KR101750365B1 - Reset Method and Apparatus For portable Device - Google Patents

Abstract

The present invention relates to a reset function of a portable terminal, and more particularly, to a portable terminal having a PMIC (Power Management IC) without a manual reset function, the resetting function comprising an input unit for generating a specific input signal for reset according to a user input, A reset unit for generating a manual reset input signal in response to the input of the manual reset input signal and for blocking supply of battery power to the PMIC by using a signal generated during an operation maintenance period of the portable terminal and the manual reset input signal, And a power supply unit for supplying power.

Description

[0001] The present invention relates to a reset method and apparatus for a portable terminal,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a reset of a portable terminal, and more particularly, to a reset method and apparatus for a portable terminal that can perform a manual reset function by controlling a PMIC (Power Management IC)

In addition to the initial simple voice call and short message transmission functions, the portable terminal has various functions such as a video call, an electronic note function, and an internet function through the rapid technological development. In addition, the portable terminal utilizes advanced hardware and software in order to support various functions. That is, the conventional portable terminal supports various application programs based on hardware having high processing capability.

However, it is virtually impossible to optimize for the various parameters that arise in the context of executing the function even if the hardware and the software designed for it have appropriate specifications. Therefore, even if a portable terminal equipped with hardware and software having the highest performance, various errors occur in the execution of the function. If an error occurs in the process of manufacturing the portable terminal, the error can be corrected and corrected by the maker and the designer. However, in the state where the manufacture of the portable terminal is completed or the state where the portable terminal is sold, the error correction by the maker or the designer is limited. To solve such a problem, a function of resetting the portable terminal is added.

However, there is a case where the reset function of the portable terminal is not supported according to the hardware specification of the portable terminal. In other words, since there are components that can not perform a manual reset function in the conventional portable terminals, it is necessary to manufacture a portable terminal capable of performing a proper reset function at a desired time regardless of a specific accessory of the terminal.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a reset method of a mobile terminal supporting a reset function by adding a circuit to a mobile terminal equipped with a PMIC without a manual reset function And an apparatus.

It is another object of the present invention to provide a reset method and apparatus for a mobile terminal that can suppress leakage current when a reset function of a PMIC without a manual reset function is supported.

It is another object of the present invention to provide a method and apparatus for resetting a portable terminal that can stably operate a terminal even in a specific low temperature state when a reset function of a PMIC without a manual reset function is supported.

According to another aspect of the present invention, there is provided a method of resetting a portable terminal, the method comprising: resetting a reset signal by a reset circuit according to whether a specific input signal for resetting is generated, in a portable terminal having a PMIC (Power Management IC) And a reset control circuit for supplying a signal having a high level during the operation maintenance period of the portable terminal and a manual reset input signal when the specific input signal is generated to the PMIC, And a control process of controlling a supply state or a cutoff state of the power supply.

In addition, the method of resetting the portable terminal may include supplying the battery power to the PMIC using either the pull-up of the battery power source or the pull-up of the input / output power source generated by the PMIC based on the battery power source before the manual reset input signal is generated The method may further include the step of activating a switch of a circuit designed to supply the battery power to the PMIC in response to the activation of the switch. The battery power may be supplied to the reset circuit for driving the reset circuit Output power generated by the PMIC based on the battery power to the reset circuit for driving the reset circuit; The process may further include any one of the following processes.

In addition, the control process may be performed by disposing an analog switch between the reset circuit and the reset control circuit, the analog switch being driven by the input / output power source generated by the PMIC using battery power, based on a signal supplied in a high state Supplying the battery power to the PMIC based on a signal supplied in a high state and a pull-up of the battery power during operation of the portable terminal; And supplying a manual reset input signal of the reset circuit to the reset control circuit through the analog switch based on a signal supplied in a high state during operation of the portable terminal and a manual reset input signal of the reset circuit , When the portable terminal is operated Controlling the PMIC to supply the battery power to the PMIC based on a signal supplied in this state and a manual reset input signal of the reset circuit; A step of supplying the manual reset input signal in a low state to the reset control circuit and a step of deactivating switches constituting the reset control circuit in accordance with the manual reset input signal to block a path through which the battery power is supplied to the PMIC . ≪ / RTI >

Here, the resetting method of the portable terminal may include a step of supplying the input / output power generated by the PMIC using the battery power by pulling up between the analog switch and the reset control circuit, and a step of supplying the pull-up of the battery power to the reset control circuit And a step of disposing a capacitor on the passageway to temporarily store the power supplies and supplying power stored when the battery is shut down.

In addition, the method of resetting the portable terminal may include the steps of driving a counter after the power supply of the PMIC is cut off to supply the output of the counter to the reset control circuit, supplying the pull-up of the battery power to the reset control circuit, And resetting the power supply of the PMIC by using the output of the counter and the pull-up of the battery power. When supplying the pull-up of the battery power between the reset circuit and the reset control circuit, Supplying the driving power of the specific input signal to the battery power; and level shifting the signal level of the specific input signal to the signal level of the battery power.

According to another aspect of the present invention, there is provided a portable terminal reset device having a PMIC (Power Management IC) having no manual reset function. The portable terminal includes an input unit for generating a specific input signal for reset according to a user input, A reset unit for generating a manual reset input signal and for blocking supply of battery power to the PMIC using a signal generated during an operation maintenance period of the portable terminal and the manual reset input signal, And the like.

As described above, according to the method and apparatus for resetting the portable terminal of the present invention, the user can perform a manual reset function through a specific signal input even if the terminal does not have a separate manual reset function.

In addition, according to the method and apparatus for resetting the portable terminal of the present invention, the present invention can prevent the leakage current generated during the manual reset function and reliably operate the reset function even in a specific temperature condition.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a schematic configuration of a mobile terminal according to an embodiment of the present invention;
2 is a detailed circuit diagram of a reset unit according to the first embodiment of the present invention,
3 is a detailed circuit diagram of a reset circuit according to a second embodiment of the present invention,
4 is a detailed circuit diagram of a reset unit according to a third embodiment of the present invention,
5 is a detailed circuit diagram illustrating a circuit configuration of a reset unit according to a fourth embodiment of the present invention,
6 is a diagram for explaining leakage current generation in the reset section circuit of the present invention,
7 is a diagram showing a switch configuration for suppressing leakage current generation in the reset circuit of the present invention,
8 is a graph showing characteristic curves of input voltage versus output current according to temperature,
9 is a graph showing characteristic curves of DC current gain vs. output current according to temperature,
10 is a diagram for explaining current characteristics in the reset control circuit of the present invention,
11 is a diagram illustrating a reset unit of the present invention for stable operation support in a specific temperature condition,
12 illustrates another embodiment of the reset portion of the present invention for stable operation support in a specific temperature situation;

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the embodiments of the present invention, descriptions of techniques which are well known in the technical field of the present invention and are not directly related to the present invention will be omitted. In addition, detailed description of components having substantially the same configuration and function will be omitted.

For the same reason, some of the elements in the accompanying drawings are exaggerated, omitted, or schematically shown, and the size of each element does not entirely reflect the actual size. Accordingly, the present invention is not limited by the relative size or spacing depicted in the accompanying drawings.

FIG. 1 is a block diagram of a configuration of a portable terminal according to an exemplary embodiment of the present invention. Referring to FIG.

1, the portable terminal 100 of the present invention includes a configuration of an input unit 110, a power unit 120, a PMIC 130, a reset unit 170, and a control unit 160, (170) may include a reset circuit (140), a reset control circuit (150), and other circuitry.

The portable terminal 100 having the above-described structure supports the resetting of the terminal by interrupting and resuming the power supply of the PMIC 130 according to a specific input signal generated from the input unit 110. The portable terminal 100 controls the reset of the PMIC 130 using an input signal input from the input unit 110 and a reset control circuit 150 disposed between the PMIC 130 and the power unit 120 . Hereinafter, each configuration will be described in detail.

The input unit 110 generates various input signals required for driving and operating the portable terminal 100. The input unit 110 may include at least one of a plurality of key buttons, a keypad, a touchpad, . ≪ / RTI > In the following description, the input unit 110 has a plurality of key buttons. When the input unit 110 is configured in the form of a key button, the input unit 110 may generate a specific input signal by applying pressure to a specific key button by the user. The input signal generated by the input unit 110 may be transmitted to the control unit 160, the reset circuit 140 and the reset control circuit 150, and particularly to the reset circuit 140 and the reset control circuit 150 The input signal may be an input signal corresponding to a specific key button. For example, the input signal transmitted to the reset circuit 140 and the reset control circuit 150 is a signal generated according to a power key button input for controlling power turn-on and turn-off of the portable terminal 100 And may be a signal generated from at least one of the other key buttons. Accordingly, the user of the portable terminal 100 can operate the power reset key of the input unit 110 of the portable terminal 100, which is operated to activate the manual reset function according to the embodiment of the present invention, Button can be performed simultaneously. Herein, the generation of the input signal for supporting the manual reset function of the present invention will be described by taking as an example a simultaneous input of a power key button and a specific key button. However, the present invention is not limited to this, and an input signal generation algorithm for activating the manual reset function may be designed May be replaced by other key buttons depending on the intent of the designer to do so. In addition, the input signal generation for activating the manual reset function may be replaced with signals generated based on the touch pad, the touch screen, or the side key as well as the signals generated from the key buttons. Therefore, the input signal generated by the power key button and the specific key button should be understood as a specific input signal allocated for the manual reset.

The power supply unit 120 supplies power to the portable terminal 100. The power supply unit 120 may be designed to be built in the portable terminal 100 or may be designed to be detachable. When the portable terminal 100 is designed as a removable type, the portable terminal 100 may further include a signal line for providing a space for inserting and inserting the power source unit 120 and receiving power from the inserted power source unit 120. The power supply unit 120 may be configured as a rechargeable secondary battery as well as a primary battery. The power supply unit 120 of the present invention can deliver power to the PMIC 130 via the reset control circuit 150. [ Accordingly, the power supplied from the power supply unit 120 may be transmitted to or blocked from the PMIC 130 under the control of the reset control circuit 150.

The PMIC 130 generates various types of power that can operate various configurations of the portable terminal 100 by using the power supplied from the power supply unit 120. The PMIC 130 may include a power source for operating the controller 160, a power source for driving the input unit 110, and a power source for operating the configuration of the portable terminal 100, such as a camera, an MP3 module, Can be generated. Since the power generated by the PMIC 130 varies in the form of power required for each configuration of the portable terminal 100, the magnitude of the power supplied to each of the configurations described above may vary, for example, . Particularly, the PMIC 130 of the present invention maintains the turn-off state of the mobile terminal 100 when the power supply from the power source unit 120 is cut off, or receives power from the power source unit 120, And can support the manual reset function of the mobile terminal 100 by changing the state to the turn-on state after the turn-off state under the control of the reset control circuit 150. [ The PMIC 130 described above can not support the manual reset function by itself.

The reset circuit 140 is disposed between the input unit 110 and the reset control circuit 150 and generates a reset instruction word according to a reset input signal input from the input unit 110, . The reset circuit 140 may be formed in a chip form. The input terminal may be connected to the input unit 110, and the output terminal may be connected to the reset control circuit 150. The shape and function of the reset circuit 140 will be described in more detail below with reference to the drawings.

The reset control circuit 150 is disposed between the reset circuit 140 and the power supply unit 120 and is disposed between the power supply unit 120 and the PMIC 130, And controls so as to be supplied to the PMIC 130 in accordance with the output of the reset circuit 140 or to be blocked. The reset control circuit 150 may be configured to maintain the power of the power source unit 120 to be continuously transmitted to the PMIC 130 when the mobile terminal 100 is driven. When the input signal for activating the reset function is received from the input unit 110, the reset control circuit 150 temporarily cuts off and re-supplies power to the PMIC 130 to support the reset of the mobile terminal 100 have. The reset control circuit 150 may further include a counter for re-supplying the shutoff power source or may use the output of a separate counter provided in the portable terminal 100. [ The detailed circuit configuration of the reset control circuit 150 will be described in detail with reference to the drawings described later.

The controller 160 controls the power of various sizes and types transmitted from the PMIC 130 to be transmitted to the respective components of the portable terminal 100. The controller 160 receives various input signals from the input unit 110 while the portable terminal 100 is operating, and controls the currently activated application programs to operate according to the input signals. Since the controller 160 and the reset circuit 140 and the reset control circuit 150 of the present invention are independently arranged, the controller 160 can operate independently of the manual reset function support of the present invention . Even so, the controller 160 must receive power from the PMIC 130 to perform an operation required for driving the portable terminal 100. [ Therefore, when the power supply 120 supplied to the PMIC 130 is cut off by the reset control circuit 150, the controller 160 may also be stopped. Meanwhile, the controller 160 may provide a counter output to the reset control circuit 150 to supply power to the PMIC 130 again. The counter may be designed as a counter that operates even when the power supply unit 120 is temporarily stopped, and may be designed as a portable terminal 100 other than the controller 160.

As described above, the portable terminal 100 according to the embodiment of the present invention includes the reset circuit 140 and the reset control circuit 150 between the input unit 110, the PMIC 130, and the power supply unit 120, It is possible to perform a manual reset through the power supply interruption of the PMIC 130 according to an input signal generated from the power supply 110. Hereinafter, detailed configurations of the reset circuit 140 and the reset control circuit 150 will be described in detail with reference to the drawings.

FIG. 2 is a circuit diagram illustrating a configuration and a reset method of the reset unit 170 according to an embodiment of the present invention.

2, the reset unit 170 includes a reset circuit 140 and a reset control circuit 150. An input signal for a manual reset from the input unit 110 is supplied to the reset circuit 140 and the reset circuit 140. [ The reset circuit 140 supplies the manual reset signal MR_RESET to the reset control circuit 150 and consequently the reset control circuit 150 supplies the PMIC 130 with the power supply 120 may be cut off. Accordingly, the reset unit 170 may stop the power supply to the control unit 160 and switch the portable terminal 100 to the turn-off state, thereby supporting the manual reset function. Hereinafter, the respective circuit configurations and circuit operations of the reset unit 170 will be described in more detail.

The input terminal of the reset circuit 140 constituting the reset unit 170 is connected to the key input circuit 111 of the input unit 110 and the output terminal of the reset circuit 140 is connected to a reset control Circuit 150 is disposed. The reset control circuit 150 includes a first switch A to which the output of the reset circuit 140 is transmitted, a second switch B whose activation is determined depending on whether the first switch A is activated, An OR gate 151 (or an OR-ING circuit, which will be described with reference to an OR gate in the following description) for transmitting any one of the specific signals generated from the terminal 100 to the second switch B, A third switch C for receiving the specific signal according to the activation of the second switch B and operating on the basis of the third signal, And a fourth switch (D) for controlling the supply of the voltage. A power supply 120 may be connected to one side of the fourth switch D and a PMIC 130 may be connected to the other side. The fourth switch D operates according to the state of the third switch C so that the battery power VBAT of the power supply unit 120 can be supplied to or disconnected from the PMIC 130. [ The input terminal of the reset control circuit 150 is configured by the OR gate 151 to add various power-on events such as charger insertion and USB jig insertion in order to support operation similar to ON_SW signal generation. Here, the ON_SW signal generating operation may mean that a switch for supplying power is operated according to the generation of a signal or the like according to the power key input. The power key input signal nPower may use an inverted signal of the signal corresponding to the power key input to output the manual reset signal MR_RESET of the reset circuit 140 as a low signal. The PS_HOLD signal during the input of the OR gate 151 provides a continuous high state signal at the time when the portable terminal 100 operates. That is, the PS_HOLD signal is a signal indicating that the power supply is maintained, and provides a high state signal while the portable terminal 100 is operating. The ETC signal may refer to a signal such as a charger or a USB jig insertion described above as a guitar signal, and may mean a counter output or the like. The first switch A and the third switch C may be NPN type transistors and the second switch B and the fourth switch D may be PNP type transistors. However, the present invention is not limited to the switch type described above, and various types of switch type arrangements may be substituted for the above-described switches.

An input / output power supply (VCC_IO) is supplied as driving power for driving the reset circuit (140). The input / output power source VCC_IO may be a power source generated by the PMIC 130 for inputting / outputting battery power VBAT supplied from the power source unit 120 to / from the portable terminal 100. The reset unit 170 includes a pull-up resistor E connected in parallel between the reset circuit 140 and the first switch A. A power source 120 is connected to one end of the pull- .

On the other hand, when the built-in resistance of the first switch A is present, since the voltage value between the base and the emitter of the first switch A is small and the current does not flow to the first switch A It is preferable that the pull-up resistance E be within 10% of the built-in resistance value because a state in which power is not supplied to the portable terminal 100 may occur. Here, the pull-up resistor E may vary depending on the presence and size of a built-in resistor of the first switch A.

The reset unit 170 has a key input circuit 111 for supplying a key power source VCC_KEY to the input unit 110, a manual reset input signal generated by the key input circuit 111, The power key input signal nPower and the specific key input signal ANY_KEY are transmitted to the reset circuit 140. Here, the key input circuit 111 may be configured such that a button resistance RB is connected to each key button. The base of the first switch A is connected to the output terminal of the reset circuit 140. A pull-up resistor E and a battery power supply VBAT are connected between the output terminal of the reset circuit 140 and the base of the first switch A. [ Can be connected in parallel. Therefore, when there is no output of the reset circuit 140, the first switch A can be kept in the turn-on state because the battery power VBAT is supplied to the base of the first switch A by default. The second switch B having a different characteristic from the first switch A is connected to the output of the OR gate 151 to the base of the third switch C, As shown in FIG. The third switch C is activated by the output of the OR gate 151 input to the base and consequently the fourth switch D connected to the collector terminal of the third switch C is connected to the battery power source VBAT < / RTI > The battery power source VBAT is continuously supplied to the PMIC 130 while the manual reset signal MR_RESET is not supplied to the base of the first switch A at the output terminal of the reset circuit 140, Various power supplies necessary for driving the portable terminal 100 can be generated using the supplied battery power VBAT and supplied to the respective components. Here, when the key power source VCC_KEY generated by the PMIC 130 is supplied to the input unit 110, the input / output power source VCC_IO is supplied to the reset circuit 140 to support the respective configurations.

The reset circuit 140 outputs a manual reset signal MR_RESET having a low signal type to the first switch A when the power key input signal nPower and the specific key input signal ANY_KEY are input from the input unit 110. [ To the base of the < / RTI > Since the pull-up resistor E is connected in parallel to the signal line to which the manual reset signal MR_RESET is transmitted and the battery power supply VBAT is connected to one end of the pull-up resistor E, While the reset signal MR_RESET is not generated, the battery power source VBAT is supplied to the base of the first switch A so that the first switch A can be maintained in the turn-on state. When the manual reset signal MR_RESET is supplied to the base end of the first switch A, the first switch A is inactivated or turned off, As shown in FIG. Then, the output of the OR gate 151 is not transmitted through the second switch B, and as a result, the third switch C can be transited to the inactive state. The fourth switch D connected to the third switch C is also deactivated so that the battery power VBAT is not supplied to the PMIC 130 and the third switch C is inactivated. The load resistor R is connected between the battery power source VBAT and the collector terminal of the third switch C so that the fourth switch D is connected to the battery power source VBAT when the third switch C is activated, To the PMIC 130. [0033]

The PMIC 130 stops supply of the input / output power source VCC_IO or the key power source VCC_KEY and consequently the input / output power source VCC_IO for driving the reset circuit 140 ) Supply is stopped. Therefore, the reset circuit 140 can not generate a separate output signal. On the other hand, if the battery is continuously connected to the portable terminal 100, the first switch A may be switched to the active state again via the battery power supply VBAT and the pull-up resistor E. A separate counter output for supporting the manual reset function is connected to the OR gate 151 so that the third switch C is activated through the second switch B so that eventually the battery power VBAT To the PMIC 130 so that the power supply to the portable terminal 100 can be resumed. Here, the counter may be arranged to use any one of various counters provided in the mobile terminal 100 or separately allocate the input to the OR gate 151 to generate an input signal after a predetermined time elapses. That is, the counter may be designed to count a predetermined time after a specific key input signal ANY_KEY and a power key input signal nPower have occurred. When the ON_SW is a non-inverted signal of a signal according to the power key input, , The power supply can be resumed by activating the second switch (B). Meanwhile, the battery power VBAT may be used as a power source of the PMIC 130 and a power source VBAT_PMIC which is an input source of the PMIC BUCK converter and the LDOs (Low Drop Outs). The power key input signal nPower may be an inverted signal generated by the PMIC 130 to which the ON_SW signal is input according to the input / output level of the portable terminal. Therefore, the low input of the power key input signal nPower and the low input of the specific key input signal ANY_KEY are supplied to the reset circuit 140, and the reset circuit 140 outputs the low output to the first switch A As shown in Fig.

As described above, the reset unit 170 according to the embodiment of the present invention can support the reset function of the mobile terminal 100 by interrupting the power supply to the PMIC 130 that does not support the manual reset function. The reset unit 170 of the present invention controls the battery power VBAT and the pull-up resistor E to supply the battery power VBAT to the PMIC 130 until an input signal for manual reset is generated And the mobile terminal 100 can support the default voltage for transitioning to the turn-on state after the transition to the turn-off state.

On the other hand, the reset unit 170 of the present invention having the above-described circuit configuration is provided with an internal current (Vcc) based on the potential difference between the battery power source VBAT of the pull-up resistor E and the input / output power source VCC_IO used for driving the reset circuit 140 Leakage may occur. To solve this problem, the following circuit configuration is possible.

FIG. 3 is a schematic circuit diagram illustrating a configuration and a reset method of the reset unit 170 according to the second embodiment of the present invention.

3, the reset unit 170 according to the second embodiment of the present invention includes a power level input signal nPower input from the input unit 110 and a level shifter inputting a specific key input signal ANY_KEY A reset circuit 140 for receiving the output of the level shifter 171 as an input and a reset control circuit 150 for receiving an output of the reset circuit 140. The reset circuit 140 Up resistor (E) and a battery power supply (VBAT), the outputs of which are connected in parallel to a signal line that is transmitted to the reset control circuit (150). The level shifter 171 is configured to transfer the level of the input / output power source VCC_IO to the battery power source VBAT. The reset circuit 140 may use battery power (VBAT) as a driving power source. Accordingly, the level shifter 171 can convert the two input signals of the input / output power source (VCC_IO) level, that is, the power key input signal nPower and the specific key input signal ANY_KEY to match the input / output level of the reset circuit 140 have. When the power key input signal nPower and the specific key input signal ANY_KEY are transmitted, the reset unit 170 of the present invention having the above-described configuration switches the input / output level of the corresponding input signal to the battery power VBAT) level and transmits it to the reset circuit 140. The reset circuit 140 may transmit a manual reset signal MR_RESET to the base of the first switch A when receiving an input signal instructing a manual reset from the level shifter 171. [ At this time, the manual reset signal MR_RESET output from the reset circuit 140 may be a low signal corresponding to the battery power level. As a result, the manual reset signal output from the reset circuit 140 transitions the first switch A to the inactive state with the low voltage, sequentially interrupts the output of the OR gate 151 of the second switch B, The power supply to the PMIC 130 is cut off by performing inactivation of the switch C and interrupting supply of the battery power (VBAT) of the fourth switch (D).

However, in the circuit configuration as described above, the pull-up of the battery power source VBAT during the operation of the portable terminal 100 may cause current consumption due to the built-in resistance of the pull-up resistor E and the first switch A have. In order to solve such a problem, a circuit configuration as shown in FIG. 4 is possible.

FIG. 4 is a circuit diagram illustrating a configuration of a reset unit 170 and a reset method according to a third embodiment of the present invention.

4, the reset unit 170 according to the third embodiment of the present invention includes a reset circuit 140, an analog switch 173 located at the output terminal of the reset circuit 140, Up resistor (E) connected in parallel between the analog switch (173) and the first switch (A) of the reset control circuit (150), and a reset control circuit A power supply VCC_IO and a capacitor Cap connected in parallel may be disposed.

The reset circuit 140 according to the third embodiment of the present invention is driven by the input / output power supply VCC_IO. The reset circuit 140 may transmit a manual reset signal MR_RESET to the analog switch 173 when a power key input signal nPower and a specific key input signal ANY_KEY are transmitted from the input unit 110. [ The input / output power supply VCC_IO is a power generated by the PMIC 130 using the battery power VBAT.

The analog switch 173 may include two selection inputs S1 and S2, an output OUT and a selection SEL. The analog switch 173 may be driven by an input / output power supply VCC_IO provided by the PMIC 130, similar to the reset circuit 140. The first selection input terminal S1 is connected to the output of the reset circuit 140 to receive a corresponding manual reset signal MR_RESET when the manual reset signal MR_RESET of the reset circuit 140 is generated. The second selection input S2 is connected through the pull-up resistor H to the battery power supply VBAT. The PS_HOLD signal having a high state is continuously input to the selected terminal SEL when the mobile terminal 100 is being driven. The analog switch 173 turns on the battery power VBAT supplied from the second selection input terminal S2 through the output terminal OUT to the reset control circuit 150). When the manual reset signal MR_RESET is inputted to the first selection input terminal S1, the analog switch 173 outputs the manual reset signal MR_RESET to the first reset input terminal S1 of the reset control circuit 150 through the output terminal OUT Can be outputted to the switch A. The output terminal OUT of the analog switch 173 is connected to the base of the first switch A of the reset control circuit 150. The input / output power supply (VCC_IO) and the pull-up resistor (E) are connected in parallel between the output terminal (OUT) and the first switch (A).

Since the PS_HOLD signal is low when the initial power is supplied or the portable terminal 100 is not driven while the power is supplied again after the reset, the analog switch 173 of the present invention has the second selection input terminal S2 to the base of the first switch A so as to maintain the default high state. The output terminal OUT of the analog switch 173 supports a state in which the output of the first selected input terminal S1 can be supplied to the first switch A when the power is supplied and the PS_HOLD signal transitions to the high state. In this process, since the reset circuit is in a state before generating the manual reset signal, the input / output power supply VCC_IO connected to the base of the first switch A maintains a high state, The first switch A can be kept in an active state before the manual reset signal MR_RESET is transmitted to the first selection input S1. Herein, the pull-up resistor E can prevent a phenomenon of being interrupted while the power is turned on due to a break-before-make-feature characteristic of the analog switch 173. In more detail, when the PS_HOLD signal transitions from a low state to a high state, a switching operation occurs from the second selected input terminal S2 to the first selected input terminal S1. At this time, the current is temporarily cut off on the output (OUT) side of the analog switch 173, so that the first switch A is momentarily turned off and the PS_HOLD signal is transited to the low again. have. The pull-up resistor E prevents the turn-on and turn-off repetition of the first switch A, which may be caused by the switching operation of the analog switch 173, and supports the turn- do.

On the other hand, the input / output power supply VCC_IO supplied to the analog switch 173 is an LDO power supply which is turned on only when the initial portable terminal 100 is turned on, is turned off in the sleep mode, and maintains high impedance Can be configured. With this configuration, the analog switch 173 can be powered down in the sleep mode to further improve the consumption current of the switch input / output port.

A capacitor Cap may be connected between the output terminal OUT of the analog switch 173 and the base of the first switch A in parallel. The capacitor Cap charges the battery power VBAT while the battery power VBAT is supplied to the first switch A at the output OUT of the analog switch 173, (A) temporarily at a certain point in time. Accordingly, the capacitor Cap can be configured to configure the circuit regardless of the influence of the break-before-make-feature characteristic of the analog switch 173 without adding the pull-up resistor E. However, such a capacitor Cap is required to have stable characteristics (for example, power supply voltage) of the portable terminal 100 even under various conditions in consideration of power on / off characteristics of the portable terminal 100, reset timing, and temperature characteristics of the first switch A and the capacitor Cap To be maintained. Thus, in a repetitive power on-off situation, the use of a pull-up resistor (E) may be more efficient. As a result, the capacitor Cap can be omitted when the pull-up resistor E is provided. When the stability of the portable terminal 100 is considered, the capacitor Cap can be replaced with a pull-up resistor E ). ≪ / RTI >

As described above, the reset unit 170 according to the embodiment of the present invention arranges the analog switch 173 between the reset circuit 140 and the reset control circuit 150 to selectively supply the manual reset signal MR_RESET And the input / output power source (VCC_IO) is used as the driving power source for the analog switch 173, and at the same time, as the driving power source for the first switch (A), generation of the consumed current can be minimized.

5 is a diagram for explaining a circuit configuration and a reset method of the reset unit 170 according to the fourth embodiment of the present invention.

5, the reset unit 170 according to the fourth embodiment of the present invention includes a reset circuit 140, an analog switch 173 located at the output terminal of the reset circuit 140, and an analog switch 173 Up resistor E connected in parallel between the analog switch 173 and the reset control circuit 150, an input / output power supply VCC_IO, and a capacitor (not shown) connected between the analog switch 173 and the reset control circuit 150. [ Cap) may be disposed.

In particular, the reset control circuit 150 may further include an AND gate B 'to which the output of the OR gate and the output of the analog switch 173 are input. The output of the AND gate B is connected to the base of the third switch C and the third switch C is connected to the collector of the battery power supply VBAT and the base of the fourth switch D .

The reset unit 170 according to the present invention having the above-described configuration is provided with an input / output (I / O) input terminal connected to the pull-up resistor E at the input terminal of the AND gate B 'while no other manual reset signal MR_RESET is generated in the reset circuit 140 When the power supply VCC_IO and the high signal of the reset circuit 140 are supplied, the output of the OR gate may also be supplied and the output of the AND gate B 'may have a high state. As a result, the third switch (C) can be activated, and as a result, the fourth switch (D) can control to supply the battery power (VBAT) to the PMIC (130).

The analog switch 173 supplies the battery power VBAT to the AND gate B` through the output terminal OUT when power is supplied to the portable terminal 100. [ The AND gate B 'may supply a high signal to the third switch C because a signal input for initial power supply during the input of the OR gate, that is, an ON_SW signal, is supplied. As a result, the reset unit 170 can supply the battery power (VBAT) to the PMIC 130 at the time when power is supplied to the initial portable terminal 100.

The PS_HOLD signal becomes high state at the selected terminal SEL of the analog switch 173 while the analog switch 173 connects the first selected input terminal S1 and the output terminal OUT Switching state. Meanwhile, when the power supply is normally performed, the PMIC 130 generates an input / output power source VCC_IO using the battery power VBAT and supplies it to the AND gate B 'through the pull-up resistor E . As a result, the AND gate B 'supplies a high signal to the third switch C to continuously supply the battery power VBAT to the PMIC 130 since the PS_HOLD signal is supplied to the OR gate in a high state .

Meanwhile, when the user desires to reset the portable terminal 100, that is, generates a power key input signal nPower and a specific key input signal ANY_KEY using the input unit 110 and supplies the same to the reset circuit 140, The circuit 140 delivers a manual reset signal MR_RESET to the first selected input S1 of the analog switch 173. Then, the analog switch 173 transfers a low manual reset signal MR_RESET to the input of the AND gate B '. The AND gate B 'supplies a low signal to the third switch C regardless of the output of the OR gate. As a result, the fourth switch D causes the battery power VBAT to be supplied to the PMIC 130 to prevent them from being supplied. Accordingly, the portable terminal 100 can be turned to the turn-off state.

Then, the analog switch 173 performs a switching operation of connecting the second selection input terminal S2 and the output terminal OUT when the PS_HOLD signal is in a low state. The battery power supply VBAT may then be supplied to the AND gate B 'through the second selected input S2 and output OUT of the analog switch 173. On the other hand, ON_SW, which is a non-inverted signal of the power key input signal nPower, is also supplied to the OR gate 151 in this process. Also, when the counting is completed by a specific counter operation provided in the portable terminal 100 and a count signal is generated, the count signal may be supplied as a specific input of the OR gate, for example, an ETC signal. As a result, the AND gate B 'can supply a high signal to the third switch C by the output of the analog switch 173 and the OR gate output of the high state.

On the other hand, the AND gate B 'may have an error in processing the various voltage input ranges of the OR gate. Accordingly, the AND gate B 'may be configured as a switch.

As described above, the portable terminal 100 according to the embodiment of the present invention supports the PMIC 130, which does not have a manual reset function, to have a reset function by using the reset circuit 140 and the reset control circuit 150 .

On the other hand, the above-described reset control circuit 150 of the present invention may generate a continuous consumption current according to the circuit configuration. This will be described in more detail with reference to FIGS. 6 and 7. FIG.

6 is a diagram for explaining leakage current generation in the circuit configuration of the reset unit 170 according to the embodiment of the present invention, and FIG. 7 is a diagram showing the configuration of the reset unit 170 circuit for suppressing the leakage current.

Here, the circuit configuration shown in Figs. 6 and 7 is substantially the same as the circuit configuration of the reset portion 170 shown in Fig. 4, or the same as the configuration shown in Fig. 4 except for the circuit configuration for leakage current suppression The detailed description of the reset unit 170 will be omitted, and only the portion related to the leakage current will be described in detail.

First, in the reset circuit 140 of the present invention, the analog switch 173 causes the battery power source VBAT connected to the second selection input S2 to be transmitted to the base of the first switch A to maintain the default high state Support. The battery power source VBAT transmitted to the first switch A through the pull-up resistor H is designed to have a relatively higher potential difference than the input / output power source VCC_IO connected to the pull-up resistor E, A leakage current may be generated due to a potential difference between the battery power source VBAT and the input / output power source VCC_IO. In particular, if the LDO supplying the input / output power (VCC_IO) provides an auto-discharge function for the output in the turn-off state or does not have an open circuit state internally, The output state can not be defined. In this case, a leakage current may be generated due to a potential difference between the battery power source VBAT and the input / output power source VCC_IO. A leakage current may be generated through the first path including the battery power source VBAT, the pull-up resistor H, the analog switch 173, and the pull-up resistor E.

The first switch A may internally have built-in resistors R1 and R2 so that the battery power VBAT output from the analog switch 173 is supplied to the first switch A, To the emitter end of the first switch (A) through the built-in resistors (R1, R2). A first switch A including emitters of the battery power source VBAT, the pull-up resistor H, the analog switch 173, the base of the first switch A, the built-in resistor R1, the built- Leakage current may occur through the path.

In order to suppress the above-described leakage current generation, the reset unit 170 of the present invention includes a configuration as shown in FIG. 7, thereby suppressing the generation of leakage current. That is, the reset unit 170 includes a diode F for preventing the leakage current from occurring between the input / output power supply VCC_IO and the pull-up resistor E, so that the battery power VBAT flows back toward the input / output power supply VCC_IO Leakage current can be suppressed. In the reset unit 170 having the above-described configuration, the reverse current of the diode F corresponds to several hundreds of microamperes, so that the leakage current in the direction of the input / output power source VCC_IO is substantially blocked.

7, the reset unit 170 of the present invention applies a switch type in which no built-in resistor is provided between the base end and the emitter end of the first switch A, It is possible to suppress the leakage current through. Here, the built-in resistor R1 provided at the base end of the first switch A may be provided in a removed form or may be provided in a form of being disposed.

As described above, the reset unit 170 according to the embodiment of the present invention can suppress the leakage current of the battery power source VBAT, thereby preventing unnecessary power consumption.

Meanwhile, since the reset unit 170 according to the embodiment of the present invention uses a plurality of switches, when the terminal transits from the turn-off state to the turn-on state or performs the reset function, It may not perform a normal function by a plurality of switches operating differently in a situation. This will be described in more detail with reference to FIGS. 8 to 12. FIG.

FIG. 8 is a graph showing a relationship between an input power source and an output current under a specific temperature condition, and FIG. 9 is a graph showing a relationship between a DC current gain and an output current in a specific temperature condition.

Referring to FIG. 8, when the temperature drops to -20 ° C at a room temperature of 25 ° C, the output current of each switch decreases by about 1mA on the basis of a circuit operating point of about 1.5V. Also, referring to FIG. 9, it can be seen that the current gain of the switches is lower at -40 ° C. than the room temperature, and the current gain is greatly reduced while the output current is reduced by about 1 mA.

The changes in the circuit characteristics according to the temperature conditions described above with reference to FIGS. 8 and 9 are also applied to the respective switches included in the reset unit 170 circuit of the present invention. Accordingly, each of the switches included in the reset unit 170 of the present invention may not perform the operation according to the intention of the designer even in a specific temperature condition. This will be described in more detail with reference to FIG.

10 is a diagram for explaining characteristics of specific circuits applied to the reset section 170 circuit of the present invention in a specific temperature condition.

10, in the circuit of the reset section 170 of the present invention, the output current collector stage current IC2 of the second switch B on the circuit arrangement is equal to the output current IB3 flowing in the base end direction of the third switch C And the collector output current IC1 current of the first switch A is equal to the output current IB2 current flowing at the base end of the second switch B. [ Therefore, when the portable terminal 100 enters a certain low temperature state, for example, -20 degrees, and the IC1 current of the first switch A decreases, the IB2 current having the same value as the IC1 current also decreases. On the other hand, when the IB2 current decreases, the output current IC2 current of the second switch is also reduced, and the IB3 current having the same value as the IC2 current is decreased. As a result, the IC3 current Conversely, if the IC3 current decreases in a certain low temperature situation, there may be a case where the IB3 current is reduced and the driving currents of the second switch B and the third switch C are reduced.

Due to the negative feedback effect described above, the third switch (C) at the end can not be driven because the IB3 current is reduced to a certain value or less, or the IC3 current becomes small so that the voltage across the load resistor R becomes small, It is possible to reach a state in which the set voltage for driving the switch D can not be satisfied. When the portable terminal 100 is left at the low temperature for a specific time, the portable terminal 100 is controlled to supply the battery power (VBAT) to the PMIC 130 according to a turn-on operation or a cold reset return operation, The battery voltage VBAT may not be supplied to the PMIC 130 because the normal circuit operation is not performed in accordance with the low temperature environment described above and the fourth switch D connected to the collector terminal of the battery C is required to operate. As a result, the portable terminal 100 may not be turned on or may not return from the cold reset. In order to solve such a problem, the reset unit 170 of the present invention may include a reset unit 170 having a configuration as shown in FIG.

11 is a diagram illustrating a configuration of a reset unit 170 that can stably operate in a low-temperature environment according to an embodiment of the present invention. Prior to the description, the configuration of the reset unit 170 shown in FIG. 11 includes substantially the same configuration except for some configurations as compared with the configuration shown in FIG. Accordingly, detailed description of other components except for some components for low temperature environment support will be omitted in the following description.

11, when a cold reset circuit of the PMIC 130 without a manual reset function is implemented, the PMIC 130 switches the connection state of the battery power (BAT) from the turn-off state to the turn-on state The transistor driving current of the third switch C may be lowered when the portable terminal 100 is placed at a low temperature, for example, at -20 degrees. Accordingly, the fourth switch (D) connected to the third switch (C) may be in a state in which normal driving can not be performed due to the restriction of the supply of the appropriate driving current. Such a phenomenon may intermittently turn the portable terminal - Could cause problems that can not be turned on. Therefore, the value of the pull-up resistor may be adjusted so as to increase the current IC3 of the third switch C by increasing the IB3 current of the third switch C, or the third switch C may be implemented by a voltage It is possible to consider using a driving transistor or using a small signal transistor without an internal built-in resistor, excluding the use of a digital transistor having an internal built-in resistance applied to a conventional digital circuit design.

11, the reset unit 170 of the present invention includes a pull-up resistor E or a resistance of pull-up resistors existing on all circuits connected to the base end of the first switch A, Can be adjusted to be smaller than a predetermined value so as to increase the IB1 current of the first switch (A). As a result, the IC1 current of the first switch A is increased, and the IB2 current of the second switch B increases with the increase of the IC1 current of the first switch A. As described above with reference to Fig. 10, The IC2 current increase of the third switch C, the IB3 current increase of the third switch C, and the IC3 current of the third switch C can be increased. As a result, the reset unit 170 of the present invention satisfies the drive current value capable of driving the fourth switch D due to the IC3 current increase of the third switch C, so that the battery power source VBAT is supplied to the PMIC 130 to form a pass. As a method for reducing the pull-up resistance, first, a current gain corresponding to the output current reduction value of the corresponding switches in a low-temperature environment is detected with respect to circuit configurations. And detects a current gain of output currents for driving each of the switches at room temperature. Here, the low-temperature current gain of the first switch A is defined as LB1, the low-temperature current gain of the second switch B is defined as LB2, and the low-temperature current gain of the third switch C is defined as LB3 with respect to the detected current gain . The current-temperature gain of the first switch A is defined as HB1, the current-temperature gain of the second switch B is defined as HB2, and the current-temperature gain of the third switch C is defined as HB3. Then, the pull-up resistor used in the previous reset portion 170 circuit is divided by a multiple corresponding to the relationship of the current gains, and the pull-up resistor thus obtained can be applied as a new pull-up resistor of the reset portion 170.

That is, a new pull-up resistor can be defined by the following equation (1).

[Equation 1]

Pull-up resistor (1) xLB1) x (LB2) x (LB3) / (HB1) x (HB2)

 Here, the pull-up resistor 1 is a pull-up resistor applied in the previous reset portion 170, and the pull-up resistor 2 may mean a pull-up resistor to be applied in a low-temperature environment. For example, a measured value of the previous reset unit 170 is a value of about 22.66 because the average temperature gain / low temperature current gain is 2.83 and three switches are connected. Therefore, it is desirable that the pull-up resistor to be applied to a low-temperature environment be implemented in a form having a resistance value about 22 times smaller than a pull-up resistance applied to a room-temperature environment. That is, the reset unit 170 to which the normal temperature pull-up resistor of 1 kohm is applied is preferably replaced with the low temperature pull-up resistor of about 50 ohms in the reset unit 170 to be applied to the low temperature environment.

On the other hand, the change of the above-mentioned circuit has a problem that the size of the pull-up resistor becomes small, and the consumed current increases. In order to prevent this, as shown in FIG. 11, a method of configuring the third switch C as a current driven BJT (bipolar junction transistor) type and a voltage driven FET type can be considered.

The third switch C greatly affects the current change of the first switch A and the second switch B when the third switch C of the reset controller 150 is changed from the BJT type to the FET type I do not accept. If the battery voltage VBAT is not supplied to the PMIC 130 of the portable terminal 100 because the fourth switch D is not driven as the IB3 output current of the third switch C decreases in the low temperature environment Can be prevented. The replacement of the FET type in the BJT type of the third switch C is the same for all the switches other than the third switch C, i.e., the first switch A, the second switch B and the fourth switch D Applicable.

On the other hand, the FET type switch application method described with reference to FIG. 11 has a disadvantage that it is relatively more expensive and relatively larger in size than the BJT type switch application method. Accordingly, the portable terminal 100 may not be suitable for downsizing and cost reduction. Therefore, in order to implement the portable terminal 100 capable of stably operating in a low temperature environment while achieving the miniaturization and cost reduction described above, the configuration of the reset unit 170 as shown in FIG. 12 can be considered.

The problem related to the operation of the portable terminal 100 in a low temperature environment is that the battery power source VBAT is not supplied to the PMIC 130 of the portable terminal 100 at a low temperature of -20 degrees as described above, This is a problem that occurs because the switch C can not normally drive the fourth switch D. Therefore, if the IB3 current of the third switch (C) and the current of IC3 are made large, it is possible to overcome this disadvantage. For this purpose, the characteristics of previously used switches can be adjusted. That is, if previously used switches are composed of digital transistors, they have internal built-in resistors arranged in parallel between the base input and the base-emitter in tens of kilohms. Therefore, the reset unit 170 can use a switch of the small signal transistor type in which the internal built-in resistor does not exist, while excluding the use of the switch of the digital transistor type in which the built-in resistor exists. The reset unit 170 may be implemented in a form that improves the non-turn-on phenomenon that occurs intermittently in a low-temperature environment. That is, when the third switch C is replaced with a TR-S type small-signal transistor having no internal resistance, the IB3 current of the third switch C And thus can lead to an increase in the IC3 current driving the fourth switch (D).

As described above, when the pull-up resistance value is changed or the type of the switch is changed in the process of implementing the cold reset circuit of the PMIC without the manual reset function, It is possible to prevent an abnormal operation of the terminal that may occur.

Meanwhile, the portable terminal 100 may further include various additional modules according to the providing mode. That is, the portable terminal 100 includes a short distance communication module for short distance communication, a camera module for photographing a still image / moving picture of a subject, a wired communication method of the portable terminal 100, An interface for transmission / reception, an internet communication module for performing Internet functions by communicating with the Internet network, and a digital broadcasting module for performing digital broadcasting reception and reproduction functions. These components can not be enumerated because of a wide variety of variations depending on the convergence trend of the digital device, but it is also possible that components having the same level as the above-mentioned components are further included in the device have. Also, it is needless to say that the portable terminal 100 according to the present invention may be excluded from the specific configurations or may be replaced with other configurations according to the providing mode. Which will be readily apparent to those skilled in the art.

Also, the portable terminal 100 according to the embodiment of the present invention may include all types of devices including a WiFi module. For example, the portable terminal 100 may include all mobile communication terminals operating based on communication protocols corresponding to various communication systems, a portable multimedia player (PMP) A multimedia player, a digital broadcasting player, a PDA (Personal Digital Assistant), a music player (e.g., MP3 player), a portable game terminal, a smart phone, a notebook, Application devices.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. , And are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention may be practiced without departing from the scope of the invention disclosed herein.

100: portable terminal 110: input unit
120: Power supply unit 130: PMIC
140: reset circuit 150: reset control circuit
160: control unit 170:

Claims (23)

1. An electronic device having a PMIC (Power Management IC) without a manual reset function,
An input unit for generating a specific input signal for reset according to a user input;
A reset unit for generating a manual reset input signal in response to the input of the specific input signal and for controlling the battery power supplied to the PMIC using a signal generated during the operation maintenance period of the electronic device and the manual reset input signal, ; And
And a power supply for supplying the battery power. The method according to claim 1,
The reset unit
A reset circuit for generating the manual reset input signal according to the input of the specific input signal;
And a reset control circuit for interrupting power supply to the PMIC according to the manual reset input signal and a signal generated during the operation maintenance period. 3. The method of claim 2,
The reset control circuit
A first switch whose activation is determined according to an output of the reset circuit;
A second switch for determining whether to activate according to whether the first switch is activated;
An OR gate for outputting a predetermined signal through the second switch;
A third switch whose activation or deactivation is determined according to whether or not the output of the OR gate is delivered; And
And a fourth switch for controlling supply or blocking of the battery power to the PMIC according to whether the third switch is activated or not. The method of claim 3,
The reset control circuit
Wherein the first switch and the second switch are constituted by AND gates,
And controls the third switch to be activated in accordance with the output of the reset circuit and the output of the OR gate. The method of claim 3,
The OR gate
An input signal having a high state during operation of the electronic device;
An input signal of an input unit that is input for instructing power supply of the electronic device;
Other input signals including at least one of a charger insert, a USB input, and a count input; To the third switch, a signal capable of activating the third switch via the second switch when at least one of the first switch and the second switch is inputted. The method of claim 3,
The first switch
And a built-in resistance is removed between the base stage and the emitter stage. The method of claim 3,
At least one of the first switch, the second switch, the third switch and the fourth switch
FET type switch. ≪ Desc / Clms Page number 24 > The method of claim 3,
The third switch
A built-in resistor connected to the base stage, and a built-in resistor between the base stage and the emitter stage. 3. The method of claim 2,
The reset unit
And a pull-up resistor disposed between the reset circuit and the reset control circuit,
Wherein the battery power source or the input / output power source generated by the PMIC is connected to one end of the pull-up resistor to provide a default high signal to a specific switch included in the reset control circuit. 10. The method of claim 9,
The reset circuit
And the power supply is driven by the battery power or the input / output power generated by the PMIC. 10. The method of claim 9,
The reset unit
Further comprising a level shifter located at a previous stage of the reset circuit, for shifting the signal level of the specific input signal for resetting generated from the input unit to a signal level of the battery power source. 3. The method of claim 2,
The reset unit
An analog switch disposed between the reset circuit and the reset control circuit;
A pull-up resistor connected between the reset circuit and the reset control circuit, and a capacitor disposed between the reset circuit and the reset control circuit, the input / output power generated by the PMIC being connected at one end, The resetting device of the electronic device. 13. The method of claim 12,
The analog switch
A first selection input terminal to which an output of the reset circuit is input;
A second selection input terminal to which a pull-up resistor connected to one end of the battery power source is connected;
A selection terminal to which a low-state signal is input when the electronic device is in a high state while the electronic device is in an operation-stopped state; And
And an output terminal for supplying a signal input to the first selection input terminal or the second selection input terminal to the reset control circuit in accordance with the state of the signal input to the selection terminal. 13. The method of claim 12,
The analog switch
Output power source generated by said PMIC. 13. The method of claim 12,
The reset unit
And a diode disposed between the input / output power supply and the pull-up resistor. 1. An electronic device having a PMIC (Power Management IC) without a manual reset function,
A reset circuit generating a manual reset input signal according to whether a specific input signal for resetting is generated and supplying the manual reset input signal to the reset control circuit; And
A control process of controlling the supply or cutoff state of the battery power to the PMIC based on a signal having a high state during an operation maintenance period of the electronic device and a reset control circuit supplied with a manual reset input signal when the specific input signal is generated, And resetting the electronic device. 17. The method of claim 16,
Before the manual reset input signal is generated
Activating a switch of a circuit designed to supply the battery power to the PMIC using either the pull-up of the battery power source or the pull-up of the input / output power source generated by the PMIC based on battery power; And
And controlling to supply the battery power to the PMIC according to the activation of the switch. 18. The method of claim 17,
Supplying battery power to the reset circuit for driving the reset circuit; or
And supplying the reset circuit with the input / output power generated by the PMIC based on the battery power for driving the reset circuit. 17. The method of claim 16,
The control process
An analog switch driven by an input / output power supply generated by the PMIC using battery power is disposed between the reset circuit and the reset control circuit, and the analog switch is connected to the reset control circuit through the analog switch Supplying the pull-up of the battery power to the reset control circuit; And
And controlling the battery power to be supplied to the PMIC based on a signal supplied in a high state during operation of the electronic device and a pull-up of the battery power. 20. The method of claim 19,
The control process
Supplying the manual reset input signal in a low state to the reset control circuit through the analog switch according to a specific input signal input for resetting the electronic device; And
And deactivating the switches constituting the reset control circuit according to the manual reset input signal, thereby blocking a path through which the battery power is supplied to the PMIC. 21. The method of claim 20,
Supplying the input / output power generated by the PMIC using the battery power by pulling up the PMIC between the analog switch and the reset control circuit; And
A capacitor is disposed on a path through which the battery power is pulled up to a reset control circuit to temporarily store the battery power and supply power stored when the battery is shut down; ≪ / RTI > further comprising at least one of the following: 17. The method of claim 16,
Driving the counter after power supply to the PMIC is cut off and supplying the output of the counter to the reset control circuit;
Supplying the pull-up of the battery power to the reset control circuit;
Supplying a signal corresponding to an input to a power key included in the electronic device to a reset control circuit; And
Further comprising the step of restarting power supply to the PMIC by using the output of the supplied counter and the pull-up of the battery power source. 17. The method of claim 16,
Supplying the driving power of the reset circuit to the battery power when the pull-up of the battery power is supplied between the reset circuit and the reset control circuit; And
And level shifting the signal level of the specific input signal to a signal level of the battery power source.

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