JP2021112056A - Remote driving system - Google Patents

Abstract

To provide a remote driving system to improve the system, for example to improve safety.SOLUTION: In this remote driving system, it is confirmed whether or not power is normally supplied from a first backup power supply device when permitting to start remote driving, and after, a preparation command for starting remote driving is output. In other words, before the preparation command for starting remote driving is output, it is determined whether or not the power is normally output from the first backup power supply device. As a result, the safety of remote traveling can be improved.SELECTED DRAWING: Figure 2

Description

The present invention relates to a remote traveling system for traveling an own vehicle, which is a vehicle, based on remote information.

Patent Document 1 describes a backup power supply device that supplies electric power to the brake actuator when the main power supply is abnormal, and a brake ECU that controls the brake actuator. The backup power supply device includes a capacitor, a charging circuit, and a microcomputer that controls the charging circuit and the like, and the charging state of the capacitor is controlled by the control of the charging circuit by the microcomputer. Further, the microcomputer and the brake ECU are connected via a signal line. The brake ECU forcibly operates the capacitor at set time by communication with the microcomputer via the signal line, acquires the output voltage of the capacitor, and determines whether the capacitor is normal or not based on the output voltage. Monitor. In this way, in the brake ECU, even if the main power supply is normal, it is possible to constantly monitor whether or not the capacitor is normal.

Japanese Unexamined Patent Publication No. 2005-014754

An object of the present invention is to improve the remote traveling system, for example, to improve safety.

In the remote traveling system according to the present invention, when the start of remote traveling is permitted, it is determined whether or not the power is normally supplied from the first backup power supply device, and the power is normally supplied. When it is determined that the vehicle is in, a preparation command for starting remote driving is output. In other words, before the preparation command for starting remote travel is output, it is determined whether or not the power is normally supplied from the first backup power supply device. As a result, the safety of remote driving can be improved.

For example, when the start of remote travel is permitted, the first control device outputs a power output command to the first backup power supply device. However, at the start of remote travel, the first control device does not play a role of detecting whether or not the power is normally supplied from the first backup power supply device. Further, although it is the second control device that outputs the preparation command, the first backup power supply device and the second control device are not connected by a signal line. Therefore, as described in Patent Document 1, is the second control device unable to directly operate the first backup power supply device, and is the power normally supplied from the first backup power supply device? It is not possible to detect whether or not.
On the other hand, the first backup power supply device and the second backup power supply device are connected via a power supply line, and the second backup power supply device and the second control device are connected via a signal line. Therefore, the output (for example, voltage) from the first backup power supply device is detected in the second backup power supply device, and it is determined in the second backup power supply device whether or not the output of the first backup power supply device is normal. The determination result is supplied to the second control device, or a voltage representing the output detected in the second backup power supply device is supplied to the second control device, and in the second control device, the first backup power supply device is supplied. It is possible to determine whether or not the voltage is a normal value. Then, in the second control device, the preparation command can be output when the power is normally supplied from the first backup power supply device. In this way, it is possible to confirm that the power is normally supplied from the first backup power supply device before the preparatory operation is performed, and it is possible to improve the safety of remote travel.
The state in which power is normally supplied from the first backup power supply device means that the power supply line connected to the first backup power supply device is not disconnected and that the first backup power supply device is in a normal state. Etc. are applicable.

It is a figure which conceptually shows the remote traveling system which concerns on one Example of this invention. The remote traveling system includes a vehicle power supply according to an embodiment of the present invention. It is a figure which shows the power-source device for a vehicle conceptually. It is a flowchart which shows the remote delivery program stored in the storage part of the remote travel ECU of the remote travel system. It is a flowchart which shows the 1st backup power supply device control program at the time of remote delivery stored in the storage part of the shift switching ECU of the remote traveling system. It is a flowchart which shows the 2nd backup power supply inspection program stored in the storage part of the brake ECU of the remote traveling system. It is a flowchart which shows the switching circuit control program stored in the storage part of the ECU of the 2nd backup power supply device.

Embodiment of the invention

Hereinafter, a remote traveling system including a vehicle power supply device according to the present embodiment will be described with reference to the drawings.

This remote travel system includes a remote travel ECU (electric control unit) 10, an information and communication terminal 12, a drive system 14, a steering system 16, a brake system 18, a shift switching system 20, and the like. In the remote traveling system, by operating the information communication terminal 12 by an operator (generally, the driver, but not limited to the driver. Hereinafter, in the present embodiment, the operator is the driver). , Even if the driver is not on the own vehicle (meaning a vehicle equipped with this remote traveling system), which is a vehicle, the own vehicle is controlled and automatically driven. For example, the own vehicle is warehousing (parking) or warehousing (parking) based on the information from the information communication terminal 12.

The remote traveling ECU 10 is mainly composed of a computer, and includes an execution unit, a storage unit, an input / output unit, and the like (not shown). A plurality (n) of digital cameras 24, sonar 26, etc. are connected to the input / output units, respectively, and the environment around the own vehicle is based on the images captured by these digital cameras 24, information from the sonar 26, and the like. Is acquired, image recognition is performed, the route of the own vehicle when remote travel is performed is acquired, and a travel plan is created. Then, a control command for the own vehicle is created based on the travel plan, and is output to the drive system 14, the steering system 16, the brake system 18, the shift switching system 20, and the like.

The information communication terminal 12 includes a communication device (not shown), a control device mainly composed of a computer, and the like, and communicates with the remote traveling ECU 10. Remote information such as remote warehousing instruction information, remote warehousing instruction information, and ID information (identification information) is supplied from the information and communication terminal 12 to the remote traveling ECU 10, and the remote traveling ECU 10 indicates the state of the own vehicle to the information and communication terminal 12. Information etc. is supplied.

The drive system 14 can drive the own vehicle and control the driving force and the like. In this embodiment, the drive actuator 14 act (drive source) including at least one of the electric motor and the engine and the drive actuator It includes a drive ECU 14c that controls 14 act. By controlling the drive actuator 14 act by the drive ECU 14c, the own vehicle can be driven without the driver operating the accelerator operating member or the like, and the traveling speed of the own vehicle can be controlled.

The steering system 16 can steer the steering wheels of the own vehicle and control the steering direction, steering force, and the like. In this embodiment, the steering actuator 16 act provided with an electric power steering device and the like. And the steering ECU 16c that controls the steering actuator 16act. By controlling the steering actuator 16 act, the steering wheel can be steered and the own vehicle can be turned without the driver operating the steering operating member.

The shift switching system 20 switches the shift position (D, R, P, etc.) of the drive transmission mechanism, switches between the shift lock and the shift lock release, and performs the shift switching actuator 20 act and the first control. Includes a shift switching ECU 20c as a device. By controlling the shift switching actuator 20 act, the shift position can be switched, the shift lock can be released, the shift lock can be set, and the like without the driver operating the shift operation member.

The shift lock means to prohibit the movement of the shift position. For example, when the brake operating member is not operated while the main switch (not shown) is ON, the brake operating member is moved from the P position or the N position to another position. Prohibiting movement.

The brake system 18 applies a braking force to the own vehicle and can control the braking force. The brake actuator 18act and the brake ECU 18c as a second control device for controlling the brake actuator 18act are included. The brake actuator 18act may be operated by hydraulic pressure or by electromagnetic driving force. By controlling the brake actuator 18 act, the own vehicle can be stopped without the driver operating the brake operating member.

The drive system 14, the steering system 16, the brake system 18, the shift switching system 20, and the like can be operated by the electric power supplied from the vehicle power supply device 40.
As shown in FIG. 2, the vehicle power supply device 40 includes a main power supply 42, a first backup power supply device 44, a second backup power supply device 46, and the like. The first backup power supply device 44 can supply electric power to the shift switching system 20 and the brake system 18 when the main power supply 42 is abnormal, and the second backup power supply device 46 can supply electric power to the brake system 18 when the main power supply 42 is abnormal. It can supply electric power. As described above, in this remote traveling system, even if the main power supply 42 is abnormal, the shift switching system 20 and the brake system 18 can be operated, and the vehicle can be stopped.

The main power supply 42 includes a main battery 50, a DC / DC converter 52, a 12V battery 54, and the like. Electric power is supplied to and stored in the main battery 50 based on the operation of the drive system 10. The voltage of the main battery 50 is stepped down by the DC / DC converter 52 and stored in the 12V battery 54. The 12V power of the 12V battery 54 is supplied to the drive system 14 and the like, and is also supplied to the first backup power supply device 44, the second backup power supply device 46, and the like.

Each of the first and second backup power supply devices 44 and 46 includes a capacitor. In order to prolong the life of a capacitor, it is usually discharged when the main switch is turned off, and after the main switch is switched on, charging by the electric power of the main power supply 42 is started. In this embodiment, the first backup power supply device 44 has a faster charging speed than the second backup power supply device 46.

The second backup power supply device 46 is provided between the main power supply 42 and the brake system 18, and has a plurality of capacitor cells (a plurality of capacitor cells are referred to as capacitors, and the capacitor cells are referred to as capacitors). In this embodiment, a plurality of capacitor cells may be referred to as capacitors below) 60, a charge circuit 62, a second power supply control unit 64, a first switching circuit 66, a second switching circuit 68, and the like. .. The capacitor 60 is connected to the first power supply line 72 that connects the main power supply 42 and the brake system 18 via the charge circuit 62. The first switching circuit 66 is provided at a portion on the brake system 18 side of the connection portion of the first power supply line 72 with the charge circuit 62. Further, the first backup power supply device 44 is connected to the second back-up power supply device 46 via a second power supply line 74 as a power supply line, and a second switching circuit 68 is provided in the second power supply line 74. Specifically, the second power supply line 74 is connected to a portion of the first power supply line 72 on the brake system 18 side of the first switching circuit 66.

The capacitor (plurality of capacitor cells) 60 stores electric power (charge) supplied from the main power supply 42, and the charge circuit 62 is a circuit for charging or discharging a plurality of capacitor cells 60. .. The first switching circuit 66 is a circuit that switches between a state in which the first power supply line 72 is communicated and a state in which the first power supply line 72 is cut off, and the second switching circuit 68 switches between a state in which the second power supply line 74 is communicated and a state in which the second power supply line 74 is cut off. It is a circuit.

The second power supply control unit 64 is mainly composed of a microcomputer, and is connected to the first switching circuit 66, the second switching circuit 68, the brake ECU 18c, and the charge circuit 62 via signal lines L1, L2, L3, and L4, respectively. Be connected. By controlling the first switching circuit 66 and the second switching circuit 68, the second power supply control unit 64 supplies power to the brake system 18 from the capacitor 60 of the second backup power supply device 46, and the first backup. It switches between a state in which power is supplied from the power supply device 44 and a state in which power is supplied from the main power supply 42. For example, when it is determined that the main power supply 42 is abnormal and the charge amount of the capacitor 60 acquired based on the voltage of the first power supply line 72 is insufficient, the first switching circuit 66, the first 2 By the control of the switching circuit 68, the power of the first backup power supply device 44 is switched to the state of being supplied to the brake system 18.

The first power supply line 72 is connected to the second power supply control unit 64 via the third power supply line 76, and the second power supply line 74 is connected via the fourth power supply line 78. The second power supply control unit 64 is connected to the capacitor 60 and the main power supply 42 via the first power supply line 72 and the third power supply line 76, and is connected to the second backup power supply via the second power supply line 74 and the fourth power supply line 78. It is connected to the device 46. The second power supply control unit 64 is operated by any one of the capacitor 60, the main power supply 42, and the second backup power supply device 46.
Further, the second power supply control unit 64 has a voltage detection unit 64v and detects the voltage V and the like of the second power supply line 74 connected via the fourth power supply line 78. When the voltage V of the second power supply line 74 is equal to or higher than the set pressure Vth, the second power supply line 74 is not disconnected, that is, the first backup power supply device 44 to the second backup power supply device 46 (brake system 18). It is determined that the power is normally supplied to the user.

The first backup power supply device 44 is provided between the main power supply 42, the shift switching system 20, and the second backup power supply device 46, and includes a capacitor 80. A detailed description of the structure of the first backup power supply device 44 will be omitted. In remote travel control, the first backup power supply device 44 supplies power to the shift switching system 20 when the main power supply 42 is abnormal, but when the charge amount of the second backup power supply device 46 is insufficient. Also supplies power to the brake system 18.
Since the first backup power supply device 44 has a faster charging speed than the second backup power supply device 46, for example, if the main power supply 42 becomes abnormal immediately after the start of remote driving, power is supplied to the brake system 18. May be done. The first backup power supply device 44 is connected to the shift switching ECU 20c via the signal line L5.

In the remote travel system configured as described above, when remote information including ID information, remote delivery command information, etc. is supplied from the information communication terminal 12 to the remote travel ECU 10, the ID information is stored in the remote travel ECU 10. Matching is done. When the IDs match, the main switch is switched to ON, and the drive ECU 14c, the steering ECU 16c, and the like are activated. Further, for example, when a predetermined remote travel start permission condition such as that the main power supply 42 is normal is satisfied, the remote travel start (delivery) permission flag (hereinafter, simply referred to as a flag) is turned ON. Information indicating that the flag is ON is supplied to the drive ECU 14c, the steering ECU 16c, the brake ECU 18c, the shift switching ECU 20c, and the like.

In response to the flag ON information, the shift switching ECU 20c outputs a "command to output electric power to the second backup power supply device 46" to the first backup power supply device 44 via the signal line L5. Further, the brake ECU 18c requests a determination result from the second power supply control unit 64 via the signal line L3. In response to the request for this determination result, the second power supply control unit 64 detects the voltage of the second power supply line 74 via the fourth power supply line 78, and determines whether or not the voltage V is higher than the set voltage Vth. The determination result is supplied to the brake ECU 18c via the signal line L3. In the brake ECU 18c, the determination result is that the voltage is higher than the set voltage Vth and the power is normally supplied from the first backup power supply device 44 to the second backup power supply device 46 (the second power supply line 74 is disconnected). A shift lock release command as a preparation command is output to the remote traveling ECU 10 to indicate that the state is not present). When the remote traveling ECU 10 receives the shift lock release command, the remote travel ECU 10 outputs the shift lock release command to the shift switching ECU 20c and starts the remote warehousing control.

The above execution will be described based on the flowchart.
In the remote traveling ECU 10c, the remote warehousing program shown in the flowchart of FIG. 3 is executed.
In step 1 (hereinafter abbreviated as S1; the same applies to other steps), whether or not the remote delivery instruction information transmitted from the information communication terminal 12 has been received (remote information includes remote delivery instruction information). Whether or not) is determined, and in S2, it is determined whether or not the remote delivery permission condition is satisfied. If at least one of the determinations of S1 and S1 is NO, the process is not executed after S3, but if the determination of S1 and S2 is YES, the flag is switched to ON in S3, and the flag ON information. Is sent. In S4, it is determined whether or not the shift lock release command has been received. If the determination is YES, the shift lock release command is output to the shift switching ECU 20c in S5 and S6, and the remote warehousing control is started. On the other hand, if the determination in S4 is NO, S5 and 6 are not executed. When the shift lock release prohibition command is received, the shift lock is not released and the remote issue control is not started.

In the shift switching ECU 20c, the first backup power supply device control program at the time of remote delivery shown in the flowchart of FIG. 4 is executed. In S11, it is determined whether or not the flag ON information has been received, and if the determination is NO, S12 is not executed. If the determination is YES, a power output command is output to the first backup power supply device 44 via the signal line L5 in S12. As a result, the first backup power supply device 44 outputs power via the second power supply line 74.

In the brake ECU 18c, the shift lock release command output program shown in the flowchart of FIG. 5 is executed.
In S21, it is determined whether or not the flag ON information has been received. If the determination is YES, the request for the determination result is output to the second power supply control unit 64 via the signal line L3 in S22, and the received determination result is "no disconnection in the second power supply line 74" in S23. Is determined. If the determination in S23 is YES, a shift lock release command is output to the remote travel ECU 10 in S24, but if the determination is NO, shift lock release prohibition information is output in S25.

In the second power supply control unit 64, the second power supply line disconnection determination program represented by the flowchart of FIG. 6 is executed.
In S31, it is determined whether or not the determination result request is received via the signal line L3. When the determination result request is received, the voltage V of the second power supply line 74 is detected in S32, and it is determined in S33 whether or not the voltage is higher than the set voltage Vth. If the determination is YES, it is determined in S34 that there is no disconnection in the second power supply line 74, and in S35, the determination result is output to the brake ECU 18c via the signal line L3. On the other hand, when the voltage V is equal to or lower than the set voltage Vth, it is determined in S36 that the second power supply line 74 has a disconnection, and in S35, the determination result is output to the brake ECU 18c.

As described above, in the present embodiment, the shift switching ECU 20c does not play a role of detecting the output voltage of the first backup power supply device 44 at the time of remote delivery. Further, the first backup power supply device 44, the brake ECU 18c, and the second backup power supply device 46 are not connected via a signal line. However, the output of the first backup power supply device 44 is detected in the second backup power supply device 46 via the power supply line, and the determination result is supplied to the brake ECU 18c via the signal line L3. Then, the brake ECU 18c is configured to output a shift lock release command when the determination result is no disconnection. As a result, it is possible to confirm the disconnection of the second power supply line before the shift lock release command is output without increasing the number of signal lines, and the safety can be improved.

When the driver is on board, the main switch is turned on, the shift position is switched (with the shift lock released) while the brake operating member is operated, and the vehicle starts. It is normal to be forced to. Therefore, even in remote driving, it is desirable to confirm whether or not the backup power supply device is normal before the shift lock is released.

In the above embodiment, the second power supply control unit 64 determines whether or not the second power supply line 74 is disconnected, and the determination result is supplied to the brake ECU 18c. However, the second power supply control unit It is also possible to supply the voltage value detected in 64 to the brake ECU 18c so that the brake ECU 18c can determine whether or not the second power supply line 74 is disconnected.
If the voltage detected by the second power supply control unit 64 is equal to or lower than the set voltage, it can be estimated that the first backup power supply device 44 is abnormal.

In addition to the above examples, the present invention can be carried out in various forms with various modifications and improvements based on the knowledge of those skilled in the art.

12: Information and communication terminal 10: Remote traveling ECU 18: Brake system 20: Shift switching system 40: Vehicle power supply 44: First backup power supply 46: Second backup power supply 74: Second power supply line L1 to 4: Signal Line 64: 2nd power supply control unit

Claimable invention

(1) Information A remote traveling system including a remote traveling control device that controls an own vehicle, which is a vehicle, to travel the own vehicle based on information from a mobile terminal.
The first control device that controls the first backup power supply device,
When the power is normally supplied from the first backup power supply device, the second control device that outputs a preparation command, which is a command to prepare for the start of the remote running, and the second control device.
A remote traveling system including a second power supply control unit provided in a second backup power supply device connected to the first backup power supply device via a power supply line and connected to the second control device via a signal line.
The "state in which power is normally supplied from the first backup power supply device" corresponds to the case where the first backup power supply device is normal, the case where the power line connected to the first backup power supply device is not disconnected, and the like.

(2) The remote travel control device outputs remote travel start permission information to the first control device and the second control device when a predetermined remote travel start permission condition is satisfied.
The first control device outputs a power output command to the first backup power supply device in response to the remote travel start permission information.
The second control device outputs request information to the second power supply control unit in response to the remote travel start permission information.
The second power supply control unit detects the voltage of the power supply line in response to the required information.
When the second control device acquires that the power is normally supplied from the first backup power supply device based on the information supplied from the second power supply control unit via the signal line. To output the preparation command,
It is determined whether or not one of the second power supply control unit and the second control device is in a state where power is normally supplied from the first backup power supply device based on the voltage of the power supply line. The remote driving system according to item (1), which includes a determination unit to be used.
Based on the detected voltage, the second power supply control unit determines whether or not the power is normally supplied from the first backup power supply device, and the determination result is transmitted to the second control device via the signal line. The voltage detected by the second power supply control unit is output to the second control device via the signal line, and the second control device normally outputs the voltage from the first backup power supply device based on the voltage. It may be determined whether or not the power is supplied.
In addition, the start of remote travel corresponds to remote warehousing, and the remote travel start permission information corresponds to remote warehousing permission information.

(3) The remote traveling system according to item (1) or (2), wherein the first backup power supply device and the second backup power supply device each include a capacitor.

(4) The first control device is a shift switching ECU that controls a shift switching actuator.
The second control device is a brake ECU that controls a brake actuator.
The second backup power supply device can supply electric power to the brake actuator when the main power supply is abnormal.
The first backup power supply device can supply electric power to at least one of the shift switching actuator and the brake actuator when the main power supply is abnormal.
The second control device outputs a shift lock release command to the remote travel control device as the preparation command.
Described in any one of items (1) to (3), wherein when the remote travel control device receives the shift lock release command, the shift lock release command is output to the shift switching ECU. Remote driving system.

(5) Information A vehicle power supply device provided in a remote travel system including a remote travel control device that controls the own vehicle, which is a vehicle, based on information from a mobile terminal to drive the own vehicle.
A first backup power supply device capable of supplying electric power to the first actuator and a second actuator different from the first actuator.
A first control device that controls the first actuator and also controls the first backup power supply device,
A second backup power supply device capable of supplying electric power to the second actuator and connected to the first backup power supply device via a power supply line.
It includes a second control device that controls the second actuator and is connected to a second power supply control unit provided in the second backup power supply device via a signal line.
The remote travel control device outputs remote travel start permission information to the first control device and the second control device when a predetermined remote travel start permission condition is satisfied.
The first control device outputs electric power by controlling the first backup power supply device according to the remote travel start permission information supplied from the remote travel control device.
The second control device outputs request information to the second power supply control unit in response to the remote travel start permission information.
The second power supply control unit detects the voltage of the power supply line in response to the required information.
When the second control device acquires that the power is normally supplied from the first backup power supply device based on the information supplied from the second power supply control unit via the signal line. Is to output a preparation command, which is a command to prepare for the start of the remote running.
It is determined whether or not one of the second power supply control unit and the second control device is in a state where power is normally supplied from the first backup power supply device based on the voltage of the power supply line. A power supply device for a vehicle including a judgment unit.

Claims (2)

Information A remote traveling system that controls the own vehicle, which is a vehicle, based on remote information, which is information from a mobile terminal, and causes the own vehicle to travel remotely.
The first control device that controls the first backup power supply device,
When the power is normally supplied from the first backup power supply device, the second control device that outputs a preparation command, which is a command to prepare for the start of the remote running, and the second control device.
The second backup power supply device provided in the second backup power supply device connected to the first backup power supply device via a power supply line includes the second control device and a second power supply control unit connected via a signal line.
The first control device outputs a power output command to the first backup power supply device when the start of the remote traveling is permitted.
The second power supply control unit detects the voltage of the power supply line, and based on the detected voltage, determines whether or not power is normally supplied from the first backup power supply device. Including
When the determination result supplied by the second control device from the power supply control unit via the signal line is a result indicating that the power is normally supplied from the first backup power supply device. A remote driving system that outputs the preparation command. The remote travel system controls the own vehicle based on the remote information to remotely travel, and when a predetermined remote travel start permission condition is satisfied, it is assumed that the remote travel start is permitted and the remote is remote. The travel start permission information is output to the first control device and the second control device.
The second control device outputs the determination result request information for requesting the determination result to the second power supply control unit via the signal line based on the remote travel start permission information.
The remote traveling according to claim 1, wherein the second power supply control unit detects the voltage based on the determination result request information and outputs the determination result by the determination unit via the signal line. system.

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