JP2016043826A - Vehicular system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology that reduces the number of wiring harnesses connecting on-board devices to one another.SOLUTION: A harness 6 connecting a first control device 3 to a second control device 4 branches into two harnesses in the vicinity of the first control device 3 and the two harnesses are respectively connected to a first receiving terminal 3a and a second receiving terminal 3b of the first control device 3. Thus, the need for connecting the harness 6 separately to the first receiving terminal 3a and the second receiving terminal 3b from the second control device 4 is eliminated, whereby the harness 6 is deleted and cost is lowered.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a technique for controlling an apparatus mounted on a vehicle.

  Conventionally, devices mounted on a vehicle are connected by a wire harness, and control signals are transmitted and received between the devices. For example, Patent Document 1 discloses a technique in which a fuel control device receives an ignition signal via a wire harness.

Japanese Patent Publication

  However, when the number of signals to be transmitted / received increases due to complicated vehicle control, the number and length of wire harnesses increase, which causes an increase in cost and becomes a problem.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a technique for reducing wire harnesses for connecting in-vehicle devices.

  In order to solve the above-mentioned problem, the invention of claim 1 is a vehicle system that is mounted on a vehicle and includes a first control device and a second control device that can communicate with the first control device, The first control device performs a first control based on a state of a signal received by the first reception terminal on an in-vehicle device mounted on the vehicle, and a second control unit is different from the first reception terminal. Second control means for performing second control on the in-vehicle device based on the state of the signal received by the receiving terminal, and the second control device has a state change similar to that of the ignition signal of the vehicle. Signal transmitting means for transmitting a control signal to the first control device via a wire harness, the wire harness being branched in the vicinity of the first control device, the first receiving terminal and the second receiving terminal Connected to each of the Wherein the reception terminal second receiving terminal, a vehicle system, characterized by receiving the same of the control signal.

  The invention of claim 2 further includes a third control device capable of communicating with the first control device in the vehicle system according to claim 1, wherein the third control device receives an ignition signal from an ignition switch. A vehicle system comprising: a receiving means for receiving the data; and a data transmitting means for transmitting the state data indicating the state of the ignition signal to the first control device via the information transmission path.

The invention of claim 3 is the vehicle system according to claim 2, wherein the first control device is a state determination means for determining the state of the ignition signal based on the state data.
The first control means, when the state determination means can determine the state of the ignition signal, based on the state of the ignition signal and the state of the control signal received by the first reception terminal The vehicle system is characterized by performing the first control and performing the first control only based on the state of the control signal when the state determination means cannot determine the state of the ignition signal.

  According to a fourth aspect of the present invention, in the vehicular system according to the third aspect, the first control device includes: a first state of the ignition signal based on the control signal; and a first state of the ignition signal based on the state data. A first determination unit configured to determine whether or not the second state is matched; and a current determination unit configured to determine whether or not a current supplied to the battery included in the vehicle exceeds a predetermined value. The control unit determines that the ignition signal is off when the first state and the second state do not match and the current does not exceed the predetermined value.

  According to a fifth aspect of the present invention, in the vehicle system according to the fourth aspect, the first control means does not match the first state and the second state, and the current exceeds the predetermined value. In this case, it is determined that the ignition signal is in an on state.

  According to the first to fifth aspects of the present invention, since the wire harness is branched in the vicinity of the first control device and connected to each of the first receiving terminal and the second receiving terminal, the first receiving terminal and the second receiving terminal are connected. There is no need to connect the wire harness separately to the terminal, and the wire harness can be reduced.

  In particular, according to the invention of claim 2, the first control device can receive the state data indicating the state of the ignition signal via the information transmission path.

  In particular, according to the invention of claim 3, when the state of the ignition signal can be determined, the first control can be performed based on the state of the ignition signal and the state of the control signal, and the state of the ignition signal is determined. Even if it is not possible, the first control can be performed based only on the state of the control signal.

  In particular, according to the invention of claim 4, when the state of the ignition signal based on the control signal does not match the state of the ignition signal based on the state data, and the current does not exceed a predetermined value, the ignition signal is turned off. Since the state is determined, it is possible to appropriately determine the OFF state of the ignition signal.

  In particular, according to the invention of claim 5, when the state of the ignition signal based on the control signal does not match the state of the ignition signal based on the state data, and the current exceeds a predetermined value, the ignition signal is turned on. Therefore, it is possible to appropriately determine the ON state of the ignition signal.

FIG. 1 is a diagram showing an outline of a vehicle system. FIG. 2 is a diagram illustrating a configuration of the vehicle system. FIG. 3 is a diagram illustrating the progress of the vehicle system. FIG. 4 is a diagram illustrating a process of the vehicle system.

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

<1. First Embodiment>
<1-1. Overview>
The upper part of FIG. 1 shows an outline of a conventional vehicle system, and the lower part of FIG. 1 shows an outline of the vehicle system according to the embodiment of the present invention.

  A conventional vehicle system includes a power management ECU with a DCDC converter (abbreviated as “PMDC-ECU” in the outline), an engine control ECU, and other ECUs. Note that ECU is an abbreviation for Electronic Control Unit (electronic control unit).

  The PMDC-ECU is an ECU that manages the power state of the vehicle system to achieve proper power distribution and power saving. When the PMDC-ECU receives a CRANK signal for turning on the starter relay from the engine control ECU, the PMDC-ECU controls the DCDC converter to perform step-up control to an in-vehicle device such as a navigation device. This is because when the starter relay is turned on, an engine starter that requires a large amount of power is driven, and the voltage applied to the in-vehicle device decreases. The vehicle-mounted device is reset when it falls below the minimum operating voltage, which hinders the user's driving operation.

  Further, the PMDC-ECU receives an IG signal from an ignition (hereinafter referred to as “IG”) switch via a wire harness (hereinafter referred to as “harness”), and receives a CAN (Controller Area Network) from another ECU. IG data is received via. The IG signal is compared with the IG data to determine the state of the IG switch (ON or OFF). When the IG switch is determined to be ON, an instruction to perform battery charge control is issued to the alternator. The reason why the IG signal is compared with the IG data is to increase the reliability of the state determination of the IG switch.

  In a conventional vehicle system, a harness that transmits an IG signal, a CRANK signal, or the like has a total extension of 3000 [m] depending on the vehicle, which is a cause of cost increase. Therefore, cost reduction by reducing harnesses has been demanded.

  The lower part of FIG. 1 is an outline of the vehicle system according to the embodiment of the present invention. In such a vehicle system, a harness for transmitting a CRANK signal from the engine control ECU is branched in the vicinity of the PMDC-ECU (for example, a dozen [cm]) and connected to an IG signal input terminal. The harness connecting the IG switch and the PMDC-ECU is deleted. Since the CRANK signal is in substantially the same state as the IG signal, it is used as a substitute signal for the IG signal. Note that the CRANK signal is reversed in state from the IG signal while the starter relay is turned on (approximately 3 [seconds] to 4 [seconds]), but is sufficiently short compared to the total operation time of the vehicle and has no problem. .

  Thus, the number of harnesses can be greatly reduced without changing hardware such as an IG terminal and software for detecting the state of the IG switch from the IG signal and IG data provided in the conventional PMDC-ECU. That is, the manufacturing cost of the vehicle system can be reduced.

<1-2. Configuration>
FIG. 2 shows the configuration of the vehicle system according to the embodiment of the present invention. The vehicle system 1 is mounted on a vehicle 2 and includes a first control device 3, a second control device 4, a third control device 5, a harness 6, and a CAN 7.

  The first control device 3, the second control device 4, and the third control device 5 are electronic control devices that control the in-vehicle device.

  The 1st control apparatus 3 is power management ECU with a DCDC converter mentioned above, for example. The power management function is a function for appropriately maintaining the power consumption of the in-vehicle device. The power management ECU with a DCDC converter monitors on / off of the IG switch and manages the battery state and the operation state of the in-vehicle device to save power. For example, power management of the in-vehicle device, control of the charge amount of the battery, and boosting of the in-vehicle device at the time of engine start are performed. The first control device 3 includes a first reception terminal 3a and a second reception terminal 3b that receive signals. The function with which the 1st control apparatus 3 is provided is mentioned later.

  The second control device 4 is, for example, an engine control ECU. The engine control ECU acquires a crank angle signal from a crank angle sensor (not shown), and controls engine ignition timing and fuel injection timing. Moreover, the 2nd control apparatus 4 performs engine idling stop control. The second control device 4 inverts the state of the CRANK signal transmitted to the first control device via the harness 6 at the time of starting the engine and returning from the idling stop. The first control device performs boost control to the in-vehicle device 25 based on the state of the CRANK signal. This is because when the starter is driven to start the engine, a large amount of electric power is consumed, so that the voltage applied to the in-vehicle device 25 decreases. The signal state is a state indicating whether the signal is on or off.

  The CRANK signal operates in substantially the same manner as the ignition signal and is a signal different from the crank angle signal described above. That is, when the state of the ignition signal is Hi, it becomes Hi, and when it is Lo, it becomes Lo. However, for the convenience of engine start control, while the starter relay is on (while the starter is being driven), the CRANK signal is Lo, and the state is inverted from that of the ignition signal. The CRANK signal functions as a control signal whose state change is similar to that of the IG signal.

  The signal transmission unit 41 transmits a crank signal to the first control device via the harness 6. The signal transmission unit 41 functions as a signal transmission unit.

  The third control device 5 is, for example, a body ECU. The body ECU controls door locks, window opening / closing, lighting, and the like. The 3rd control apparatus 5 is connected with the 1st control apparatus 3 by CAN7. The CAN 7 connects various control devices (not shown) mounted on the vehicle 2 in addition to the first control device 3 and the third control device 5. Each control apparatus connected by CAN7 mutually transmits / receives the data used for control of the vehicle 2. FIG. The third control device 5 includes a reception terminal 5a, a reception unit 51, and a data transmission unit 52.

  The receiving terminal 5a is connected to an IG switch 26, which will be described later, via a harness, and receives an IG signal indicating whether the IG switch 26 is on or off.

  The receiving unit 51 receives the IG signal input to the receiving terminal 5a and converts it into IG data that is digital data. The IG data is data indicating either the on or off state of the IG switch 26. The receiving unit 51 functions as a receiving unit.

  The data transmission part 52 transmits IG data to the 1st control apparatus 3 via CAN7. The data transmission unit 52 functions as a data transmission unit.

  The harness 6 is a collective part in which a plurality of electric wires are bundled. The length of the harness 6 extends over several meters. The harness 6 connects the second receiving terminal 3b of the first control device 3 and the second control device 4, and is used for communication between the two devices. The harness 6 branches off from the branch harness 6b at the branch point 6a in the vicinity of the first control device 3. The branch harness 6 b is connected to the first receiving terminal 3 a of the first control device 3. The length of the branch harness 6b is several centimeters. Therefore, the signal transmitted from the second control device 4 via the harness 6 is also transmitted to the branch harness 6b at the branch point 6a and input to the first reception terminal 3a and the second reception terminal 3b of the first control device 3. Is done. That is, the first receiving terminal 3a and the second receiving terminal 3b receive the same control signal.

  CAN 7 is a standard used for data transfer between devices interconnected in the vehicle 2. It is used for transmission / reception of data such as ON / OFF data of the IG switch, speed data, engine speed, brake state, and failure diagnosis information.

The first control device 3 includes a first control unit 31, a second control unit 32, a state determination unit 33, a coincidence determination unit 34, a current determination unit 35, and a storage unit 36. The first control unit 31 is an IG switch. The state (on or off) is monitored, and when the on state of the IG switch is detected, an alternator described later is instructed to perform charge control. In addition, implementation of charge control functions as 1st control, and the 1st control part 31 functions as 1st control means.

  The second control unit 32 includes a DCDC converter, and performs boost control of the supply voltage to the in-vehicle device 25 when the supply voltage to the in-vehicle device 25 decreases. In addition, the pressure | voltage rise control to the vehicle equipment 25 functions as 2nd control, and the 2nd control part 32 functions as a 2nd control means.

  When the supply voltage decreases, for example, the starter 21 that starts the engine is driven. Thereby, it is possible to prevent the supply voltage to the in-vehicle device 25 from being lower than the minimum operating voltage of the in-vehicle device 25, and to prevent the in-vehicle device 25 from being reset.

  Boost control of the supply voltage to the in-vehicle device 25 is performed when returning from idle stop control. This is because the in-vehicle device 25 is executing the control even during the idling stop control, and a trouble occurs when reset. For this reason, when the engine is started at the start of the first running of the vehicle (not at the time of return from the idle stop control), the in-vehicle device 25 is before the start of the control, so there is no need to consider resetting and the boost control is performed. There is no need.

  The state determination unit 33 determines whether the IG signal and IG data received by the first control device 3 are in an on state or an off state. Moreover, the state determination part 33 detects abnormality of CAN7 and the disconnection of the harness 6 based on a determination result, memorize | stores the code | cord | chord which shows applicable abnormality in the memory | storage part 36, and makes the abnormality lamp which is not illustrated light. The state determination unit 33 functions as a state determination unit.

  The coincidence determination unit 34 determines whether or not the state of the IG signal matches the state of the IG data. That is, it is determined whether or not both the IG signal and the IG data are in an on state or an off state. The coincidence determination unit 34 functions as a coincidence determination unit.

  The current determination unit 35 detects a current value energized by the battery 23 from an ammeter (not shown) connected to the battery 23 described later. When the current value is detected, the current determination unit 35 compares the current data 36a stored in the storage unit 36 with the current value of the battery 23, and determines whether or not the current value is equal to or greater than the value indicated by the current data 36a. The current determination unit 35 functions as a current determination unit.

  The storage unit 36 is a storage medium that stores data. For example, it is a nonvolatile memory such as an EEPROM (Electrical Erasable Programmable Read-Only Memory), a flash memory, or a hard disk drive equipped with a magnetic disk. The storage unit 36 stores current data 36a.

  The current data 36a is data indicating a specific current value. The specific current value is 2 [A], for example.

  In addition to the vehicle system 1, the vehicle 2 includes a starter 21, a starter relay 22, a battery 23, an alternator 24, an in-vehicle device 25 such as a navigation 25a and an audio 25b, and an IG switch 26.

  The starter 21 is a device that starts (starts) the engine by rotating (cranking) the engine with the power of the electric motor.

  The starter relay 22 is a switch that is connected to a power source (not shown) and starts driving the starter 21.

  The battery 23 is a secondary battery that supplies power to the electrical system in the vehicle 2. For example, a lead storage battery or a lithium ion battery.

  The alternator 24 is a generator that generates electricity. The alternator 24 detects the remaining amount of electricity in the battery 23 when the first control unit 31 instructs to carry out the charge control, and charges the battery 23 with the generated electricity when the remaining amount of electricity is reduced. To do.

  The in-vehicle device 25 is an electronic control device mounted on the vehicle 2. For example, navigation 25a and audio 25b. In addition, meter devices in the inner panel, an air conditioner, a seat position adjusting device, and the like.

  The IG switch 26 is a switch for supplying and shutting off power to the electrical system in the vehicle 2. The IG switch 26 includes a cylinder lock and a push button, and is turned on or off by a user's key operation or push operation.

<1-3. Progress>
FIG. 3 is a timing chart showing the processing progress of the vehicle system 1.

  When the IG switch 26 is turned on by the user, the IG signal is turned on (time t1). When the IG signal is turned on, the second controller 4 transmits the CARNK signal to the first controller 3 and the starter relay 22 via the harness 6 with the CARNK signal turned off (Hi). When receiving the CARNK signal, the first control device 3 instructs the alternator to perform charging control.

  The starter relay 22 is turned on at the timing when the CARNK signal is turned on (Lo) (time t2). The starter 21 is driven in conjunction with the ON operation of the starter relay 22, and the engine starts driving (time t3). The engine starting time at time t3 is the initial engine starting time. Note that boost control to the in-vehicle device 25 is not performed between time t1 and time t3. This is because when the engine is initially started, the in-vehicle device 25 is not started yet, and is not reset even when the starter 21 is driven to a low voltage.

  When the vehicle 2 stops traveling, the idle stop control is started and the driving of the engine is stopped (time t4). When the user operates (steps on) the accelerator during the idle stop control, the second control device 4 turns the CARNK signal ON (Lo) (time t5).

  When the CARNK signal is turned on (Lo), the starter relay 22 is turned on (time t5). The starter 21 is driven in conjunction with the ON operation of the starter relay 22, and the engine resumes driving (time t6).

  The second control device 4 turns the CARNK signal on (Lo) for a predetermined time (for example, 3.8 [seconds]) and then reverses it to off (Hi) (time t7). When the CARNK signal is inverted to OFF (Hi), the starter relay 22 is turned OFF, and the drive of the starter 21 is stopped (time t7). The second control device 4 directly starts the starter relay after the CARNK signal is turned on (Lo), that is, after the starter relay 22 is turned on, after a predetermined time has elapsed (for example, 3.8 [seconds]). You may control so that 22 may be turned off.

  At time t <b> 5, the first control device 3 starts boost control to the in-vehicle device 25 at a timing when the CARNK signal is turned on (Lo). The boost control is continued until the starter relay 22 is turned off, and the boost control is terminated at time t7. That is, while the starter 21 is being driven, boost control is performed on the in-vehicle device 25. This is because the voltage applied to the in-vehicle device 25 decreases during this period.

  In order to discriminate between when the engine is initially started and when the engine is started by returning to idle stop control, an idle stop control flag that is turned on during idle stop control may be referred to.

<1-4. Process>
FIG. 4 shows the processing steps of the vehicle system 1. The processing step is executed immediately after the IG switch is turned on.

  First, the state determination unit 33 of the first control device 3 determines the state of the IG data received from the third control device 5 via the CAN 7, that is, whether the IG switch 26 is on or off (step S11).

  When the state determination part 33 cannot determine the state of IG data (it is No at step S11), the 1st control part 31 determines implementation or non-implementation of charge control based on the state of the IG signal received via the harness 6. Then, the alternator 24 is instructed (step S12). That is, charging control is performed when the IG signal indicates ON. In order to instruct execution or non-execution of charging control, an instruction signal may be transmitted to the alternator 24, or the contents of the instruction may be transmitted by turning on or off a flag. The non-execution instruction may be replaced with no execution instruction. The case where the state of the IG data cannot be determined is a case where an abnormality has occurred in CAN 7 and an error has occurred in the IG data. In general, it is considered that the occurrence of CAN 7 abnormality and the disconnection of the harness 6 occur at the same time, and the first control unit 31 is based on the state of the IG signal received via the harness 6 when CAN 7 is abnormal. The alternator 24 is instructed to perform charge control.

  When the first control unit 31 instructs the alternator 24 to perform charging control, the state determination unit 33 detects an abnormality in the CAN 7 (step S13). That is, the state determination unit 33 causes the storage unit 36 to store a code indicating abnormality of the CAN 7. Further, the state determination unit 33 turns on a warning lamp (not shown). When the user finds that the warning lamp is turned on, the user can recognize that an abnormality has occurred in the CAN 7 and can read out the abnormality code from the storage unit 36 and perform appropriate repairs or the like.

  When the state determination unit 33 detects an abnormality in CAN7, the process ends.

  On the other hand, when the state determination unit 33 can determine the state of the IG data (Yes in step S11), whether or not the match determination unit 34 matches the state of the IG data and the state of the CRANK signal received via the harness 6. (Step S14).

  When the coincidence determination unit 34 determines that the state of the IG data and the state of the CRANK signal match (Yes in step S14), the first control unit 31 performs or does not perform the charge control based on the determined state. Judgment is made and the alternator 24 is instructed (step S15). That is, the first control unit 31 instructs the alternator 24 to execute the charge control when both the IG data state and the CRANK signal state are ON, and instructs the non-execution of the charge control when both indicate OFF.

  When step S15 is executed, the process ends.

  On the other hand, when the coincidence determination unit 34 determines that the state of the IG data does not match the state of the CRANK signal (No in step S14), the current determination unit 35 energizes the battery 23 from the ammeter connected to the battery 23. Detect current value. When the current determination unit 35 detects the current value, the current determination unit 35 refers to the current data 36a stored in the storage unit 36 and compares the current value of the battery 23 with the current data 36a. That is, it is determined whether or not the current value of the battery 23 exceeds 2 [A] (step S16).

  If the current determination unit 35 determines that the current value of the battery 23 does not exceed 2 [A] (No in step S16), the state determination unit 33 determines that the IG switch 26 is off (step S17), and Abnormality or disconnection of the harness 6 is detected (step S18). That is, the state determination unit 33 causes the storage unit 36 to store a code indicating an abnormality of the CAN 7 or the disconnection of the harness 6.

  When step S18 is executed, the process ends.

  On the other hand, when the current determination unit 35 determines that the current value of the battery 23 exceeds 2 [A] (Yes in step S16), the state determination unit 33 determines that the IG switch 26 is on, and the first control unit 31 instructs the alternator 24 to perform charge control (step S19). Moreover, the state determination part 33 detects abnormality of CAN7 or the disconnection of the harness 6 (step S20). That is, the state determination unit 33 causes the storage unit 36 to store a code indicating an abnormality of the CAN 7 or the disconnection of the harness 6.

  When step S20 is executed, the process ends.

  As described above, according to the embodiment of the present invention, the harness 6 that connects the first control device 3 and the second control device 4 is branched in the vicinity of the first control device 3. The receiving terminal 3a and the second receiving terminal 3b are connected to each other. Thereby, it is not necessary to connect the harness 6 separately from the 2nd control apparatus 4 to the 1st receiving terminal 3a and the 2nd receiving terminal 3b, and the harness 6 can be reduced and cost can be reduced.

  A CRANK signal having a state change similar to that of the IG signal is transmitted from the second control device 4 to the first control device 3 via the harness 6. As a result, the first control device 3 can perform control based on the CRANK signal instead of control based on the conventional IG signal, and can also perform control based on the IG signal as in the conventional case.

  Since the harness 6 is branched in the vicinity of the first control device 3 and the CRANK signal is connected to the first reception terminal 3a and the second reception terminal 3b, the design of the first control device 3 is possible even if the harness 6 is reduced. There is no need to change, and the increase in cost can be suppressed.

<2. Deformation>
The embodiment of the present invention has been described above. However, the present invention is not limited to the above embodiment. It can be deformed. Hereinafter, modified examples will be described. The embodiments described above and below can be combined as appropriate.

  In the above embodiment, data communication between the first control device and the third control device is performed by CAN. However, LIN (Local Interconnect Network) may be used. LIN is also useful in systems that do not require much transfer speed, such as power windows.

  Moreover, in the said embodiment, the 2nd control part 32 assumed that the DCDC converter was provided. However, the DCDC converter may be provided outside the second control unit 32.

  Moreover, in the said embodiment, the electric current determination part 35 determined whether the electric current value of the battery 23 exceeded 2 [A]. However, it may be determined whether the current value is 2 [A] or more. There is no substantial difference in control.

  In the above embodiment, the configuration described as hardware may be realized by software. On the other hand, the function described as software may be realized by hardware. Further, hardware or software may be realized by a combination of hardware and software. For example, the contact type switch may be replaced with a push button or a touch panel.

DESCRIPTION OF SYMBOLS 1 Vehicle system 2 Vehicle 3 1st control apparatus 4 2nd control apparatus 5 3rd control apparatus 6 Harness 7 CAN

Claims (5)

A vehicle system including a first control device mounted on a vehicle and a second control device capable of communicating with the first control device,
The first control device includes:
First control means for performing first control based on the state of the signal received by the first receiving terminal on the in-vehicle device mounted on the vehicle;
Second control means for performing second control based on a state of a signal received by a second receiving terminal different from the first receiving terminal on the in-vehicle device;
With
The second control device includes:
A signal transmission means for transmitting a control signal having a state change similar to the ignition signal of the vehicle to the first control device via a wire harness;
With
The wire harness is branched in the vicinity of the first control device and connected to each of the first reception terminal and the second reception terminal;
The vehicle system, wherein the first receiving terminal and the second receiving terminal receive the same control signal. The vehicle system according to claim 1,
A third control device capable of communicating with the first control device;
Further including
The third control device includes:
Receiving means for receiving an ignition signal from the ignition switch;
Data transmitting means for transmitting state data indicating the state of the ignition signal to the first control device via the information transmission path;
A vehicle system comprising: The vehicle system according to claim 2,
The first control device includes:
State determination means for determining the state of the ignition signal based on the state data;
Further comprising
The first control means includes
When the state determination means can determine the state of the ignition signal, the first control is performed based on the state of the ignition signal and the state of the control signal received by the first reception terminal,
When the state determination means cannot determine the state of the ignition signal, the vehicle system is characterized in that the first control is performed based only on the state of the control signal. The vehicle system according to claim 3,
The first control device includes:
A coincidence determining means for determining whether or not a first state of the ignition signal based on the control signal matches a second state of the ignition signal based on the state data;
Current determination means for determining whether or not a current supplied to a battery included in the vehicle exceeds a predetermined value;
Further comprising
The first control means includes
The vehicle system according to claim 1, wherein when the first state and the second state do not match and the current does not exceed the predetermined value, the ignition signal is determined to be in an off state. The vehicle system according to claim 4,
The first control means includes
The vehicle system according to claim 1, wherein when the first state and the second state do not match and the current exceeds the predetermined value, the ignition signal is determined to be an on state.

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