₂ . The second transistor TR ₂ may perform a switching operation according to the second gate voltage V _SW2 . For example, when the second transistor (TR ₂ ) is turned on according to the voltage of the second gate (V _SW2 ), the input voltage (V _IN ) may be applied to the hybrid buck converter 110 .

One end of the third transistor (TR ₃ ) is connected to the second node (N ₂ ), and the other end is connected to the output node (N _OUT ).

In one embodiment, if the third transistor TR ₃ is a MOSFET, its source may be connected to the output node (N _OUT ) and its drain may be connected to the second node (N ₂ ). The third transistor TR ₃ may perform a switching operation according to the third gate voltage V _SW3 . For example, when the third transistor (TR ₃ ) is turned on according to the third gate (V _SW3 ) voltage, the input voltage (V _IN ) may be applied to the hybrid buck converter 110 .

One end of the fourth transistor TR ₄ is connected to the third node N ₃ and the other end is connected to the output node N _OUT .

In one embodiment, if the fourth transistor TR ₄ is a MOSFET, its source may be connected to the output node (N _OUT ) and its drain may be connected to the third node (N ₃ ). The fourth transistor TR ₄ may perform a switching operation according to the fourth gate voltage V _SW4 . For example, when the fourth transistor (TR ₄ ) is turned on according to the voltage of the fourth gate (V _SW4 ), the input voltage (V _IN ) may be applied to the hybrid buck converter 110 .

One end of the fifth transistor TR ₅ is connected to the fourth node N ₄ and the other end is connected to ground.

In one embodiment, if the fifth transistor TR ₅ is a MOSFET, the source may be connected to ground and the drain may be connected to the fourth node N ₄ . The fifth transistor TR ₅ may perform a switching operation according to the fifth gate voltage V _SW5 . For example, when the fifth transistor (TR ₅ ) is turned on according to the voltage of the fifth gate (V _SW5 ), the input voltage (V _IN ) may be applied to the hybrid buck converter 110 .

One end of the sixth transistor TR ₆ is connected to the fourth node N ₄ and the other end is connected to the output node N _OUT .

In one embodiment, if the sixth transistor TR ₆ is a MOSFET, its source may be connected to the output node (N _OUT ) and its drain may be connected to the fourth node (N ₄ ). The fourth transistor TR ₄ may perform a switching operation according to the fourth gate voltage V _SW4 . For example, when the fourth transistor (TR ₄ ) is turned on according to the voltage of the fourth gate (V _SW4 ), the input voltage (V _IN ) may be applied to the hybrid buck converter 110 .

Among the plurality of transistors (TR _{1 to TR 6} ) described above, the first transistor (TR ₁ ), the third transistor (TR ₃ ), and the sixth transistor (TR ₆ ) are composed of PMOS transistors, and the second transistor (TR ₂ ) and The fourth to fifth transistors TR ₄ and TR ₅ may be configured as NMOS transistors, but are not limited thereto. For convenience, in FIGS. 1 to 2B, 4A to 4C, 6A to 6C, and 9 of the present invention, some are PMOS and some are NMOS, as described above.

The output voltage (V _OUT ) of the hybrid buck converter 110 may be stored in the output capacitor (C ₀ ) according to the operation of the plurality of transistors (TR _{1 to 6} ).

Hereinafter, embodiments related to the operation of the hybrid buck converter 110 described above will be described based on FIGS. 2A to 7.

Figure 2a is a circuit diagram showing the operation in the first phase during the second phase operation of the hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 2A, the hybrid buck converter 110 uses the first transistor (TR ₁ ) and the third to fifth transistors (TR _3, TR ₄ , TR ₅₎ in the first phase set according to the duty ratio during the second phase operation. ) is turned on, and the second transistor (TR ₂ ) and the sixth transistor (TR ₆ ) are turned off.

Specifically, in the first phase, the first transistor (TR ₁ ) and the third to fifth transistors (TR _3, TR ₄ , TR ₅ ) are turned on and the inductor (L) is charged. On the other hand, due to the turn-off of the second transistor (TR ₂ ) and the sixth transistor (TR ₆ ), the first capacitor (C _F1 ) and the second capacitor (C _F2 ) are discharged.

Figure 2b is a circuit diagram showing the operation in the second phase of the hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 2B, the hybrid buck converter 110 uses the first transistor (TR ₁ ) and the third to fifth transistors (TR ₃ , TR ₄ , and TR ₅ in the second phase set according to the duty ratio during second-phase operation). ) is turned off, and the second transistor (TR ₂ ) and the sixth transistor (TR ₆ ) are turned on.

Specifically, in the second phase, the second transistor TR ₂ and the sixth transistor TR ₆ are turned on and the inductor L is discharged. On the other hand, the first transistor (TR ₁ ) and the third to fifth transistors (TR ₃ , TR ₄ , TR ₅ ) are turned off, so the first capacitor (C _F1 ) and the second capacitor (C _F2 ) are charged. .

Figure 3 is a graph showing the states of elements during second-phase operation of a hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 3, when the hybrid buck converter 110 operates in the second phase, the inductor (L) is charged in the first phase, and the first capacitor (C _F1 ) and the second capacitor (C _F2 ) are discharged. do. At the output terminal, an output voltage having a magnitude lowered from the input voltage is output according to the above-described embodiments.

In addition, when the hybrid buck converter 110 operates in the second phase, the inductor (L) is discharged in the second phase, and the first capacitor (C F1 ) and the first capacitor (C _F1 ) are charged with energy in the form of current charged in the inductor (L). 2 By charging the capacitor (C _F2 ), the charge balance of the hybrid buck converter is maintained.

Additionally, the hybrid buck converter 110 can prevent a decrease in circuit efficiency by allowing the current flowing in the inductor (L) to flow in the first capacitor (C _F1 ) and the second capacitor (C _F2 ).

In another embodiment, the hybrid buck converter 110 may operate in the third phase, unlike the above-described embodiment. When operating in the third phase, the hybrid buck converter 110 may operate based on the voltage conversion rate (M) defined as the ratio of the input voltage (V _IN ) and the output voltage (V _OUT ) of the output stage.

For example, the voltage conversion rate (M) may be set to a first section and a second section that is set in a larger range than the first section.

For example, the first section may be set to 1/3<M<1/2, and the second section may be set to 1/2<M<1. In addition, in FIGS. 4A to 4C described below, the case of the first section in which the voltage conversion rate (M) is 1/3 < M < 1/2 will be described as an example, and in FIGS. 5A to 5C, the voltage conversion rate ( The case of the second section where M) is 1/2<M<1 will be described as an example. However, the value of the voltage conversion rate (M) will not be limited to this.

Figure 4a is a circuit diagram showing the operation in the 1-1 phase of the first section of the voltage conversion rate during the third phase operation of the hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 4A, for example, when the hybrid buck converter 110 operates in the third phase in the first section of the voltage conversion rate (M), in the 1-1 phase, the first transistor (TR ₁ ) and the third transistor ( TR ₃ ) and the sixth transistor (TR ₆ ) are turned on, and the second transistor (TR ₂ ) and the fourth to fifth transistors (TR ₄ and TR ₅ ) are turned off.

Specifically, in the 1-1 phase, the first transistor (TR ₁ ), the third transistor (TR ₃ ), and the sixth transistor (TR ₆ ) are turned on, and the inductor (L) and the second capacitor (C _F2 ) are charged. . On the other hand, the first capacitor C _F1 is discharged due to the turn-off of the second transistor TR ₂ and the fourth to fifth transistors TR ₄ TR ₅ .

Figure 4b is a circuit diagram showing the operation in the 1-2 phase of the first section of the voltage conversion rate during the third phase operation of the hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 4B, for example, the hybrid buck converter ₁₁₀ has a voltage conversion rate (M) of The 5 transistors (TR ₄ and TR ₅ ) are turned on, and the first transistor (TR ₁ ), the third transistor (TR ₃ ), and the sixth transistor (TR ₆ ) are turned off.

Specifically, in the 1-2 phase, the second transistor TR ₂ and the fourth to fifth transistors TR ₄ and TR ₅ are turned on, and the inductor L and the first capacitor C _F1 are charged. On the other hand, the second capacitor C _F2 is discharged due to the turn-off of the first transistor TR ₁ , third transistor TR ₃ , and sixth transistor TR ₆ .

Figure 4c is a circuit diagram showing the operation in the 1st to 3rd phases of the first section of the voltage conversion rate during the 3rd phase operation of the hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 4C, for example, when the hybrid buck converter 110 operates in the third phase in the first section with a voltage conversion rate (M), the second transistor (TR ₂ ) and the sixth transistor (TR 2 ) in the 1-3 phase. TR ₆ ) is turned on, and the first transistor (TR ₁ ) and the third to fifth transistors (TR ₃ , TR _{4 , and} TR ₅ ) are turned off.

Specifically, in the 1-3 phase, the second transistor (TR ₂ ) and the sixth transistor (TR ₆ ) are turned on and the inductor (L) is discharged. On the other hand, the first transistor (TR ₁ ) and the third to fifth transistors (TR ₃ , TR _4, TR ₅ ) are turned off, so the first capacitor (C _F1 ) and the second capacitor (C _F2 ) are charged. .

Figure 5 is a graph showing the states of elements in the first section of the voltage conversion rate during third-phase operation of the hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 5, when the hybrid buck converter 110 operates in the third phase, when the voltage conversion rate is 1/3 < M < 1/2, the hybrid buck converter 110 operates at the inductor (L) in the 1-1 phase. ) and the second capacitor (C _F2 ) are charged, and the first capacitor (C _F1 ) is discharged.

Additionally, the hybrid buck converter 110 charges the inductor (L) and the first capacitor (C _F1 ) and discharges the second capacitor (C _F2 ) in the 1-2 phase.

Additionally, in the first to third phases of the hybrid buck converter 110, the inductor L is discharged and the first capacitor C _F1 and the second capacitor C _F2 are charged.

Figure 6a is a circuit diagram showing the operation in the 2-1 phase of the second section of the voltage conversion rate during the third phase operation of the hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 6A, for example, when the hybrid buck converter 110 operates in the third phase in the second section with a voltage conversion rate (M), in the 2-1 phase, the first transistor (TR ₁ ) and the third to third The 5 transistors (TR ₃ , TR _4, TR ₅ ) are turned on, and the second transistor (TR ₂ ) and the 6th transistor (TR ₆ ) are turned off.

Specifically, in the 2-1 phase, the first transistor (TR ₁ ) and the third to fifth transistors (TR ₃ , TR ₄ , and TR ₅ ) are turned on and the inductor (L) is charged. On the other hand, the first capacitor (C _F1 ) and the second capacitor (C _F2 ) are discharged due to the turn-off of the second transistor (TR ₂ ) and the sixth transistor (TR ₆ ).

Figure 6b is a circuit diagram showing the operation in the 2-2 phase of the second section of the voltage conversion rate during the third phase operation of the hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 6B, for example, when the hybrid buck converter 110 operates in the third phase in the second section with a voltage conversion rate (M), in the 2-2 phase, the first transistor (TR ₁ ) and the third transistor ( TR ₃ ) and the sixth transistor (TR ₆ ) are turned on, and the second transistor (TR ₂ ) and the fourth to fifth transistors (TR ₄ and TR ₅ ) are turned off.

Specifically, in the 2-2 phase, the first transistor (TR ₁ ), the third transistor (TR ₃ ), and the sixth transistor (TR ₆ ) are turned on, and the inductor (L) and the first capacitor (C _F1 ) are discharged. . On the other hand, the second capacitor C _F2 is charged due to the turn-off of the second transistor TR ₂ and the fourth to fifth transistors TR ₄ and TR ₅ .

Figure 6c is a circuit diagram showing the operation in the 2-3 phase of the second section of the voltage conversion rate during the third phase operation of the hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 6C, for example, when the hybrid buck converter 110 operates in the third phase in the second section with a voltage conversion rate (M), the second transistor (TR ₂ ) and the fourth to fourth transistors are used in the 2-3 phase. The 5 transistors (TR ₄ and TR ₅ ) are turned on, and the first transistor (TR ₁ ), the third transistor (TR ₃ ), and the sixth transistor (TR ₆ ) are turned off.

Specifically, in the 2-3 phase, the second transistor TR ₂ and the fourth to fifth transistors TR ₄ and TR ₅ are turned on and the first capacitor C _F1 is charged. On the other hand, the inductor (L) and the second capacitor (C _F2 ) are discharged due to the turn-off of the first transistor (TR ₁ ), the third transistor (TR ₃ ), and the sixth transistor (TR ₆ ).

Figure 7 is a graph showing the states of elements in the second section of the voltage conversion rate during third-phase operation of the hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 7 , the hybrid buck converter 110 can prevent a decrease in circuit efficiency by allowing the current flowing in the inductor (L) to flow in the first capacitor (C _F1 ) and the second capacitor (C _F2 ).

In addition, when the hybrid buck converter 110 operates in the third phase, when the voltage conversion rate is 1/2 < M < 1, the inductor L is charged in the 2-1 phase, and the inductor L is charged in the 2-1 phase. The first capacitor (C _F1 ) and the second capacitor (C _F2 ) are discharged.

Additionally, in the hybrid buck converter 110, the inductor (L) and the first capacitor (C _F1 ) are discharged and the second capacitor (C _F2 ) is charged in the 2-2 phase.

Additionally, in the 2-3 phase of the hybrid buck converter 110, the inductor (L) and the second capacitor (C _F2 ) are discharged, and the first capacitor (C _F1 ) is charged.

When operating in the third phase, the hybrid buck converter 110 according to an embodiment rectifies AC power to convert direct current to DC power due to repeated charging or discharging of the first capacitor (C _F1 ) and the second capacitor (C _F2 ). It is possible to reduce the ripple voltage generated by some AC signals when generating.

Specifically, the hybrid buck converter 110 reduces the size of the alternating current signal by adding a first capacitor (C _F1 ) and a second capacitor (C _F2 ) in addition to the output capacitor (C ₀ ) essential for the buck converter circuit, thereby reducing the ripple voltage. can be reduced.

Figure 8 is a simplified diagram of an electronic device including a hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 8 , the electronic device 100 includes a hybrid buck converter 110, a voltage converter 120, a comparison unit 130, a control unit 140, and a mode selection unit 150.

The hybrid buck converter 110 is a direct current-direct current (DC-DC) conversion circuit that generates an output voltage (V _OUT ) that is lower than the input voltage (V _IN ).

The voltage converter 120 serves as a regulator that stabilizes the output voltage. For example, the voltage converter 120 may be implemented with a low drop-output (LDO), etc. The voltage converter 120 generates a regulated output voltage (V _ROUT ) and transmits it to the comparison unit.

The comparator 130 compares the regulated output voltage (V _ROUT ) provided from the voltage converter 120 and the reference voltage (V _REF ), generates a comparison result, and outputs it to the control unit 140 . In one embodiment, the comparator 130 may compare the output voltage (V _ROUT ) and the reference voltage (V _REF ) and provide the comparison result to the control unit 140. Accordingly, the control unit 140 may generate first to second phase signals for the second phase operation and first to third phase signals for the third phase operation that are adjusted according to the duty ratio.

Additionally, the comparison unit 130 may be implemented with various types of compensation circuits, for example, a Type-3 compensation circuit may be used.

The control unit 140 refers to the PWM (Pulse Width Modulation) signal (REF _OUT ), which is a comparison result, from the comparison unit 130, and refers to the mode selection signal (MODE _SEL ) of the mode selection unit 150 to determine the hybrid buck. Gate voltages (V _{SW1 to 6} ) connected to the gate of the transistor of the converter 110 are generated.

When the control unit 140 receives a signal corresponding to second-phase operation from the mode selection signal (MODE _SEL ), it can control the buck converter to operate in the second phase.

When operating in the second phase, the control unit 140 may operate according to first and second phase signals for the second phase operation. The length of the first phase signal and the second phase signal in the time domain is defined according to the comparison result received from the comparison unit 130.

For example, if the output voltage (V _OUT ) is higher than the reference voltage (V _REF ) according to the comparison result, the control unit 140 may operate according to the first phase signal by decreasing the duty ratio.

Additionally, when the output voltage (V _OUT ) is lower than the reference voltage (V _REF ) according to the comparison result, the control unit 140 may increase the duty ratio and operate according to the second phase signal.

When receiving a signal corresponding to third-phase operation from the mode selection signal MODE _SEL , the control unit 140 may control the buck converter to operate in the third phase.

When operating in the third phase, the control unit 140 may operate according to the first to third phase signals for the third phase operation. The time domain lengths of the first phase signal, second phase signal, and third phase signal are defined according to the comparison result received from the comparison unit 130.

For example, when the output voltage (V _OUT ) is higher than the reference voltage (V _REF ) according to the comparison result, the control unit 140 operates in the first to third phases with a length defined according to the reduced duty ratio. And the length of each phase is defined according to the comparison result as described above.

In addition, when the output voltage (V _OUT ) is lower than the reference voltage (V _REF ) according to the comparison result, the control unit 140 operates in the first to third phases having a length defined according to the increased duty ratio, The length of each phase is defined according to the comparison result as described above.

In one embodiment, the control unit 140 controls the first DTC clock signal (DTC _CK1 ) and the second DTC clock signal, which are the sections in which the plurality of transistors (TR _{1 to TR 6} ) included in the hybrid buck converter 110 are all turned off. (DTC _CK2 ) can be generated.

Specifically, the control unit 140 may generate a first DTC clock signal (DTC _CK1 ) corresponding to the first phase in a second or third phase operation.

Additionally, the control unit 140 may generate a second DTC clock signal (DTC _CK2 ) corresponding to the second phase in the second or third phase operation.

In addition, the control unit 140 copies the first DTC clock signal (DTC _CK1 ) or the second DTC clock signal (DTC _CK2 ) corresponding to the third phase and generates the third DTC clock corresponding to the third phase in the third phase operation. A signal (DTC _CK3 ) can be generated.

The control unit 140 converts the lengths of the first DTC clock signal (DTC _CK1 ), the second DTC clock signal (DTC _CK2 ), and the third DTC clock signal (DTC _CK3 ) to be the same, and operates according to the identically converted clock signal. Gate voltage (V _SW1~6 ) can be applied.

The mode selection unit 150 is connected to the control unit 140 and can transmit a mode selection signal (MODE _SEL ) to the control unit 140.

The mode selection unit 150 may generate a mode selection signal (MODE _SEL ) corresponding to a second phase or third phase operation.

The electronic device 100 according to one embodiment is configured to control the inductor (L), the first capacitor (C _F1 ), and the second capacitor (C _F2 ) included in the hybrid buck converter 110 with the second to third phases. The first to sixth gate voltages (V _{SW1 to SW6) of the plurality of transistors (TR 1 to} TR 6) corresponding to the phase operation can be controlled.

Figure 9 is a circuit showing the structure of a hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 9, the electronic device 100 includes a hybrid buck converter 110, a voltage converter 120, a comparison unit 130, a control unit 140, a mode selection unit 150, and a signal copying unit 160. Includes.

The hybrid buck converter 110 uses an inductor (L), a first capacitor (C _F1 ), a second capacitor (C _F2 ), and a plurality of transistors (TR _{1 to 6} ) to generate an output voltage lower than the input voltage (V _IN ). (V _OUT ) can be generated.

The hybrid buck converter 110 is connected to the voltage converter 120 and can transmit the generated output voltage (V _OUT ) to the voltage converter 120.

The voltage converter 120 generates a regulated output voltage (V- _ROUT ) and transmits it to the comparison unit 130.

The comparator 130 compares the regulated output voltage (V- _ROUT ) provided by the voltage converter 120 and the reference voltage (V- _REF ) to generate a PWM signal (REF _OUT ) and provide it to the control unit 140. You can.

The control unit 140 includes a DTC generator and gate driver 160, and a signal copy unit 170.

The DTC generator and gate driver 160 receives the PWM signal (REF _OUT ), which is a comparison result, from the comparison unit 130, and receives the mode selection signal (MODE _SEL ) from the mode selection unit 150.

The DTC generator and gate driver 160 defines the time domain phase length of the first to third phase signals for the second to third phase operations with reference to the PWM signal (REF _OUT ) and the mode selection signal (MODE _SEL ). can do.

The DTC generator and gate driver 160 may generate a DTC, which is a period in which a plurality of transistors (TR _{1 to TR 6} ) included in the hybrid buck converter 110 are all turned off, and transmit it to the signal copying unit 170.

The signal copy unit 170 copies the received DTC signal and transmits it to the DTC generator and gate driver 160.

The DTC generator and gate driver 160 generates a signal corresponding to the time domain phase length defined in the plurality of transistors (TR _{1 to 6} ) based on the PWM signal (REF _OUT ), the mode selection signal (MODE _SEL ), and the copied DTC signal. The first to sixth gate voltages (V _{SW1 to SW6} ) are applied.

The mode selection unit 150 may generate a mode selection signal (MODE _SEL ) corresponding to the second or third phase operation and transmit it to the control unit 140.

Figure 10 is a graph exemplarily showing the power conversion efficiency of a hybrid buck converter according to an embodiment of the present invention.

Referring to FIG. 10, the hybrid buck converter 110 according to the above-described embodiment converts the maximum voltage stress applied to the plurality of transistors (TR _{1 to 6} ) into the output voltage (V _OUT ) in the second to third phase operation. By fixing it, the area of multiple transistors (TR _{1 to TR 6} ) can be reduced.

As a result, the hybrid buck converter 110, which reduced the area of a plurality of transistors (TR _{1 to 6} ), has a DCR (DC Resistance) of 250 m and a simulation result showing a high efficiency of more than 90% even when the current is within the range of 0.2 to 1.6 A. can be obtained.

The above-described details are specific embodiments for carrying out the present invention. In addition to the above-described embodiments, the present invention will also include embodiments that can be simply changed or easily changed in design. In addition, the present invention will also include technologies that can be easily modified and implemented using the embodiments. Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the claims and equivalents of the present invention as well as the claims described later.

100: electronic device 140: control unit
110: Hybrid buck converter 150: Mode selection unit
120: Voltage conversion unit 160: DTC generator and gate driver
130: comparison unit 170: signal copy unit

Claims (11)

In the hybrid buck converter,
inductor;
a first capacitor connected to one end of the inductor;
a second capacitor connected to the other end of the inductor; and
A plurality of transistors connected to at least one of the inductor, the first capacitor, and the second capacitor and turned on or off by a gate voltage,
In the first phase set according to the duty ratio when the hybrid buck converter operates in the second phase, the inductor is charged and the first capacitor and the second capacitor are discharged, and in the first phase set according to the duty ratio when the hybrid buck converter operates in the second phase. In phase 2, the inductor is discharged and the first capacitor and the second capacitor are operated to charge. According to paragraph 1,
The plurality of transistors include first to sixth transistors,
In the first phase set according to the duty ratio during the second phase operation of the hybrid buck converter, the first transistor and the third to fifth transistors are turned on, and the second transistor and the sixth transistor are turned off. become,
In the second phase of the hybrid buck converter set according to the duty ratio during the second phase operation, the second transistor and the sixth transistor are turned on, and the first transistor and the third to fifth transistors are turned off. Hybrid buck converter. According to paragraph 1,
The plurality of transistors include first to sixth transistors,
When the hybrid buck converter operates in the third phase in the first section of the voltage conversion rate, the inductor and the second capacitor are charged and the first capacitor is discharged in the 1-1 phase,
When the voltage conversion rate operates in the third phase in the first section, the inductor and the first capacitor are charged and the second capacitor is discharged in the 1-2 phase,
When the voltage conversion rate operates in the third phase in the first section, the inductor is discharged and the first capacitor and the second capacitor are charged in the 1-3 phase. According to paragraph 3,
When the hybrid buck converter operates in the third phase in the first section of the voltage conversion rate, the first transistor, the third transistor, and the sixth transistor are turned on in the 1-1 phase, and the second transistor and The fourth to fifth transistors are turned off,
In the 1-2 phase, the second transistor and the fourth to fifth transistors are turned on, the first transistor, the third transistor, and the sixth transistor are turned off,
In the 1-3 phase, the second transistor and the sixth transistor are turned on, and the first transistor and the third to fifth transistors are turned off. According to paragraph 1,
The plurality of transistors include first to sixth transistors,
When the hybrid buck converter operates in the third phase in the second section of the voltage conversion rate, the inductor is charged and the first capacitor and the second capacitor are discharged in the 2-1 phase,
When the voltage conversion rate operates in the third phase in the second section, the inductor and the first capacitor are discharged and the second capacitor is charged in the 2-2 phase,
When the voltage conversion rate operates in the third phase in the second section, the first capacitor is charged and the inductor and the second capacitor are discharged in the 2-3 phase. According to clause 5,
When the hybrid buck converter operates in the third phase in the second section of the voltage conversion rate, the first transistor and the third to fifth transistors are turned on in the 2-1 phase, and the second transistor and the first transistor are turned on. 6 The transistor is turned off,
In the 2-2 phase, the first transistor, the third transistor, and the sixth transistor are turned on, the second transistor and the fourth to fifth transistors are turned off,
In the 2-3 phase, the second transistor and the fourth to fifth transistors are turned on, and the first transistor, the third transistor, and the sixth transistor are turned off. According to paragraph 1,
The plurality of transistors include first to sixth transistors,
One end of the first transistor is connected to a first node connected to the first capacitor, and the other end is connected to an input node where an input voltage is input,
The second transistor has one end connected to a second node connected to the first capacitor and the other end connected to ground connected to the ground,
The third transistor has one end connected to the second node and the other end connected to an output node that outputs an output voltage,
The fourth transistor has one end connected to a third node connected to the inductor and the other end connected to the output node,
The fifth transistor has one end connected to the fourth node connected to the second capacitor and the other end connected to ground connected to the ground,
A hybrid buck converter wherein one end of the sixth transistor is connected to the fourth node and the other end is connected to the output node. In clause 7,
The first transistor, the third transistor, and the sixth transistor are composed of PMOS transistors,
A hybrid buck converter in which the second transistor and the fourth to fifth transistors are configured as NMOS transistors. In electronic devices,
A hybrid buck converter that generates an output voltage by lowering the input voltage;
A voltage converter connected to the hybrid buck converter and generating a regulated output voltage;
a comparison unit connected to the voltage converter and generating a pulse width modulation signal by comparing the regulated output voltage and a reference voltage;
a control unit that receives the pulse width modulation signal and applies a gate voltage to a plurality of transistors included in the hybrid buck converter for second or third phase operation of the hybrid buck converter; and
An electronic device comprising a mode selection unit that generates a mode selection signal corresponding to the second phase or the third phase operation. According to clause 9,
The control unit includes a dead time generator and a gate driver that receives the pulse width modulation signal and the mode selection signal, generates a dead time signal, and applies the gate voltage,
The gate voltage is applied to the plurality of transistors as a voltage corresponding to a length in the time domain defined. According to clause 10,
The electronic device further includes a signal copying unit where the control unit receives the dead time signal, copies the dead time signal, and transmits it to a dead time generator and a gate driver.