JP2013104347A - Electronic controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic controller configured to handle a failure without reboot.SOLUTION: The electronic controller includes a control part for controlling power to be supplied to an assist motor and operation thereof, a failure diagnosing part for diagnosing a failure during start-up and operation of the control part, and a CAN communication part. The control part controls the failure diagnosing part to diagnose a failure. When a failure is detected, the power to be supplied to the assist motor is cut off. When the CAN communication part receives a signal indicating release of an idle stop state from other devices, the failure diagnosing part diagnoses the failure again. When the failure is detected as a result of the diagnosis, the power cut to the assist motor is continued. When no failure is detected, power is supplied to the assist motor.

Description

  The present invention relates to an electronic control device mounted on a vehicle system that performs idle stop control.

  Recently, for the purpose of reducing fuel consumption and reducing emissions, there are vehicles that perform idle stop control that automatically stops the engine temporarily when the vehicle stops due to a signal or the like. In such a vehicle, the engine is stopped during the idle stop control. Then, after the idle stop control is stopped, the engine starting motor is driven to restart the engine. As a technique for improving safety at the time of engine restart, for example, there is one disclosed in Patent Document 1.

  Conventionally, various systems and devices for performing failure diagnosis as disclosed in, for example, Patent Documents 2 to 6 are mounted on a vehicle system.

  In the fuel injection system of Patent Document 2, after the internal combustion engine is started, the presence or absence of a failure of the fuel injection device body is determined, and when the failure detection means detects that a failure has occurred, a control signal for stopping the engine is output. This completes the fuel injection control operation. Further, when a stop command signal for stopping the rotation of the internal combustion engine for the idle stop operation is output from the fuel injection device main body, a simulated failure signal is output from the simulated failure generating means to check whether or not the failure detecting means has failed. Determine.

  In the failure determination device of Patent Document 3, a failure of the temperature sensor is diagnosed after the engine is started in order to perform highly accurate failure diagnosis of the temperature sensor that detects a temperature that changes according to the operating state of the engine. When the engine is stopped and the failure determination condition for the temperature sensor is satisfied, the failure of the temperature sensor is re-diagnosed after a predetermined time has elapsed, and the diagnosis result is determined.

  In the control device of Patent Literature 4, when an automatic stop condition for idle stop control is established during engine operation, if an abnormality diagnosis to be executed before that is not executed, automatic stop is prohibited. Then, the abnormality diagnosis execution condition is switched from the running condition to the idle driving condition, and the abnormality diagnosis is executed with the engine idling while the vehicle is stopped, and then automatic stop is permitted. Further, when the determination result of the abnormality diagnosis performed while the engine is operating belongs to the gray zone, the automatic stop is prohibited and the abnormality diagnosis is performed again while the engine is idling.

  In the seat belt device of Patent Document 5, as a failure diagnosis, an initial diagnosis is performed when the ignition state is switched from OFF to ON and the ECU is activated. Further, when the vehicle is not in the idle stop state and is running, a diagnosis is always performed. Furthermore, after the power supply voltage is lowered and the ECU is reset during idle stop, reset diagnosis is performed when the power supply voltage rises due to the operation of the alternator and the ECU is activated.

  In the control device of Patent Document 6, when the state shifts to the idle stop state, power supply to the EPS (electric power steering) motor is stopped, and power supply to the EPS control unit is not stopped. As a result, conventionally, startup processing such as failure diagnosis that is performed when power supply to the EPS control unit is started is not performed after the engine is restarted due to the idle stop stop.

  In the control device that controls the operation of the control target, when a failure that may interfere with the control is detected, power supply to the control target is stopped, and the control target is not controlled. However, some of these failures are temporary and then go away. For example, in a fault diagnosis of a relay provided on the power supply line to be controlled, if a foreign object having insulating properties is sandwiched between the contacts, the contact does not turn on and power cannot be supplied to the control target. To detect. However, after that, when the foreign object moves between the contacts due to vibration or the like, the above failure is resolved.

  In this way, even if the once detected failure is resolved thereafter, the control target is not driven and control of the control target is not performed as long as the control device still stops supplying power to the control target. . When the ignition state is once turned off and then turned on and the control device is restarted, the failure diagnosis may be redone.

JP 2010-77904 A JP 2001-304025 A JP 2008-25468 A JP 2008-155101 A JP 2011-131671 A JP 2010-248964 A

  An object of the present invention is to provide an electronic control device that can cope with occurrence and elimination of a failure without restarting.

  An electronic control device according to the present invention includes a control unit that controls power supply and operation to an object to be controlled, a failure diagnosis unit that diagnoses a failure when the control unit is activated and in operation, and other devices of the vehicle system A receiving unit that receives a signal indicating cancellation of the idle stop state. When the failure diagnosis unit detects a failure, the control unit stops power supply to the controlled object, and when the reception unit receives a signal indicating the release of the idle stop state, the failure diagnosis unit diagnoses the failure again. As a result of the diagnosis, when a failure is detected, power supply to the controlled object is stopped, and when no failure is detected, power is supplied to the controlled object.

  In addition, another electronic control device according to the present invention includes a control unit that controls power supply and operation to a control target, a failure diagnosis unit that diagnoses a failure when the control unit is activated and in operation, and a vehicle system A receiving unit that receives a signal indicating an idle stop state from another device. When the failure diagnosis unit detects a failure, the control unit stops power supply to the control target, and when the reception unit receives a signal indicating an idle stop state, the failure diagnosis unit diagnoses the failure again. As a result of the diagnosis, when a failure is detected, power supply to the controlled object is stopped, and when no failure is detected, power is supplied to the controlled object.

  According to the above, after the failure is detected and the power supply to the controlled object is stopped, the failure is diagnosed again when the vehicle enters the idle stop release state or the idle stop state. Then, when the failure has been resolved, it is possible to supply power to the controlled object and control the operation of the controlled object. Therefore, the electronic control device can cope with the occurrence and resolution of the failure without restarting.

  In the present invention, in the electronic control device, the failure diagnosis performed by the failure diagnosis unit at the time of starting the control unit is different from the failure diagnosis performed by the failure diagnosis unit during the operation of the control unit, and the operation of the control target The control unit may include the content that needs to be stopped, and the failure diagnosis unit may perform the failure diagnosis at the start-up as the second failure diagnosis performed once the failure is detected.

  In the present invention, in the electronic control device, even when a failure is detected by the failure diagnosis unit, power supply to the control unit may be continued.

  Further, according to the present invention, in the electronic control device, the control unit may continue to control the operation of the controlled object even when the vehicle is in an idle stop state while controlling the operation of the controlled object.

  ADVANTAGE OF THE INVENTION According to this invention, even if it does not restart, the electronic control apparatus which can respond to generation | occurrence | production and elimination of a failure can be provided.

It is a block diagram of EPS-ECU which concerns on embodiment of this invention. It is the figure which showed the control part with which EPS-ECU of FIG. 1 is equipped. It is the figure which showed an example of the vehicle system. It is an operation | movement flowchart of EPS-ECU of FIG. It is an operation | movement flowchart of EPS-ECU which concerns on other embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals.

  First, the configuration of an EPS-ECU (electric power steering electronic control device) 100 according to the present embodiment will be described with reference to FIGS. The EPS-ECU 100 is an example of the “electronic control device” in the present invention.

  The electric power steering unit and the idle stop unit shown in FIG. 3 are mounted on the same vehicle system. In the electric power steering unit, the EPS-ECU 100 drives the assist motor 10 to operate a known drive mechanism 50 to assist the steering operation of the vehicle. The EPS-ECU 100 is connected to an IDS-ECU (idle stop electronic control unit) 200 of an idle stop unit by a CAN (car area network).

  In the idle stop unit, the IDS-ECU 200 performs idle stop control and stops the engine 70 of the vehicle when a predetermined stop condition is satisfied. This state is an idle stop state. Thereafter, when a predetermined restart condition is satisfied, IDS-ECU 200 stops idle stop control, drives starter motor 60, and restarts engine 70. This state is an idle stop release state.

  The IDS-ECU 200 transmits an IDS signal indicating that the vehicle is in the idle stop state and an IDS release signal indicating that the idle stop state has been released to the EPS-ECU 100 by CAN. The ECUs 100 and 200 and the motors 10 and 60 are supplied with electric power from the battery 80.

  In the EPS-ECU 100 shown in FIG. 1, the control unit 1 includes a CPU and a memory. The power supply voltage detection unit 2 detects a power supply voltage input from the battery 80 to the EPS-ECU 100. The control power supply generation unit 3 converts the voltage of the battery 80 into a voltage having a predetermined magnitude, and generates a power supply for the control unit 1. Note that VBAT in FIG. 1 represents power supplied from the battery 80 to each unit.

  The IG (ignition) voltage detection unit 4 is connected to one end of the IG switch 40 via a diode 39. The other end of the IG switch 40 is connected to the battery 80. The IG voltage detector 4 detects a voltage appearing at one end of the IG switch 40. For example, when the IG switch 40 is in an OFF state (open state), the IG voltage detector 4 detects a low level voltage, and an IG-OFF signal (low voltage) indicating that the IG switch 40 is in the OFF state. Signal) to the control unit 1. Further, when the IG switch 40 is turned on (closed state), the IG voltage detector 4 detects a high level voltage, and an IG-ON signal (high voltage) indicating that the IG switch 40 is turned on. Signal) to the control unit 1.

  The torque sensor power supply generation unit 6 is connected to the source of the FET 5. The drain of the FET 5 is connected to the power supply VBAT. The gate of the FET 5 is connected to the control unit 1. When the control unit 1 inputs a drive signal to the gate of the FET 5 and the FET 5 is turned on, the torque sensor power source generation unit 6 converts the voltage of the power source VBAT into a voltage of a predetermined magnitude, and for the torque sensor 41 Generate power for

  The torque sensor power supply voltage detection unit 7 detects the power supply voltage input from the torque sensor power supply generation unit 6 to the torque sensor 41. The torque sensor signal detection unit 8 detects the output signal of the torque sensor 41. The control unit 1 detects the steering torque applied to the rotation shaft of the vehicle handle based on the output of the torque sensor signal detection unit 8.

  The CAN communication unit 9 is an interface for communicating with other devices of the vehicle system by CAN. Other devices include IDS-ECU 200. The control unit 1 receives the IDS signal and the IDS release signal transmitted from the IDS-ECU 200 by the CAN communication unit 9. The CAN communication unit 9 is an example of the “reception unit” in the present invention.

  The assist motor 10 is a three-phase brushless motor. The motor drive circuit 11 includes a bridge circuit having six FETs 12a to 12f and three shunt resistors 13a to 13c. The motor drive circuit 11 drives the assist motor 10 by energizing the A phase, the B phase, and the C phase of the assist motor 10.

  The gate drive unit 14 inputs a drive signal to the gates of the FETs 12a to 12f of the motor drive circuit 11, and switches the ON / OFF states of the FETs 12a to 12f. The control unit 1 inputs a gate drive permission signal to the gate drive unit 14 and controls the motor drive circuit 11 via the gate drive unit 14. Specifically, the control unit 1 controls the magnitude and direction of the current flowing in each phase of the assist motor 10 by switching the ON / OFF states of the FETs 12 a to 12 f by the gate driving unit 14. The motor phase current detection unit 15 detects a current flowing in each phase of the assist motor 10 based on the voltages at both ends of each shunt resistor 13a to 13c.

  A motor relay 16 is provided between the motor drive circuit 11 and the assist motor 10. Specifically, the contact of the motor relay 16 is connected to two energization lines among the three energization lines from the motor drive circuit 11 to the assist motor 10. A coil (not shown) of the motor relay 16 is connected between the power supply VBAT and the motor relay drive unit 17. The motor relay drive unit 17 includes a switching element and the like.

  The control unit 1 switches the ON / OFF state of the motor relay 16 by the motor relay driving unit 17. Specifically, the control unit 1 drives the motor relay drive unit 17 to energize the coil of the motor relay 16 and turn on the contact of the motor relay 16. Moreover, the control part 1 stops the drive of the motor relay drive part 17, stops energization to the coil of the motor relay 16, and makes the contact of the motor relay 16 an OFF state.

  When the motor relay 16 is turned on, the motor drive circuit 11 and the assist motor 10 are electrically connected. When the motor relay 16 is turned off, the motor drive circuit 11 and the assist motor 10 are electrically disconnected. The motor terminal voltage detector 18 detects a voltage applied to each phase terminal of the assist motor 10.

  A power relay 19 is provided between the battery 80 and the motor drive circuit 11. A capacitor 20 is provided between the power supply relay 19 and the motor drive circuit 11. A shunt resistor 21 is provided between the capacitor 20 and the motor drive circuit 11. That is, the contact of the power relay 19, the capacitor 20, and the shunt resistor 21 are connected on the energization line from the battery 80 to the motor drive circuit 11.

  A coil (not shown) of the power supply relay 19 is connected between the power supply VBAT and the power supply relay drive unit 22. The power relay drive unit 22 is composed of a switching element and the like. The control unit 1 switches the ON / OFF state of the power relay 19 by the power relay driving unit 22. Specifically, the control unit 1 drives the power supply relay drive unit 22 to energize the coil of the power supply relay 19 to turn on the contact of the power supply relay 19. In addition, the control unit 1 stops driving the power supply relay drive unit 22 to stop energization of the coil of the power supply relay 19 and turns off the contact of the power supply relay 19.

  When the power supply relay 19 is turned on, the battery 80 and the motor drive circuit 11 are electrically connected. When the power supply relay 19 is turned off, the battery 80 and the motor drive circuit 11 are electrically disconnected.

  Capacitor 20 smoothes the voltage of battery 80. The motor / capacitor voltage detector 23 detects the voltage applied to the motor drive circuit 11. The motor / capacitor voltage detector 23 detects the voltage of the capacitor 20 when the power supply relay 19 is in the OFF state. The overcurrent detection unit 24 detects an overcurrent flowing through the motor drive circuit 11 based on the voltage across the shunt resistor 21.

  The self-holding circuit 25 is provided in parallel with the power supply relay 19. The drain of the FET 26 of the self-holding circuit 25 is connected to the battery 80 via the diode 38. The source of the FET 26 is connected to the cathode of the diode 35 of the precharge circuit 27, the drain of the FET 28, the power supply voltage detection unit 2, and the control power supply generation unit 3. The gate of the FET 26 is connected to the IG switch 40 through the diode 36 and is connected to the control unit 1 through the diode 37.

  The source of the FET 28 of the precharge circuit 27 is connected to one end of the resistor 29. The other end of the resistor 29 is connected to the anode of the diode 35, the power supply relay 19, and the capacitor 20. The gate of the FET 28 is connected to the control unit 1.

  When the IG switch 40 is turned on, the power of the battery 80 is input to the gate of the FET 26 of the self-holding circuit 25 via the IG switch 40 (IGN in the figure). Then, the FET 26 is turned on, and the electric power from the battery 80 is supplied to the power supply voltage detection unit 2, the control power generation unit 3, the coils of the relays 16 and 19, and the drain of the FET 5 through the diode 38 and the FET 26. Is done. Then, the control power generation unit 3 turns on the power to the control unit 1 and the control unit 1 is activated. After the start-up, when the control unit 1 inputs a drive signal to the gate of the FET 26, the ON state of the FET 26 is maintained, and the supply of power from the battery 80 to each of the above units is continued.

  Further, when the control unit 1 inputs a drive signal to the gate of the FET 28 of the precharge circuit 27, the FET 28 is turned on, and the power from the battery 80 is passed through the diode 38, the FET 26, the FET 28, and the resistor 29. It is supplied to the capacitor 20. The capacitor 20 is charged by the precharge circuit 27 when the power supply relay 19 is in the OFF state.

  The motor drive circuit 11, the relays 16 and 19, the capacitor 20, the shunt resistor 21, and the thermistor 30 are mounted on the same substrate. The temperature detector 31 detects the temperature around the motor drive circuit 11 by the thermistor 30.

  The resolver power supply generation unit 32 generates a power supply for the resolver 42 based on the output from the control unit 1. The resolver power supply voltage detection unit 33 detects the power supply voltage input from the resolver power supply generation unit 32 to the resolver 42. The resolver signal detector 34 detects the output signal of the resolver 42. The control unit 1 detects the rotation angle of the assist motor 10 based on the output of the resolver signal detection unit 34.

  As shown in FIG. 2, the control unit 1 includes a relay control unit 1a, a motor control unit 1b, and a failure diagnosis unit 1c. These are configured by software, for example.

  The relay control unit 1 a controls the motor relay driving unit 17 and the power relay driving unit 22 to switch the ON / OFF state of the motor relay 16 and the power relay 19. That is, the control unit 1 controls the power supply to the assist motor 10 by driving the relays 16 and 19 by the relay control unit 1a and the relay driving units 17 and 22.

  The motor control unit 1b controls the gate drive unit 14 based on the steering torque of the steering wheel, the rotation angle of the assist motor 10, and the current and voltage of each phase of the assist motor 10 detected by each unit as described above. The assist motor 10 is driven by the motor drive circuit 11. That is, the control unit 1 controls the operation of the assist motor 10 by driving the motor drive circuit 11 by the motor control unit 1 b and the gate drive unit 14. The assist motor 10 is an example of the “control target” in the present invention.

  The failure diagnosis unit 1c diagnoses a predetermined failure when the control unit 1 is activated based on the activation diagnosis program 1d (hereinafter, this failure diagnosis is referred to as “activation diagnosis”). Further, the failure diagnosis unit 1c diagnoses a predetermined failure during operation of the control unit 1 based on the in-operation diagnosis program 1e (hereinafter, this failure diagnosis is referred to as “in-operation diagnosis”).

  When a failure occurs, the failure must be detected by the failure detection function mainly of the failure diagnosis unit 1c, and the steering operation assist must be stopped by the stop means. For this reason, the control unit 1 performs a startup diagnosis at the time of startup by the failure diagnosis unit 1c, and periodically performs an operation diagnosis during operation. Thereafter, when the assist operation is resumed, it must be possible to confirm that the location where the failure has occurred functions normally. For this reason, after detecting a failure once, the control part 1 performs a diagnosis at the time of starting again by the failure diagnosis part 1c.

  The contents of the start-up diagnosis and the in-operation diagnosis are different. The startup diagnosis is a diagnosis for detecting a failure in the failure detection function and the stopping means. The start-up diagnosis includes contents that need to stop the operation of the assist motor 10 and contents that need to lock the handle. For this reason, it is desirable that the startup diagnosis be performed immediately after the control unit 1 is started or while the vehicle is stopped. As a diagnosis at the time of start-up, for example, ON / OFF fixation of each contact of the motor relay 16 and the power relay 19, an abnormality in gate drive of the FETs 12 a to 12 f of the motor drive circuit 11, and an abnormality in power supply to the torque sensor 41 and power supply stop and so on.

  On the other hand, the diagnosis during operation is a diagnosis for detecting a failure of the assist function in order to confirm whether or not the steering operation is normally assisted and whether or not the assist may be continued. The in-operation diagnosis is performed when the assist function is not stopped. As the diagnosis during operation, for example, a diagnosis such as whether overcurrent is flowing in the assist motor 10 or the motor drive circuit 11, whether the current is flowing normally, or whether the EPS-ECU 100 is overheated is performed. is there. The result of the failure diagnosis is stored in the memory of the control unit 1.

  Next, the operation of the EPS-ECU 100 will be described with reference to FIG.

  When the IG switch 40 in FIG. 1 is operated to the ON state, power supply to the control unit 1 is started, the control unit 1 is activated, and receives an IG-ON signal from the IG voltage detection unit 4 (in FIG. 4). Step S1). And the control part 1 makes FET12a-12f of the power supply relay 19, the motor relay 16, and the motor drive circuit 11 OFF state (step S2). As a result, power supply to the assist motor 10 and control of the operation of the assist motor 10 remain stopped.

  Next, the control unit 1 performs a startup diagnosis by the failure diagnosis unit 1c (step S3). Here, if the startup diagnosis is OK (step S4: YES), that is, if no failure is detected by the startup diagnosis, the control unit 1 controls the power relay 19, the motor relay 16, and the motor drive circuit 11. The FETs 12a to 12f are turned on (step S5). Thereby, power supply to the assist motor 10 is started.

  Then, the control unit 1 performs an in-operation diagnosis by the failure diagnosis unit 1c (step S6). If the in-operation diagnosis is OK (step S7: YES), that is, if no failure is detected in the in-operation diagnosis, the control unit 1 controls the operation of the assist motor 10 to assist the steering operation. (Step S8). The control unit 1 continues to control the operation of the assist motor 10 even when the vehicle is in an IDS (idle stop) state during the control of the operation of the assist motor 10, that is, during the assist of the steering operation. Assistance is implemented.

  And the control part 1 monitors reception of an IG-OFF signal (step S9). Steps S6 to S9 are periodically executed while the IG switch 40 is in the ON state.

  Thereafter, when the IG switch 40 is operated in the OFF state, the control unit 1 receives an IG-OFF signal from the IG voltage detection unit 4 (step S9: YES). Then, the control unit 1 turns off the power supply relay 19, the motor relay 16, and the FETs 12a to 12f of the motor drive circuit 11 (step S10), and ends the operation. Thereby, the power supply to the assist motor 10 and the control of the operation of the assist motor 10 are stopped, and the assist of the assist motor 10 and the steering wheel operation is stopped. Further, when the IG switch 40 is operated in the OFF state, the power supply to the control unit 1 is stopped, and the control unit 1 enters the stop state.

  On the other hand, if a failure is detected by the startup diagnosis in step S3, the control unit 1 receives the IDS release signal (signal indicating release of the idle stop state) because the startup diagnosis is not OK (step S4: NO). Is monitored (step S12). Moreover, the control part 1 monitors reception of an IG-OFF signal (step S13). At this time, power supply to the control unit 1 is continued.

  On the other hand, when a failure is detected in the operation diagnosis in step S6, the control unit 1 determines that the operation diagnosis is not OK (step S7: NO), so the power supply relay 19, the motor relay 16, and the FET 12a of the motor drive circuit 11 To 12f are turned off (step S11). Thereby, power supply to the assist motor 10 and control of the operation of the assist motor 10 are stopped. At this time, power supply to the control unit 1 is continued. However, the control part 1 will be in the standby state which operate | moves with a voltage lower than usual.

  And the control part 1 monitors reception of an IDS cancellation | release signal (step S12). Moreover, the control part 1 monitors reception of an IG-OFF signal (step S13).

  Thereafter, when the control unit 1 receives an IDS release signal from the IDS-ECU 200 via the CAN communication unit 9 (step S12: YES), the failure diagnosis unit 1c performs the startup diagnosis again (step S3).

  If the previously detected failure is a failure detected in the previous startup diagnosis and has already been resolved, the failure is not detected and the startup diagnosis is OK again (step S4: YES) ). For this reason, the control part 1 sets FET12a-12f of the power supply relay 19, the motor relay 16, and the motor drive circuit 11 to an ON state (step S5). Thereby, power supply to the assist motor 10 is started. Thereafter, the control unit 1 executes the subsequent processing.

  In addition, if the failure detected in the previous startup diagnosis has not been resolved by the time of performing the startup diagnosis again, the failure is detected again and the startup diagnosis is not OK again (step S4: NO). For this reason, the control part 1 monitors reception of an IDS cancellation | release signal and an IG-OFF signal again (step S12 and step S13).

  On the other hand, if the previously detected failure is a failure detected in the previous in-operation diagnosis and no failure is detected in the re-startup diagnosis, the re-startup diagnosis is OK (step S4: YES). For this reason, the control unit 1 turns on the power supply relay 19, the motor relay 16, and the FETs 12 a to 12 f of the motor drive circuit 11 (Step S <b> 5), and starts power supply to the assist motor 10.

  Then, the control unit 1 performs the in-operation diagnosis again by the failure diagnosis unit 1c (step S6). At this time, if the failure detected in the previous in-operation diagnosis has been resolved, the failure is not detected, and the in-operation diagnosis again is OK (step S7: YES). For this reason, the control part 1 controls operation | movement of the assist motor 10, and implements steering operation assist (step S8). At this time, when the control unit 1 is in the standby state, the standby state is canceled, and after the normal state, the operation of the assist motor 10 is controlled to assist the steering operation. Thereafter, the control unit 1 executes the subsequent processing.

  If the failure detected in the previous in-operation diagnosis has not been resolved by the time when the in-operation diagnosis is performed again, the failure is detected again, and the in-operation diagnosis is not OK again (step S7: NO). Therefore, the control unit 1 turns off the power supply relay 19, the motor relay 16, and the FETs 12 a to 12 f of the motor drive circuit 11 (step S <b> 11), supplies power to the assist motor 10, and controls the operation of the assist motor 10. To stop. And the control part 1 monitors reception of an IDS cancellation | release signal and an IG-OFF signal again (step S12 and step S13).

  Thereafter, when the IDS release signal is not received (step S12: NO) and the IG switch 40 is operated to be in the OFF state, the control unit 1 receives the IG-OFF signal from the IG voltage detection unit 4 (step S13: YES). And the control part 1 complete | finishes operation | movement, and will be in a halt condition.

  In the embodiment of FIG. 4, when an IDS release signal is received (step S12: YES) after a failure is detected by the startup diagnosis or the operating diagnosis (step S4: NO, step S7: NO), the startup diagnosis Is performed again (step S3), but the present invention is not limited to this.

  In addition to this, for example, as shown in FIG. 5, after the controller 1 detects a failure in the startup diagnosis or the in-operation diagnosis (step S4: NO, step S7: NO), the IDS signal (indicates the idle stop state) When the signal is received (step S12a: YES), the startup diagnosis may be performed again (step S3). That is, in the embodiment of FIG. 5, the control unit 1 monitors the reception of the IDS signal after detecting a failure in the startup diagnosis or the in-operation diagnosis (step S12a).

  According to each of the above embodiments, when a failure is detected by the start-up diagnosis or the in-operation diagnosis and the power supply to the assist motor 10 is stopped, and then the vehicle enters the idle stop release state or the idle stop state. The startup diagnosis is performed again.

  If the previously detected failure is a failure detected by the previous startup diagnosis and is resolved, the failure is not detected by the startup diagnosis again, and power is supplied to the assist motor 10 to assist. The operation of the motor 10 can be controlled to assist the steering operation.

  If the previously detected failure is a failure detected in the previous in-operation diagnosis and no failure is detected in the start-up diagnosis again, the assist motor 10 is powered and operating. Diagnosis is performed again. If the failure detected in the previous in-operation diagnosis is resolved, the failure is not detected in the in-operation diagnosis again, the power supply to the assist motor 10 is continued, and the operation of the assist motor 10 is controlled. Handle operation assist can be implemented.

  Therefore, in the EPS-ECU 100, it is possible to cope with the occurrence and elimination of the failure without restarting the control unit 1.

  In the embodiment of FIG. 4, the start-up diagnosis is performed again immediately after the vehicle releases the idle stop state. Therefore, if the failure is resolved at this time, the vehicle is about to start immediately after the engine is started. When the vehicle is stopped (when the vehicle is stopped or at an extremely low speed), the assist motor 10 can be supplied with power to control the operation of the assist motor 10 and assist the steering wheel operation.

  In addition, before the vehicle enters the idle stop state, a failure that becomes a starting point is detected, and power supply to the assist motor 10 is stopped. Therefore, the start of power supply to the assist motor 10 is delayed from the time of engine start. However, users do not feel any change.

  In the embodiment of FIG. 5, the startup diagnosis is performed again when the vehicle is in the idle stop state. Therefore, if the failure is resolved at this time, the vehicle is stopped before the engine is started. Electric power can be supplied to control the operation of the assist motor 10 to assist steering operation.

  In the above embodiment, when the vehicle is in the idle stop state, or immediately after releasing the idle stop state, that is, when the vehicle is about to start moving immediately after the engine is stopped or immediately after the engine is started. In addition, it is possible to safely perform the start-up diagnosis that needs to stop the operation of the assist motor 10 again.

  In the above embodiment, even if a failure is detected by the startup diagnosis or the in-operation diagnosis, the power supply to the control unit 1 is continued, so that the control unit 1 can reliably perform the startup diagnosis again. it can.

  Furthermore, in the above embodiment, during the control of the operation of the assist motor 10, even if the vehicle is in an idle stop state, the control of the operation of the assist motor 10 is continued. The convenience of the user.

  The present invention can employ various embodiments other than those described above. For example, in the above-described embodiment, an example in which the contents of the startup diagnosis and the in-operation diagnosis are different has been described, but the present invention is not limited to this. The contents of the start-up diagnosis and the in-operation diagnosis may be all or part of the same, or one content may be a part of the other content omitted. Further, the content of the failure diagnosis is not limited to the content described in the above embodiment.

  Moreover, although the example which applied this invention to EPS-ECU100 was given in the said embodiment, this invention is applied also to the electronic control apparatus with the control object mounted in the other vehicle system. Is possible. Further, the control target may be a device other than the motor.

DESCRIPTION OF SYMBOLS 1 Control part 1c Failure diagnosis part 9 CAN communication part 10 Assist motor 100 EPS-ECU
200 IDS-ECU

Claims (5)

A control unit that controls power supply and operation to the controlled object;
A fault diagnosis unit for diagnosing a fault when the control unit is activated and in operation;
A receiver that receives a signal indicating release of the idle stop state from another device of the vehicle system,
The controller is
When a failure is detected by the failure diagnosis unit, power supply to the controlled object is stopped,
After that, upon receiving a signal indicating the release of the idle stop state by the receiving unit, the failure diagnosing unit diagnoses the failure again,
As a result of the diagnosis,
If a failure is detected, continue power supply to the controlled object,
An electronic control device, characterized in that when no failure is detected, power is supplied to the control object. A control unit that controls power supply and operation to the controlled object;
A fault diagnosis unit for diagnosing a fault when the control unit is activated and in operation;
A receiver for receiving a signal indicating an idle stop state from another device of the vehicle system,
The controller is
When a failure is detected by the failure diagnosis unit, power supply to the controlled object is stopped,
After that, upon receiving a signal indicating an idle stop state by the receiving unit, the failure diagnosis unit diagnoses the failure again,
As a result of the diagnosis,
If a failure is detected, continue power supply to the controlled object,
An electronic control device, characterized in that when no failure is detected, power is supplied to the control object. The electronic control device according to claim 1 or 2,
The failure diagnosis performed by the failure diagnosis unit when the control unit is started is different from the failure diagnosis performed by the failure diagnosis unit during the operation of the control unit, and the operation needs to be stopped. Including
The electronic control device, wherein the control unit performs a failure diagnosis at the start-up by the failure diagnosis unit as the second failure diagnosis performed once a failure is detected. The electronic control device according to any one of claims 1 to 3,
An electronic control device, wherein power supply to the control unit is continued even if a failure is detected by the failure diagnosis unit. The electronic control device according to any one of claims 1 to 4,
The control unit continues to control the operation of the control target even when the vehicle is in an idle stop state while controlling the operation of the control target.

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