KR102454517B1 - Apparatus for managing wake-up function of vehicle and method thereof - Google Patents

Abstract

The present invention relates to an apparatus for managing a wake-up function of a vehicle, comprising: a communication module which wakes up a power module by a signal from a designated device when a vehicle's ignition key is off; a power module which is woken up by the signal from the communication module and applies driving power to a microcomputer and first and second driving chips; and the microcomputer which outputs a virtual ignition key-on signal to the power module when the same is woken up by receiving the driving power, which is to enable the second driving chip when a specified operating condition is satisfied in a status in which a virtual ignition key-on signal is output, and which selectively operates only designated specific functions among functions related to functional safety of the vehicle connected to the second driving chip. According to the apparatus for managing the wake-up function of the vehicle and a method thereof, the designated specific function can be selectively driven even in the ignition key off status.

Description

Apparatus and method for managing wake-up function of a vehicle

The present invention relates to an apparatus and method for managing a wake-up function of a vehicle, and more particularly, among various functions related to functional safety of a vehicle that should be operated only in an ignition key on state, a specific function designated even in an ignition key off state is selectively selected. It relates to an apparatus and method for managing a wake-up function of a vehicle to enable driving.

In general, a vehicle has a function that operates only in the ignition key on state in relation to the functional safety of the vehicle (that is, the function related to the safety of the vehicle) (that is, the ignition key on state, that is, the user (a function that does not operate unless the ignition key is turned on according to the intention of the

However, unlike the ignition key of an internal combustion engine vehicle, an electric vehicle does not have an ignition key, and a switch that operates in place of the ignition key (e.g., a power switch, a switch linked to a gear, a switch operated by receiving a remote signal using a smartphone, etc.) may be included. Therefore, the ignition key in this embodiment should be understood as a concept including a switch that performs an equivalent function instead of the ignition key.

However, some of the functions related to functional safety of the vehicle (ie, functions that operate only when the ignition key is on) are dependent on the environmental characteristics in which the vehicle is operated (eg, extremely cold or extremely hot areas) or In the event of an unusually exceptional driving situation (e.g., a situation in which the ignition key is forcibly turned off due to a dangerous symptom in the vehicle), some specific functions related to functional safety of the vehicle are limited even when the ignition key is off There are times when this should work.

Therefore, there is a need for a technology to selectively enable certain specified functions among various functions related to functional safety of the vehicle even in the ignition key off state.

Background art of the present invention is disclosed in Korean Patent Application Laid-Open No. 10-1998-0049816 (published on September 15, 1998, device and method for wake-up of an electronic control device).

According to one aspect of the present invention, the present invention was created to solve the above problems, and among various functions related to functional safety of a vehicle that should be operated only in the ignition key on state, a specific function designated even in the ignition key off state An object of the present invention is to provide an apparatus and method for managing a wake-up function of a vehicle, which enables the vehicle to be selectively driven.

An apparatus for managing a wake-up function of a vehicle according to an aspect of the present invention includes: a communication module for waking up a power module by waking up by a signal from a designated device in an ignition key-off state of the vehicle; a power module that wakes up by a signal from the communication module and applies driving power to the microcomputer and the first and second driving chips; and when it wakes up by receiving the driving power, it outputs a virtual ignition key-on signal to the power module, and enables the second driving chip when a specified operating condition is satisfied while the virtual ignition key-on signal is output. and a microcomputer that selectively operates only specified specific functions from among functions related to functional safety of the vehicle connected to the second driving chip after entering the state.

In the present invention, when the actual ignition key on state is detected, the microcomputer stops output of the virtual ignition key on signal or outputs a low signal, and all of the vehicles connected to the first driving chip and the second driving chip. It is characterized in that a normal operation operation for driving a function is performed.

In the present invention, the power module checks the self-test results of the microcomputer and the first and second driving chips that are woken up by the driving power and perform the self-test, and when the self-test results are all normal, a monitoring module for outputting a check result signal for this; and an AND gate for outputting a second driving chip enable signal by performing an AND operation on the check result signal and the virtual ignition key on signal.

In the present invention, the microcomputer comprises: a first function module for detecting an actual ignition key state and a virtual ignition key state; a second function module that selectively drives only a designated specific function among functions related to functional safety of a vehicle connected to the second driving chip in a virtual ignition key-on state; and a third function module for driving all functions of the vehicle connected to the first and second driving chips in an actual ignition key on state.

In the present invention, when the microcomputer is in an actual ignition key-off state and a virtual ignition key-off state, and satisfies a specified operating condition of a function related to functional safety of a vehicle to be driven in an actual ignition key-off state, virtual It is characterized in that the virtual ignition key on signal for switching to the ignition key on state is output.

In the present invention, the second driving chip includes an AND gate at an enable signal input port, and the AND gate includes a first input terminal that is a positive input terminal and a second input terminal that is a negative input terminal.

In the present invention, the second driving chip receives a 'high signal' output from the power module as a second driving chip enable signal to a first input terminal, and outputs it as a second driving chip enable signal from the microcomputer. It is characterized in that it is in an enabled state by receiving a 'low signal'.

In the present invention, when the microcomputer is in an actual ignition key off state and a virtual ignition key on state, and satisfies a specified operating condition of a function related to functional safety of a vehicle to be driven in an actual ignition key off state, the second driving chip It is characterized in that the enable signal is output to the

In the present invention, actuators for activating functions not related to functional safety of the vehicle are connected to the first driving chip, and actuators for activating functions related to functional safety of the vehicle are connected to the second driving chip do it with

In the present invention, the specified operating condition includes a timeout condition, an actual ignition key state and a virtual ignition key state condition, and an operating condition of the second driving chip.

According to another aspect of the present invention, a method for managing a wake-up function of a vehicle includes: waking up a power module by waking up a communication module by a signal from a designated device in an ignition key-off state of the vehicle; applying driving power to the microcomputer and the first and second driving chips when the power module is woken up by a signal from the communication module; and when the microcomputer wakes up by receiving the driving power, it outputs a virtual ignition key-on signal to the power module, and when a specified operating condition is satisfied while outputting the virtual ignition key-on signal, the second driving chip and, after enabling , selectively operating only designated specific functions among functions related to functional safety of a vehicle connected to the second driving chip.

In the present invention, after selectively operating only specified specific functions among functions related to functional safety of the vehicle connected to the second driving chip, when an actual ignition key-on state is detected, the microcomputer generates a virtual ignition key-on signal The method may further include: stopping the output of , outputting a low signal, and performing a normal operation operation of driving all functions of the vehicle connected to the first driving chip and the second driving chip.

In the present invention, the power module checks the self-test results of the microcomputer and the first and second driving chips that are woken up by the driving power through the monitoring module and perform the self-test, so that the self-test result is When all are normal, a check result signal is output, and a second driving chip enable signal is output by performing an AND operation on the check result signal and the virtual ignition key-on signal through an AND gate.

In the present invention, the microcomputer detects the actual ignition key state and the virtual ignition key state through the first function module, and the function of the vehicle connected to the second driving chip in the virtual ignition key on state through the second function module It is characterized in that only a specific function designated among safety-related functions is selectively driven, and all functions of the vehicle connected to the first and second driving chips are driven in an actual ignition key-on state through a third function module.

In the present invention, in the step of outputting the virtual ignition key on signal, the actual ignition key is off and the virtual ignition key is off, and the specified operating conditions of functions related to functional safety of the vehicle to be driven in the actual ignition key off state are determined. If satisfied, the microcomputer outputs a virtual ignition key-on signal for switching to a virtual ignition key-on state to the power module.

In the present invention, the second driving chip includes an AND gate at an enable signal input port, and the AND gate includes a first input terminal that is a positive input terminal and a second input terminal that is a negative input terminal.

In the present invention, the second driving chip receives a 'high signal' output from the power module as a second driving chip enable signal to a first input terminal, and outputs it as a second driving chip enable signal from the microcomputer. It is characterized in that it is in an enabled state by receiving a 'low signal'.

In the present invention, in the step of enabling the second driving chip, a function related to functional safety of a vehicle to be driven is designated in an actual ignition key off state and a virtual ignition key on state, and in an actual ignition key off state. When the operating condition is satisfied, the microcomputer outputs an enable signal to the second driving chip.

In the present invention, the specified operating conditions include a timeout condition, an ignition key state condition, and an operating condition of the second driving chip.

According to an aspect of the present invention, among various functions related to functional safety of a vehicle that should be operated only in an ignition key on state, a specified specific function can be selectively driven even in an ignition key off state.

1 is an exemplary diagram illustrating a schematic configuration of an apparatus for managing a wake-up function of a vehicle according to an embodiment of the present invention;
2 is a flowchart illustrating a method for managing a wake-up function of a vehicle according to an embodiment of the present invention;

Hereinafter, an embodiment of an apparatus and method for managing a wake-up function of a vehicle according to the present invention will be described with reference to the accompanying drawings.

In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, definitions of these terms should be made based on the content throughout this specification.

1 is an exemplary diagram illustrating a schematic configuration of an apparatus for managing a wake-up function of a vehicle according to an embodiment of the present invention.

As shown in FIG. 1 , the apparatus for managing a wake-up function of a vehicle according to the present embodiment includes a communication module 110 , a power module 120 , a microcomputer 130 , a first driving chip 140 , and a first 2 driving chips 150 are included.

At this time, the components 110 to 150 transmit signals (eg, control signals, status signals, etc.) to each other through respective ports P1 to P9. Therefore, a description of each of the ports P1 to P9 will be omitted below.

In addition, the current state of the vehicle is the communication module 110 , the power module 120 , the microcomputer 130 , the first driving chip 140 , and the second driving chip 150 in the ignition key (igk in FIG. 1 ) off state. Assume that it is in this sleep state.

The communication module 110 receives an alarm signal from a specified alarm signal providing device (eg, AVN device, navigation, etc.) (not shown) in a specified communication method (eg, CAN, LIN, etc.).

For example, the alarm signal providing device (not shown) means a device for outputting an alarm signal when a specified condition (eg, a specified time, a specified temperature, reception of a specified remote signal, etc.) occurs.

When the communication module 110 receives an alarm signal from the designated alarm signal providing device (eg, AVN device, navigation device, etc.) (not shown), it wakes up from the sleep state and wakes up.

When the communication module 110 wakes up from the sleep state, it outputs an enable signal (or a wakeup signal) to the second enable port en2 of the power module 120 .

When the power module 120 receives an enable signal (or a wake-up signal) from the communication module 110 , it wakes up from the sleep state and wakes up.

Since the communication module 110 and the power module 120 are in a state in which battery power (bat) is being supplied, they wake up immediately upon receiving a specified signal (eg, an alarm signal, an enable signal, and a wake-up signal). do.

When the power module 120 wakes up, although a driving power line (vdd line) is not shown, it is connected to the microcomputer 130 , the first driving chip 140 , and the second driving chip 150 . The driving power vdd is applied.

The microcomputer 130 , the first driving chip 140 , and the second driving chip 150 wake up when the driving power vdd is applied to perform a self-test.

The monitoring module 121 in the power module 120 receives the self-test results of the microcomputer 130 , the first driving chip 140 , and the second driving chip 150 , so that the driving power vdd is reduced. Check whether it is supplied normally.

In addition, when the self-test results of the microcomputer 130 , the first driving chip 140 , and the second driving device 150 are all normal, the monitoring module 121 in the power module 120 , The check result signal (eg, high signal) is output to the AND gate (&).

The microcomputer 130 internally includes a first function module FM1, a second function module FM2, and a third function module FM3.

In this case, the first to third function modules FM1 to FM3 may be implemented in software or may be integrated into one function module FM. However, in this embodiment, in order to help the understanding of the operation of the microcomputer 130, the first to third functional modules FM1 to FM3 will be described separately as described above.

The microcomputer 130, which has been woken up as described above, detects the actual ignition key (igk) state and the virtual ignition key state through the first function module FM1 (detected using the P5 port and the P4 port).

For example, the actual ignition key (igk) state is a current ignition key off state, and the virtual ignition key state is also a virtual ignition key off state.

In addition, the microcomputer 130 confirms that the result detected through the first function module FM1 is a specified result (ie, the actual ignition key off state & the virtual ignition key off state), and the vehicle to be driven in the ignition key off state Control signal (CTL_wk_state_ON) for switching to the virtual ignition key on state through the second function module (FM2) when the operable conditions (eg timeout state, second driving chip state) of the functional safety-related functions are satisfied. ) to the first enable port en1 of the power module 120 (control signal output for switching to the virtual ignition key on state through the P3 port).

Accordingly, the power module 120 recognizes the actual ignition key on state by the control signal CTL_wk_state_ON, but the actual state becomes the virtual ignition key on state described in this embodiment. However, the power module 120 does not distinguish between an actual ignition key on state or a virtual ignition key on state, and merely recognizes the ignition key on state.

Therefore, the power module 120 performs an AND operation on the ignition key on state signal (eg, high signal) and the check result signal (eg, high signal) output from the monitoring module 121 through the AND gate (&). (eg: high signal), a second driving chip enable signal (eg, high signal) through a designated enable signal output port (ndis) of the enable signal input port (ndis) of the second driving chip 150 It is output to the first input terminal (eg, positive input terminal) of the AND gate (&).

Here, the AND gate (&) of the enable signal input port ndis of the second driving chip 150 includes a first input terminal that is a positive input terminal and a second input terminal that is a negative input terminal.

Accordingly, in the AND gate (&) of the enable signal input port ndis of the second driving chip 150, a 'high signal' is input to the first input terminal and a 'low signal' is input to the second input terminal, When the AND operation result becomes 'high', the second driving chip 150 is enabled.

On the other hand, the microcomputer 130 confirms that the result detected through the first function module FM1 is a specified result (ie, the actual ignition key off state & the virtual ignition key on state), and can be driven in the ignition key off state. When the operable conditions (eg, timeout state, second driving chip state) of functions related to functional safety of the vehicle are satisfied, the second driving chip enable signal (eg, low) through the enable signal output port (dis) signal) to the second input terminal (eg, negative input terminal) of the AND gate (&) of the enable signal input port ndis of the second driving chip 150 .

Accordingly, a 'high signal' is input to the first input terminal of the AND gate (&) of the enable signal input port (ndis) of the second driving chip 150, and a 'low signal' is input to the second input terminal. As the operation result becomes 'high', the second driving chip 150 is in an enabled state.

Here, to the first driving chip 150, actuators for activating functions not related to functional safety of the vehicle are connected, and to the second driving chip 150, actuators for activating functions related to functional safety of the vehicle are connected. .

In addition, in the microcomputer 130 , the second driving chip 150 is enabled, and the result detected through the first function module FM1 is a specified result (that is, the actual ignition key off state & the virtual ignition key). ON state), a control signal for selectively driving only specified specific functions among functions related to functional safety of the vehicle connected to the second driving chip 150 is transmitted through the second function module FM2. output to the second driving chip 150 (using the P6 port and the P9 port).

In addition, when the microcomputer 130 detects the actual ignition key on state through the first function module FM1, the first enable port of the power module 120 through the second function module FM2 ( Stop the output of the 'control signal (CTL_wk_state_ON) for transition to the virtual ignition key on state (CTL_wk_state_ON)' output to en1) (or output a low signal), and functional safety of the vehicle connected to the second driving chip 150 A control signal for driving all related functions is output to the second driving chip 150 .

That is, the microcomputer 130 drives all functions of the vehicle connected to the first driving chip 140 and the second driving chip 150 through the third function module FM3 in an actual ignition key on state. to selectively drive only a specified specific function among functions related to functional safety of a vehicle connected to the second driving chip 150 through the second function module FM2 in the virtual ignition key on state. Outputs a control signal.

Accordingly, the present embodiment has an effect of selectively driving a specified specific function even in the ignition key off state among various functions related to functional safety of the vehicle that should be operated only in the ignition key on state.

2 is a flowchart illustrating a method for managing a wake-up function of a vehicle according to an embodiment of the present invention.

Referring to FIG. 2 , the current state of the vehicle is the communication module 110 , the power module 120 , the microcomputer 130 , the first driving chip 140 , and the second driving chip 150 in the ignition key off state. When in the sleep state (or OFF state) (S101), the communication module 110 receives an alarm signal from a designated alarm signal providing device (eg, AVN device, navigation device, etc.) (not shown) to wake-up. up) (Yes in S102), the microcomputer 130 is woken up according to a specified procedure (S103).

For example, when the communication module 110 wakes up, an enable signal (or a wake-up signal) is output to the power module 120 to wake up the power module 120 , and the power module 120 wakes up. When it is up, the driving power vdd is applied to the microcomputer 130 , the first driving chip 140 , and the second driving chip 150 to wake up.

The wake-up microcomputer 130 outputs a virtual ignition key-on signal to the power module 120 ( S104 ), and also checks whether the microcomputer 130 satisfies the operable condition of the second driving chip 150 . to be satisfied (Yes in S105), the second driving chip 150 is placed in an operation allowable state (ie, an enabled state) (S106).

For example, the microcomputer 130 confirms that the result detected through the first function module FM1 is a specified result (ie, the actual ignition key off state & the virtual ignition key on state), and can be driven in the ignition key off state. When the operable conditions (eg, timeout state, second driving chip state) of functions related to functional safety of the vehicle are satisfied, by outputting a second driving chip enable signal (eg, low signal), the second driving chip (150) is enabled.

When the second driving chip 150 is in the enabled state, the microcomputer 130 outputs a control signal to the second driving chip 150 to ensure functional safety of the vehicle connected to the second driving chip 150 . Among the related functions, only specified specific functions are selectively operated (S107).

The above processes (S104 to S107) are repeatedly performed until the actual ignition key is turned on (NO in S108).

Meanwhile, when the actual ignition key-on state is detected (Yes in S108), the output of the virtual ignition key-on signal is stopped (or a low signal is output) (S109), and the first driving chip 140 and the second driving A normal operation operation is performed by outputting a control signal for driving all functions of the vehicle connected to the chip 150 (S110).

Accordingly, the present embodiment has an effect of selectively driving a specified specific function even in the ignition key off state among various functions related to functional safety of the vehicle that should be operated only in the ignition key on state.

As described above, the present invention has been described with reference to the embodiment shown in the drawings, but this is merely an example, and various modifications and equivalent other embodiments are possible therefrom by those skilled in the art. will understand the point. Therefore, the technical protection scope of the present invention should be defined by the following claims. Implementations described herein may also be implemented as, for example, a method or process, an apparatus, a software program, a data stream, or a signal. Although discussed only in the context of a single form of implementation (eg, discussed only as a method), implementations of the discussed features may also be implemented in other forms (eg, as an apparatus or a program). The apparatus may be implemented in suitable hardware, software and firmware, and the like. A method may be implemented in an apparatus such as, for example, a processor, which generally refers to a computer, a microprocessor, a processing device, including an integrated circuit or programmable logic device, or the like. Processors also include communication devices such as computers, cell phones, portable/personal digital assistants ("PDAs") and other devices that facilitate communication of information between end-users.

110: communication module
120: power module
121: monitoring module
130: microcomputer
140: first driving chip
150: second driving chip

Claims (19)

a communication module for waking up the power module by waking up by a signal from a designated device in a vehicle ignition key off state;
a power module that wakes up by a signal from the communication module and applies driving power to the microcomputer and the first and second driving chips; and
When it wakes up by receiving the driving power, a virtual ignition key-on signal is output to the power module, and when a specified operating condition is satisfied while the virtual ignition key-on signal is output, the second driving chip is enabled. and a microcomputer that selectively operates only specified specific functions among functions related to functional safety of the vehicle connected to the second driving chip.
According to claim 1, wherein the microcomputer,
When the actual ignition key on state is detected, the output of the virtual ignition key on signal is stopped or a low signal is output,
and performing a normal operation operation for driving all functions of the vehicle connected to the first driving chip and the second driving chip.
According to claim 1, wherein the power module,
A monitoring module that checks the self-test results of the microcomputer, the first and second driving chips that are woken up by the driving power and performs the self-test, and outputs a check result signal when the self-test results are all normal ; and
and an AND gate for outputting a second driving chip enable signal by performing an AND operation on the check result signal and the virtual ignition key on signal.
According to claim 1, wherein the microcomputer,
a first function module for detecting an actual ignition key state and a virtual ignition key state;
a second function module that selectively drives only a designated specific function among functions related to functional safety of a vehicle connected to the second driving chip in a virtual ignition key-on state; and
and a third function module for driving all functions of the vehicle connected to the first and second driving chips in an actual ignition key on state.
According to claim 1, wherein the microcomputer,
The actual ignition key is off and the virtual ignition key is off.
When a specified operating condition of a function related to functional safety of a vehicle to be driven is satisfied in an actual ignition key off state, a virtual ignition key on signal for switching to a virtual ignition key on state is output to the power module. The wake-up function of the management device.
According to claim 1, wherein the second driving chip,
and an AND gate to the enable signal input port;
The AND gate is a wake-up function management apparatus for a vehicle, characterized in that it is composed of a first input terminal as a positive input terminal and a second input terminal as a negative input terminal.
According to claim 1, wherein the second driving chip,
receiving a 'high signal' output as a second driving chip enable signal from the power module to a first input terminal;
The device for managing a wake-up function of a vehicle, characterized in that it is in an enabled state by receiving a 'low signal' output as a second driving chip enable signal from the microcomputer.
According to claim 1, wherein the microcomputer,
The actual ignition key is off and the virtual ignition key is on.
The device for managing a wake-up function of a vehicle, characterized in that when a specified operating condition of a function related to functional safety of a vehicle to be driven is satisfied in an actual ignition key-off state, an enable signal is output to the second driving chip.
The method of claim 1,
Actuators for activating functions not related to functional safety of the vehicle are connected to the first driving chip,
The device for managing a wake-up function of a vehicle, characterized in that actuators for activating functions related to functional safety of the vehicle are connected to the second driving chip.
The method of claim 1 , wherein the specified operating conditions are:
A wake-up function management apparatus for a vehicle, characterized in that it includes a timeout condition, an actual ignition key state and a virtual ignition key state condition, and an operating condition of the second driving chip.
waking up the power module by waking up the communication module by a signal from a designated device in the ignition key off state of the vehicle;
applying driving power to the microcomputer and the first and second driving chips when the power module is woken up by a signal from the communication module; and
When the microcomputer wakes up by receiving the driving power, it outputs a virtual ignition key-on signal to the power module, and when a specified operating condition is satisfied while outputting the virtual ignition key-on signal, the second driving chip and selectively operating only specified specific functions from among functions related to functional safety of the vehicle connected to the second driving chip after the enable state is established.
The method of claim 11 , wherein after selectively operating only specified specific functions among functions related to functional safety of a vehicle connected to the second driving chip,
When the actual ignition key on state is detected,
The microcomputer is
Stop the output of the virtual ignition key on signal or output a low signal,
and performing a normal operation operation of driving all functions of the vehicle connected to the first driving chip and the second driving chip.
12. The method of claim 11, wherein the power module,
The monitoring module checks the self-test results of the microcomputer and the first and second driving chips that are woken up by the driving power to perform the self-test. If the self-test results are all normal, the check result signal is provided. print out,
and outputting a second driving chip enable signal by performing an AND operation on the check result signal and the virtual ignition key-on signal through an AND gate.
The method of claim 11, wherein the microcomputer,
Detects the actual ignition key state and the virtual ignition key state through the first function module,
In the virtual ignition key on state through the second function module, only a specified specific function is selectively driven among functions related to the functional safety of the vehicle connected to the second driving chip,
A method for managing a wake-up function of a vehicle, wherein all functions of the vehicle connected to the first and second driving chips are driven in an actual ignition key-on state through a third function module.
The method of claim 11, wherein in the step of outputting the virtual ignition key on signal,
The actual ignition key is off and the virtual ignition key is off.
When the specified operating conditions for functions related to the functional safety of the vehicle to be driven in the actual ignition key off state are satisfied,
The method for managing a wake-up function of a vehicle, wherein the microcomputer outputs a virtual ignition key-on signal for switching to a virtual ignition key-on state to the power module.
The method of claim 11, wherein the second driving chip,
and an AND gate to the enable signal input port;
The AND gate is a wake-up function management method of a vehicle, characterized in that consisting of a first input terminal as a positive input terminal and a second input terminal as a negative input terminal.
The method of claim 11, wherein the second driving chip,
receiving a 'high signal' output as a second driving chip enable signal from the power module to a first input terminal;
The method for managing a wake-up function of a vehicle, characterized in that the microcomputer enters an enabled state by receiving a 'low signal' output as a second driving chip enable signal.
12. The method of claim 11, wherein in the step of enabling the second driving chip,
The actual ignition key is off and the virtual ignition key is on.
When the specified operating conditions for functions related to the functional safety of the vehicle to be driven in the actual ignition key off state are satisfied,
The microcomputer is
A method for managing a wake-up function of a vehicle, characterized in that outputting an enable signal to the second driving chip.
12. The method of claim 11, wherein the specified operating conditions are:
A method for managing a wake-up function of a vehicle, comprising a timeout condition, an ignition key state condition, and an operating condition of the second driving chip.

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