JP7163952B2 - Control device, system, control method and vehicle - Google Patents

Description

The present invention relates to a control device , system , control method and vehicle.

Patent Literature 1 describes a vehicle lateral motion control system that controls the lateral motion of the vehicle by driving actuators respectively provided for front steering, rear steering, and brakes. In the system described in Patent Document 1, the availability representing the controllable range of each actuator is acquired, and the acquired availability is used to perform feedforward control of each actuator and F/F request values for feedforward control of each actuator. Then, based on the calculated F/F request value and F/B request value, the mechanism to be controlled and the control amount to be finally generated in the mechanism are determined. ing.

JP 2012-96619 A

2. Description of the Related Art In recent years, as the number of driving support functions installed in vehicles has increased, the processing executed by actuators in response to requests from multiple applications has become more complicated. Therefore, the vehicle is provided with an arbitration function unit that relays signal transmission/reception between a plurality of applications and a plurality of actuators and mediates requests from a plurality of applications. A system configuration that feeds back to each application is conceivable.

SUMMARY OF THE INVENTION An object of the present invention is to provide a control device or the like that arbitrates requests from a plurality of applications.

One embodiment of the present invention is a control device mounted on a vehicle, comprising: a request arbitration unit that receives a plurality of request signals from a plurality of driving assistance applications and mediates requests from the plurality of driving assistance applications; a request generation unit that generates a drive request for the actuator based on the arbitration result of the arbitration unit, and the request arbitration unit outputs actuator status information to a plurality of driving support applications when the request arbitration unit is not abnormal. If the request arbitration unit is abnormal, information indicating that the request arbitration unit is abnormal is output to the control unit that controls the actuator.

According to the present invention, it is possible to provide a control device or the like that arbitrates requests from a plurality of applications.

1 is a functional block diagram of a vehicle control device according to an embodiment; Functional block diagram of the request arbitration unit shown in FIG. Functional block diagram of the control unit shown in FIG. Flowchart showing control processing executed by the control unit shown in FIG.

(Overview)
A vehicle control device according to the present invention includes a request arbitration unit that arbitrates requests from a plurality of application execution units between a plurality of application execution units that implement driving support functions and a control unit that controls actuators. The control unit that controls the actuator feeds back information indicating the state of the actuator to the application execution unit through the request arbitration unit when the request arbitration unit is operating normally, and directly provides information indicating the state of the actuator when the request arbitration unit is abnormal. Feedback to the application execution part. Therefore, regardless of the operation state of the request arbitration unit, the state of the actuator can be reliably fed back to the application execution unit that implements the driving support function.

(embodiment)
<Configuration>
FIG. 1 is a functional block diagram of the vehicle control device according to the embodiment. In FIG. 1 , solid-line arrows represent request signal transmission paths from the application execution unit 5 to the actuator 4 , and broken-line arrows represent signal feedback paths from the actuator 4 to the application execution unit 5 .

The vehicle control device 10 is a device that controls actuators 4 provided in the vehicle based on requests from a plurality of application execution units 5 . The application execution unit 5 is a device that executes an application that implements vehicle driving support functions such as automatic driving, automatic parking, adaptive cruise control, lane keep assist, and collision mitigation braking, and is typically implemented by an ECU. be. A plurality of application execution units 5 may simultaneously execute an application depending on the driving support function to be used. Although three application execution units 5 are shown in FIG. 1 for simplification of explanation, the number of application execution units that implement the driving support function is not limited, and two or less or four or more application execution units are shown. In some cases, the part is mounted on the vehicle. The application execution unit 5 outputs a request signal for operating the actuator 4 to the request arbitration unit 1, which will be described later. The actuator 4 is a drive mechanism that operates a power train (sometimes called a drive train), a braking device, a steering device, etc., and is controlled by the control unit 3, which will be described later.

The vehicle control device 10 includes a request arbitration unit 1 , a request generation unit 2 and a control unit 3 .

The request arbitration unit 1 receives request signals output from a plurality of application execution units 5, and selects one request signal from among the received plurality of request signals based on a predetermined selection criterion. It arbitrates requests from the application execution unit 5 .

The request generation unit 2 generates a drive request for the actuator 4 based on the arbitration result of the request arbitration unit 1, that is, the request signal selected by the request arbitration unit 1, and outputs the generated drive request to the control unit 3. .

The control unit 3 is an ECU that controls the actuator 4 . In the example of FIG. 1, one controller 3 controls one or two actuators 4, but the number of actuators controlled by the controller 3 may be three or more.

The request arbitration unit 1, the request generation unit 2, the control unit 3, the actuator 4, and the application execution unit 5 are communicably connected via a communication network. As a feedback path of a signal to , a first feedback path that transmits a signal to the application execution unit 5 via the request arbitration unit 1 and a signal that is transmitted directly to the application execution unit 5 without going through the request arbitration unit 1 A second feedback path is provided for The details of these two types of feedback paths will be described later. The communication network that connects the actuator 4 and the application execution unit 5 via the request arbitration unit 1 and the communication network that directly connects the actuator 4 and the application execution unit 5 may be the same or different. .

In the example of FIG. 1, the vehicle control device 10 includes three request generators 2 and three controllers 3, but the number of request generators 2 and controllers 3 is not limited to this.

Hereinafter, detailed configurations of the request arbitration unit 1 and the control unit 3 will be described with reference to FIGS. 2 and 3. FIG.

FIG. 2 is a functional block diagram of a request arbitration unit shown in FIG. 1;

The request arbitration unit 1 includes an arbitration processing unit 11 , a state information reception unit 12 and a state information output unit 13 .

The arbitration processing unit 11 receives request signals from a plurality of application execution units 5 and performs arbitration processing, that is, processing for selecting one request signal from a plurality of received request signals.

The state information receiving section 12 receives state information representing the state of the actuator 4 from the control section 3 . The state information is information indicating whether the actuator 4 is normal or out of order, and is obtained or generated by the controller 3 that controls the actuator 4 . If the actuator 4 has failed, the status information includes information indicating the failure mode of the actuator 4, ie, what failure state the actuator 4 is in. If the state information includes the failure mode of the actuator 4, the application execution unit 5 that has received the state information can distinguish between a drive request that can be issued to the actuator 4 in the failure state and a drive request that cannot be issued. .

The state information output unit 13 feeds back the state of the actuator 4 by outputting the state information received by the state information reception unit 12 to the application execution unit 5 .

FIG. 3 is a functional block diagram of a control unit shown in FIG. 1;

Each control unit 3 includes a detection unit 19 , a state acquisition unit 20 , a first transmission unit 21 and a second transmission unit 22 .

The detection unit 19 detects whether the request arbitration unit 1 is abnormal. The method of determining abnormality of the request arbitration unit 1 by the detection unit 19 is not particularly limited. Alternatively, the abnormality may be determined based on the fact that the request signal or the response signal from the request arbitration unit 1 cannot be detected for a predetermined time, or the abnormality may be determined based on the fact that the drive request received from the request generation unit 2 is not normal. can be judged.

The state acquisition unit 20 detects the state of the actuator 4 and generates state information representing the state of the actuator 4 . For example, the state acquisition unit 20 detects the actuator 4 based on a response signal output from the actuator 4 in response to a drive signal output to the actuator 4, outputs from sensors provided in or near the actuator 4, and the like. 4 is normal or not, and if it is determined that the actuator 4 is out of order, what kind of failure state (failure mode) is specified. The state acquisition unit 20 generates state information including the determination result of the state of the actuator 4 and the specified failure mode.

The first transmission unit 21 transmits the state information generated by the state acquisition unit 20 to the request arbitration unit 1 . The state information transmitted to the request arbitration unit 1 by the first transmission unit 21 is output from the state information output unit of the request arbitration unit 1 to the application execution unit 5 . A route for transmitting the state information from the first transmission unit 21 to the application execution unit 5 via the request arbitration unit 1 corresponds to the above-described first feedback route.

The second transmission unit 22 is generated by the state acquisition unit 20 when the detection unit 19 determines that the request arbitration unit 1 is abnormal or determines that the actuator 4 is in a specific failure state. The received status information is sent to the application execution unit 5 without going through the request arbitration unit 1 . Here, the specific failure state of the actuator 4 refers to a state in which a failure has occurred to the extent that it is necessary to quickly transition the vehicle to a safe state. The path through which the state information is transmitted from the second transmission section 22 to the application execution section 5 without going through the request arbitration section 1 corresponds to the above-described second feedback path.

<Control processing>
FIG. 4 is a flow chart showing control processing executed by the control unit shown in FIG. The control process of FIG. 4 is started when the start switch of the vehicle is turned on, and is repeatedly executed until the operation of the vehicle is turned off.

Step S1: The detection unit 19 determines whether the request arbitration unit 1 is abnormal. If the determination in step S1 is YES, the process proceeds to step S4; otherwise, the process proceeds to step S2.

Step S2: The state acquisition unit 20 determines whether or not the actuator 4 is out of order. If the determination in step S2 is YES, the process proceeds to step S3; otherwise, the process proceeds to step S5.

Step S3: The state acquisition unit 20 determines whether the actuator 4 is in a specific failure state. If the determination in step S3 is YES, the process proceeds to step S4; otherwise, the process proceeds to step S5.

Step S<b>4 : The second transmission section 22 directly transmits the state information of the actuator 4 to the application execution section 5 . After that, the process proceeds to step S1.

Step S5: The first transmission unit 21 transmits the state information of the actuator 4 to the request arbitration unit 1. FIG. After that, the process proceeds to step S1. In the request arbitration unit 1 , when the state information reception unit 12 receives the state information transmitted from the first transmission unit 21 , the state information output unit 13 outputs the received state information to the application execution unit 5 .

<Effects, etc.>
In the vehicle control device 10 according to the present embodiment, a request arbitration unit 1 is provided between a plurality of application execution units 5 that operate each actuator 4 in order to realize a driving support function, and the control unit 3 of the actuator 4. is provided. The request arbitration unit 1 has a function of relaying signal transmission/reception between the application execution unit 5 and the control unit 3 and arbitrating requests from a plurality of application execution units 5 . By providing the request arbitration unit 1, even when the number of the application execution units 5 that realize the driving support function increases, control interference with the actuators 4 is prevented, and the signal paths between the application execution units 5 and the actuators 4 are reduced. Complication can be suppressed.

However, in a configuration in which all signals are transmitted and received between the application execution unit 5 and the actuator 4 via the request arbitration unit 1, if an abnormality such as a failure occurs in the request arbitration unit 1, the state information of the actuator 4 cannot be fed back to the application execution unit 5, and controllability may deteriorate. In addition, when a failure occurs in the actuator 4 to the extent that it is necessary to shift the vehicle to a safe state, the application executes the state information of the actuator 4 without delay so that the vehicle can be quickly controlled to a safe state. It is preferable to be able to transmit to the part 5 . In order to solve these technical problems, it is conceivable to always send the state information of the actuators 4 directly to the application execution unit 5. A problem arises that the load on the structure is increased.

In the vehicle control device 10 according to the present embodiment, the state information of the actuator 4 is normally transmitted from the first transmission section 21 to the application execution section 5 via the request arbitration section 1 . However, if it is determined that the request arbitration unit 1 is abnormal, or if it is determined that the actuator 4 is in a specific failure state, the second transmission unit 22 , the state information is directly transmitted from the actuator 4 to the application execution unit 5 . By configuring in this way, even when an abnormality occurs in the request arbitration unit 1, the state information of the actuator 4 can be reliably fed back to the application execution unit 5. FIG. In addition, when the actuator 4 is in a specific failure state to some extent that it is necessary to quickly transition to a safe state, the state information of the actuator 4 can be sent directly to the application execution unit 5 without going through the request arbitration unit 1. delay in signaling can thus be avoided. Further, direct feedback of state information from the actuator 4 to the application execution unit 5 is limited to specific conditions, so an increase in the load on the communication infrastructure can be minimized.

(Other modifications)
In the above embodiment, when the actuator 4 is detected to be in a specific failure state, the second transmission unit 22 directly feeds back the state information to the application execution unit 5. If the unit 1 is not abnormal, the first transmission unit 21 may feed back the status information to the application execution unit 5 via the request arbitration unit 1, as in normal times. However, as in the above embodiment, even when it is detected that the actuator 4 is in a specific failure state, it is better for the second transmission unit 22 to directly feed back the state information to the application execution unit 5. This is preferable because the delay in information transmission can be further suppressed.

INDUSTRIAL APPLICABILITY The present invention can be used as a vehicle control device for controlling a vehicle equipped with a driving support function.

1 request arbitration unit 2 request generation unit 3 control unit 4 actuator 5 application execution unit 10 vehicle control device 11 arbitration processing unit 12 state information reception unit 13 state information output unit 19 detection unit 20 state acquisition unit 21 first transmission unit 22 2 transmitter

Claims (4)

A control device mounted on a vehicle,
a request arbitration unit that receives a plurality of request signals from a plurality of driving support applications and arbitrates requests from the plurality of driving support applications;
a request generation unit that generates a drive request for the actuator based on the result of mediation by the request mediation unit;
The request arbitration unit outputs the state information of the actuators to the plurality of driving support applications when the request arbitration unit is not abnormal, and when the request arbitration unit is abnormal, the request arbitration unit is abnormal. A control device that outputs information indicating something to a control unit that controls an actuator. A system comprising a control device mounted on a vehicle and a control unit for controlling an actuator of the vehicle,
The control device is
a request arbitration unit that receives a plurality of request signals from a plurality of driving support applications and mediates requests from the plurality of driving support applications;
a request generation unit that generates a drive request for the actuator based on the arbitration result of the request arbitration unit;
The request arbitration unit outputs the state information of the actuators to the plurality of driving support applications when the request arbitration unit is not abnormal, and when the request arbitration unit is abnormal, the request arbitration unit is abnormal. A system that outputs information indicating something to a controller that controls an actuator. A control method executed by an electronic control unit mounted on a vehicle,
receiving a plurality of request signals from a plurality of driving assistance applications and arbitrating requests from the plurality of driving assistance applications;
generating a drive request for the actuator based on the arbitration result;
outputting state information of the actuator to the plurality of driving assistance applications when the electronic control unit is not abnormal;
and outputting information indicating that the electronic control unit is abnormal to a control unit that controls an actuator when the electronic control unit is abnormal. A vehicle comprising the control device according to claim 1 .

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