JP2021018162A - Failure detection system - Google Patents

Abstract

To provide a technology that suppresses inappropriate passing of an OBD automobile inspection.SOLUTION: A failure detection system 1 comprises: an electronic control device 50; and an external device 20. The external device comprises an external update unit 72. The external update unit is configured to generate synchronization information having both of an acquired failure item and a history failure item as a diagnostic item representing failure, and to store the synchronization information in an external storage device 27 as new history information. The acquired failure item is a diagnostic item of specific failure information included in transmission information acquired by the external acquiring unit 72, the diagnostic item representing the failure. The history failure item is a diagnostic item of history information stored in the external storage device before the transmission information is acquired by the external acquiring unit, the diagnostic item representing the failure.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to a technique for detecting a failure in a vehicle.

For example, Patent Document 1 describes an electronic control device (hereinafter referred to as an ECU) mounted on a vehicle having a failure diagnosis function. ECU is an abbreviation for Electronic Control Unit. The failure diagnosis function of the ECU is also called OBD. OBD is an abbreviation for On Board Diagnostics.

Japanese Unexamined Patent Publication No. 2006-113668

In Patent Document 1, the failure type code detected by the ECU is read out by an inspection tool which is an external device connected to the vehicle network. The maintenance staff confirms the failure type code displayed on the inspection tool and recognizes the failure location. The failure type code is generally called DTC. DTC is an abbreviation for Diagnostic Trouble Code.

In recent years, the implementation of vehicle inspections utilizing OBD (hereinafter referred to as OBD vehicle inspections) has been studied. In the OBD vehicle inspection, one or more specific DTCs among the DTCs related to a plurality of types of failures that can be detected in the vehicle are defined as specific DTCs. For example, if the specific DTC is recorded in the ECU mounted on the vehicle and the specific DTC is read from the ECU at the time of performing the OBD vehicle inspection, the vehicle is rejected from the OBD vehicle inspection.

However, if the specific DTC recorded in the ECU is improperly erased before the OBD vehicle inspection is carried out, the OBD vehicle inspection is performed based on the recorded contents after the deletion, and it is improperly assumed that no failure has been detected. There is a risk of passing the vehicle inspection.

Therefore, one aspect of the present disclosure provides a technique for suppressing improperly passing the OBD vehicle inspection.

One aspect of the present disclosure is a failure detection system (1) including at least an electronic control device (50) mounted on the vehicle and an external device (20) installed outside the vehicle to communicate with the electronic control device. is there. The electronic control device includes a storage execution unit (61) and a transmission execution unit (65, S260). The storage execution unit repeatedly acquires specific failure information representing the diagnosis result for at least one predetermined diagnosis item for diagnosing the state of the vehicle, and stores the specific failure information in the vehicle storage device. The transmission execution unit is configured to transmit transmission information including specific failure information stored by the storage execution unit to an external device. The external device includes an external acquisition unit (72, S400) and an external history unit (72, S410-S510). The external acquisition unit is configured to repeatedly acquire transmission information. The external history unit is configured to store specific failure information included in the transmission information acquired by the external acquisition unit as history information in the external storage device, and includes an external update unit (72, S440-S510). The external update unit is configured to generate synchronization information in which both the acquired failure item and the history failure item are diagnostic items indicating the failure, and store the synchronization information in the external storage device as new history information. .. The acquired failure item is a diagnostic item of specific failure information included in the transmission information acquired by the external acquisition unit, and is a diagnostic item indicating a failure. The history failure item is a diagnostic item of history information stored in the external storage device before the transmission information is acquired by the external acquisition unit, and is a diagnostic item indicating a failure.

In general, communication may be interrupted between the electronic control device and the external device. During the communication blackout, the external device cannot acquire the specific failure information from the electronic control device. For example, if the specific failure information is improperly erased by the electronic control device when the communication interruption occurs, the vehicle inspection is performed based on the specific failure information transmitted from the electronic control device after the communication interruption is resolved. If done, there is a risk of improperly passing the vehicle inspection.

In the above-mentioned failure detection system, the external device generates synchronization information in which both the acquired failure item and the history failure item are used as diagnostic items indicating the failure, and stores the synchronization information as new history information. That is, the synchronization information includes both a diagnostic item representing a failure before the specific failure information is acquired and a diagnostic item representing a failure after the specific failure information is acquired as a diagnostic item representing the failure.

As a result, even if a communication blackout occurs and the specific failure information is improperly erased by the electronic control device during the communication blackout, the vehicle inspection can be improperly passed by using the synchronization information. Can be suppressed.

A block diagram showing a configuration of a communication system, an in-vehicle device, a server, and a tool. Explanatory drawing explaining the function of the ECU. Explanatory drawing explaining the function of a server control part. Flowchart of tool deletion history processing. Flowchart of battery removal history processing. Flowchart of diagnostic transmission process. Flowchart of interruption resolution processing. Flowchart of history update process. Explanatory drawing explaining operation of an Example. Explanatory drawing explaining the transition of history information.

[Embodiment]
[1. Constitution]
The communication system 1 shown in FIG. 1 includes an in-vehicle device 11 mounted on the vehicle and a server 12 installed outside the vehicle. The communication system 1 may include an inspection tool (hereinafter, tool) 13 which is an external device of the vehicle. In this embodiment, an example in which the communication system 1 includes the tool 13 will be described.

(1) In-vehicle device The in-vehicle device 11 includes at least one electronic control device (hereinafter, ECU) 50. Further, the in-vehicle device 11 includes a vehicle communication unit 56.

ECU is an abbreviation for "Electronic Control Unit". Although one ECU 50 is shown in FIG. 1, the communication system 1 may include a plurality of ECUs 50. In this case, the plurality of ECUs 50 may be communicably connected to each other by the communication line 15 in the vehicle. For example, these ECUs 50 may perform communication according to a communication protocol such as CAN. The communication protocol may be a communication protocol other than CAN. CAN is an abbreviation for Controller Area Network and is a registered trademark.

The ECU 50 includes a microcomputer 51. The microcomputer 51 includes a CPU 52, a ROM 53, a RAM 54, and another memory 55. The CPU 52 executes the program. The ROM 53 stores a program executed by the CPU 52, data referred to when the program is executed, and the like. The RAM 54 temporarily stores the data.

The other memory 55 is at least one memory that can hold data even when the operation of the ECU 50 is stopped and can write and read data. At least predetermined data (that is, specific DTC described later) is stored in the other memory 55.

As shown in FIG. 2, the ECU 50 has a diagnosis unit 61, a monitoring unit 62, an erasure execution unit 63, an erasure history unit 64, and a diagnosis transmission as a configuration of a function realized by the CPU 52 executing a program. A unit 65 and a synchronization unit 66 are provided.

The vehicle communication unit 56 is a device that communicates with the server 12. Although the vehicle communication unit 56 is configured to perform wireless communication in FIG. 1, it may be configured to perform wired communication.
The tool 13 is detachably connected to the communication line 15 via a connector 16 provided on the communication line 15.

(2) The server server 12 includes a server control unit 20, a server communication unit 26, and a server storage device 27. The server control unit 20 includes a microcomputer 21. The microcomputer 21 includes a CPU 22 for executing a program and a memory 23. The memory 23 includes a program executed by the CPU 22, a ROM in which data referred to when the program is executed, and the like are stored, a RAM for temporarily storing the data, and the like.

As shown in FIG. 3, the server control unit 20 includes a confirmation unit 71 and a history update unit 72 as a configuration of functions realized by the CPU 22 executing a program. The server 12 may include a server-side inspection unit 73.

The server communication unit 26 is a communication device capable of communicating with at least the ECU 50. In the present embodiment, the server communication unit 26 performs wireless communication with the vehicle communication unit 56 included in the ECU 50. However, the server communication unit 26 may be configured to perform wired communication with the ECU 50.

The server storage device 27 is a storage device for at least storing predetermined data (that is, a specific specific DTC or the like described later) transmitted from the ECU 50.
(3) Tool Tool 13 is not shown, but includes a tool control unit including a microcomputer, an operation unit operated by a maintenance staff, and a tool communication unit that communicates with the ECU 50. The microcomputer includes a CPU, a memory, and the like.

The tool 13 realizes at least an erasing function when the CPU of the tool control unit executes a program. The erasing function is a function for erasing at least the specific DTC in the other memory 55 of the ECU 50. When the erasing instruction is input by the maintenance staff via the operation unit, the tool 13 transmits the erasing instruction to the ECU 50 via the tool communication unit. The erasure instruction is an instruction for erasing the specific failure information (that is, the specific DTC) stored in the other memory 55 of the ECU 50.

[2. processing]
[2-1. Processing in in-vehicle devices]
(1) Diagnostic unit The diagnostic unit 61 performs a diagnostic function. The diagnostic function includes a function of executing a diagnosis for at least one predetermined diagnostic item. The specific failure information referred to below is information representing a diagnosis result for a diagnosis item. The diagnostic function includes a function of repeatedly acquiring specific failure information and storing the specific failure information in another memory 55. The diagnosis referred to here is to determine whether or not a specific failure has occurred. A specific failure is a failure in which a vehicle fails a predetermined safety standard (that is, a failure that fails an OBD vehicle inspection). The diagnostic item is an item for the above-mentioned specific failure, and is an item for diagnosing the state of the vehicle.

In the present embodiment, when it is determined by the diagnosis that a specific failure has occurred, the diagnosis unit 61 stores the specific DTC corresponding to the diagnostic item in which the specific failure has occurred in another memory 55 as specific failure information. Further, when the diagnosis unit 61 determines that the specific failure has not occurred by the diagnosis, the diagnosis unit 61 does not store the specific DTC corresponding to the diagnosis item in the other memory 55. The specific DTC is a predetermined failure code associated with each diagnostic item. The specific DTC represents the type of diagnostic item, that is, the type of specific failure.

For example, when storing the specific DTC, the diagnosis unit 61 may store the specific DTC table for expressing the diagnosis result for the diagnosis item in the memory 55, as shown in FIG. 10 described later. For example, either one of the stored information and the non-stored information may be stored in a predetermined storage area corresponding to each specific DTC. The stored information is information indicating that the specific DTC has occurred, and the non-memory information is information indicating that the specific DTC has not occurred. The stored information and the non-stored information may be, for example, a flag whose bit value is represented by 0 or 1.

Each time a specific failure is detected by the diagnostic process, the diagnosis unit 61 overwrites the stored information and the detection time information about the corresponding specific DTC in the corresponding storage area. As a result, the latest detection result for each specific DTC is stored in the specific DTC table. In FIG. 10, the identification of a plurality of specific DTCs such as the first specific DTCd1-the nth specific DTCdn corresponding to a plurality of (that is, n) diagnostic items such as the first diagnostic item-the nth diagnostic item. An example of a DTC table is shown. However, the mode for storing the specific DTC is not limited to the specific DTC table, and may be various modes.

The ECU 50 may be provided with a function of detecting in advance a time (hereinafter, detection time) when it is determined that a specific failure corresponding to the specific DTC has occurred. The detection time is represented by, for example, a combination of a date and an absolute time. The diagnosis unit 61 may store the specific DTC in the memory 55 in association with the information indicating the detection time when it is determined that the specific failure corresponding to the specific DTC has occurred (hereinafter, the detection time information). ..

(2) Monitoring unit The monitoring unit 62 implements a communication monitoring function. The communication monitoring function is a function for confirming that the in-vehicle device 11 and the server 12 can communicate with each other. For example, the monitoring unit 62 transmits a predetermined inquiry signal to the server 12 at a predetermined cycle via the vehicle communication unit 56. Here, when the monitoring unit 62 receives a predetermined response signal corresponding to the inquiry signal from the server 12, the monitoring unit 62 determines that the in-vehicle device 11 and the server 12 can communicate with each other. On the other hand, the monitoring unit 62 determines that the communication between the in-vehicle device 11 and the server 12 is interrupted when the response signal corresponding to the inquiry signal is not received from the server 12 within a predetermined period. The monitoring unit 62 stores the determination result in another memory 55.

(3) Erasing execution unit The erasing execution unit 63 performs an erasing function. The erasing function is a function of erasing a specific DTC stored in another memory 55 according to an erasing instruction from the tool 13. When the erasing execution unit 63 receives the erasing instruction via the vehicle communication unit 56, the erasing execution unit 63 erases the specific DTC stored in the other memory 55. Then, the specific DTC erasure flag is set. The specific DTC erasure flag is a flag that is set when an erasure instruction is received. In other words, the specific DTC erasure flag is a flag that is set when the specific DTC is erased according to the erasure instruction. The specific DTC erase flag may be stored in the RAM 54, for example.

(4) Erase history unit The erase history unit 64 implements a history storage function. The history storage function is a function of determining whether or not the specific DTC stored in the other memory 55 has been erased and storing the erased information in the other memory 55. The erasure information is information indicating that the specific failure information has been erased.

The erasure history unit 64 executes the history storage function by executing the tool erasure history process and the battery removal history process.
The tool erasure history process executed by the erasure history unit 64 will be described with reference to the flowchart shown in FIG. The specific DTC stored in the other memory 55 can be erased by the erase instruction from the tool 13. The tool erasure history process is repeatedly executed at a predetermined cycle.

In S10, the erasure history unit 64 determines whether or not the specific DTC has been erased by the tool 13. When the specific DTC erasure flag is set, the ECU 50 determines that the specific DTC has been erased by the tool 13. Here, the erasure history unit 64 shifts the process to S20 when it is determined by the tool 13 that the specific DTC has been erased. On the other hand, the erase history unit 64 ends the tool erase history process when the specific DTC erase flag is set and the tool 13 determines that the specific DTC has not been erased.

In S20, the erasure history unit 64 determines whether or not the in-vehicle device 11 and the server 12 can communicate with each other. Here, the erasure history unit 64 ends the tool erasure history process when the determination result by the monitoring unit 62 indicates that communication is possible. On the other hand, the erasure history unit 64 shifts the process to S30 when the determination result by the monitoring unit 62 indicates that the communication is interrupted.

In S30, the erasure history unit 64 stores the tool erasure history as erasure information in another memory 55, and ends the tool erasure history process. The tool erasure history is information indicating that the specific DTC has been erased by the tool 13. The tool erasure history may be represented by a binary value such as 1 or 0. The tool erasure history may be reset by a diagnostic transmission process executed by the diagnostic transmission unit 65, which will be described later.

The battery removal history process executed by the erase history unit 64 will be described with reference to the flowchart shown in FIG. The specific DTC stored in the other memory 55 can be erased by removing the battery 57 (not shown) mounted on the vehicle. The battery 57 referred to here supplies power to at least the microcomputer 51. The battery removal history processing is repeatedly executed at a predetermined cycle.

In S110, the erasure history unit 64 determines whether or not the battery 57 has been removed. The ECU 50 may be configured so that the removal flag is set by the microcomputer 51 when the battery 57 is removed. The removal flag may be stored in the RAM 54, for example. The erasure history unit 64 may determine that the battery 57 has been removed when the removal flag is set.

Here, the erasure history unit 64 shifts the process to S120 when it is determined that the battery 57 has been removed. On the other hand, when it is determined that the battery 57 has not been removed, the erase history unit 64 ends the battery removal history process.

In S120, the erasure history unit 64 determines whether or not the in-vehicle device 11 and the server 12 can communicate with each other. Here, the erasure history unit 64 ends the battery removal history process when the determination result by the monitoring unit 62 indicates that communication is possible. On the other hand, the erasure history unit 64 shifts the process to S130 when the determination result by the monitoring unit 62 indicates that the communication is interrupted.

In S130, the erasure history unit 64 stores the battery removal history as erasure information in another memory 55, and ends the battery removal history processing. The battery removal history is information indicating that the battery 57 has been removed. The battery removal history may be represented by a binary value such as 1 or 0. The battery removal history may be reset by a diagnostic transmission process executed by the diagnostic transmission unit 65, which will be described later.

(5) Diagnosis transmission unit The diagnosis transmission unit 65 implements the diagnosis transmission function. The diagnostic transmission function is a function of transmitting at least specific failure information to the server 12. The specific failure information referred to here refers to specific failure information stored in another memory 55. The diagnosis transmission unit 65 executes the diagnosis transmission function by executing the diagnosis transmission process.

The diagnostic transmission process executed by the diagnostic transmission unit 65 will be described with reference to the flowchart shown in FIG. The diagnosis transmission process is started every time the diagnosis unit 61 stores the specific failure information in the other memory 55. However, the present disclosure is not limited to this. The diagnostic transmission process may be executed at predetermined intervals.

The diagnosis transmission unit 65 acquires specific failure information in S200. That is, the specific DTC stored in the other memory 55 as the specific failure information is acquired.
In S210, the diagnosis transmission unit 65 acquires the determination result by the monitoring unit 62 and determines whether or not the in-vehicle device 11 and the server 12 can communicate with each other. Here, the diagnosis transmission unit 65 shifts the process to S230 when the determination result by the monitoring unit 62 can be communicated. On the other hand, the diagnosis transmission unit 65 shifts the process to S220 when the determination result by the monitoring unit 62 is not communicable, that is, when the communication is interrupted.

The diagnosis transmission unit 65 sets the communication blackout flag in S220. The communication blackout flag is a flag indicating that a communication blackout has occurred between the in-vehicle device 11 and the server 12. The communication blackout flag may be stored in the RAM 54, for example. Then, the diagnosis transmission unit 65 shifts the process to S210. That is, when the communication interruption occurs, the diagnosis transmission unit 65 sets the communication interruption flag and waits until the in-vehicle device 11 and the server 12 can communicate with each other.

In S230, the diagnosis transmission unit 65 determines whether or not the interruption has been resolved. The term "disruption resolution" refers to a state in which a communication blackout occurs between the in-vehicle device 11 and the server 12, and the communication blackout is resolved after the communication blackout occurs. Communication blackout means that communication is interrupted between the vehicle and the server 12. The diagnosis transmission unit 65 determines that the interruption has been resolved when the communication interruption flag is set. Here, the diagnosis transmission unit 65 shifts the process to S260 when it is determined that the interruption has been resolved. On the other hand, the diagnosis transmission unit 65 shifts the process to S240 when it is determined that the interruption has not been resolved. In other words, the fact that the disruption has not been resolved means that the communication blackout has not occurred.

The diagnosis transmission unit 65 acquires the detection time information in S240, and transmits the specific failure information (that is, the specific DTC) acquired in S200 and the detection time information to the server 12 via the vehicle communication unit 56. The process is transferred to S280.

In S260, the diagnosis transmission unit 65 executes the interruption resolution process described later. The disruption resolution process is a process for transmitting specific failure information to the server 12 when the disruption resolution state occurs. The diagnosis transmission unit 65 shifts the process to S270 after executing the interruption resolution process.

In S270, the diagnosis transmission unit 65 resets the communication interruption flag and shifts the process to S280.
In S280, the diagnosis transmission unit 65 resets the tool erasure history and the battery removal history, and ends the diagnosis transmission process.

Next, the interruption resolution process executed by the diagnosis transmission unit 65 in S260 of the diagnosis transmission process will be described with reference to the flowchart shown in FIG. 7.
In S310, the diagnosis transmission unit 65 determines whether or not the battery removal history is stored in another memory 55. That is, it is determined whether or not the battery 57 has been removed. Here, the diagnosis transmission unit 65 shifts the process to S320 when it is determined that the battery removal history is stored in another memory 55 and the battery 57 has been removed. On the other hand, the diagnosis transmission unit 65 shifts the process to S330 when it is determined that the battery removal history is not stored in the other memory 55 and the battery 57 is not removed.

In S320, the diagnosis transmission unit 65 acquires the detection time information, and stores the battery removal history, the specific failure information, and the detection time information as transmission information in, for example, the RAM 54. The transmission information is information transmitted to the server 12, and is information including at least specific failure information. Then, the diagnosis transmission unit 65 shifts the processing to S360.

In S330, the diagnosis transmission unit 65 determines whether or not the above-mentioned tool erasure history is stored in another memory 55. That is, it is determined whether or not the specific failure information has been deleted according to the deletion instruction from the tool 13. Here, the diagnosis transmission unit 65 shifts the process to S340 when the tool erasure history is stored in another memory 55 and it is determined that the specific failure information has been erased by the tool 13. On the other hand, the diagnosis transmission unit 65 shifts the process to S350 when it is determined that the tool erasure history is not stored in the other memory 55 and the specific failure information is not erased by the tool 13.

In S340, the diagnosis transmission unit 65 acquires the detection time information and stores the tool erasure history, the specific failure information, and the detection time information as transmission information in, for example, the RAM 54. Then, the diagnosis transmission unit 65 shifts the processing to S360.

In S350, the diagnosis transmission unit 65 stores specific failure information and detection time information as transmission information in, for example, RAM 54. Then, the diagnosis transmission unit 65 shifts the processing to S360.
In S360, the diagnosis transmission unit 65 transmits the above-mentioned transmission information to the server 12 via the vehicle communication unit 56. Then, the interruption resolution process is completed.

(6) Synchronization unit When the synchronization unit 66 receives new history information described later from the server 12, the synchronization unit 66 stores the new history information in another memory 55.

[2-2. Processing on the server]
(1) Confirmation unit When the confirmation unit 71 receives the inquiry signal transmitted from the vehicle-mounted device 11 via the server communication unit 26, the confirmation unit 71 transmits a response signal corresponding to the inquiry signal.

(2) History update unit The history update unit 72 implements the history update function. The history update function is a function of storing the specific failure information received from the in-vehicle device 11 in the server storage device 27. The history update unit 72 executes the history update function by executing the history update process.

The history update process executed by the history update unit 72 will be described with reference to the flowchart shown in FIG. The history update process is repeatedly started every time transmission information is received from the in-vehicle device 11 via the server communication unit 26.

The history update unit 72 acquires transmission information in S400.
In S410-S420, the history update unit 72 determines whether or not the erase information has been acquired from the in-vehicle device 11.

Specifically, the history update unit 72 determines in S410 whether or not the transmission information includes the battery removal history. The history update unit 72 shifts the process to S440 when the battery removal history is included, and shifts the process to S420 when the battery removal history is not included.
In S420, the history update unit 72 determines whether or not the transmission information includes the tool deletion history. The history update unit 72 shifts the process to S440 when the tool erase history is included, and shifts the process to S430 when the tool erase history is not included.

In S430, the history update unit 72 stores the specific failure information included in the transmission information acquired by S400 in the server storage device 27 as history information. The history information is information stored in the server storage device 27, and includes at least specific failure information transmitted from the ECU 50.
In the present embodiment, the specific DTC as the specific failure information and the detection time information are stored in the server storage device 27. For example, the history update unit 72 may store the above-mentioned specific DTC table in the server storage device 27 when storing the specific DTC. In this step, the history update unit 72 may overwrite the stored information and the detection time information of the specific DTC table with the corresponding storage area in the server storage device 27 each time the transmission information is received. ..

In S440-S510, the history update unit 72 generates synchronization information when it is determined that the erase information has been acquired, and stores the synchronization information in the server storage device 27 as new history information. The synchronization information referred to here is newly generated specific failure information in which both the acquired failure item and the history failure item are used as diagnostic items indicating the failure. Representing a failure means that a failure has occurred.

Here, the acquired failure item is a diagnostic item of specific failure information included in the transmission information acquired by S400, and refers to a diagnostic item representing a failure. The transmitted information includes specific failure information detected by the in-vehicle device 11. On the other hand, the history failure item is a diagnosis item of the history information already stored in the server storage device 27 before the specific failure information from the in-vehicle device 11 is acquired by S400, and is a diagnosis item indicating the failure. Say.

In the present embodiment, as described above, the in-vehicle device 11 transmits the transmission information when it is determined that at least the interruption has been resolved. At this time, the server 12 stores the transmission information transmitted from the in-vehicle device 11 as history information before the interruption is resolved.

That is, the acquired failure item referred to in the present embodiment is a diagnostic item of specific failure information included in the transmission information acquired by S400 when the interruption is resolved, and means a diagnostic item indicating a failure. Further, the history failure item is a diagnostic item of the history information already stored in the server storage device 27 before the transmission information is acquired by S400 when the interruption is resolved, and is a diagnostic item indicating the failure. means.

In S440, the history update unit 72 compares a diagnostic item representing a failure included in the acquired failure item with a diagnostic item representing a failure included in the history failure item, and detects a difference item. The difference item is a diagnostic item that differs between the diagnostic item representing the failure included in the acquired failure item and the diagnostic item representing the failure included in the historical failure item. That is, the difference item is included in either the acquired failure item or the history failure item. In the present embodiment, the history update unit 72 compares the specific DTC included in the acquired failure item with the specific DTC included in the history failure item, and detects a different specific DTC as a difference item.

The history update unit 72 specifies that the difference item is not included in any of the acquired failure item and the history failure item in S450-S470. Further, the history update unit 72 specifies whether the difference item is included in the acquired failure item or the history failure item.
Specifically, the history update unit 72 determines in S450 whether or not the difference item is included in the history failure item. The history update unit 72 shifts the process to S460 when the difference item is not included in the history failure item, and shifts the process to S470 when the difference item is included in the history failure item.

In S460, the history update unit 72 determines whether or not the difference item is included in the acquired failure item. The history update unit 72 shifts the process to S500 when the difference item is included in the acquisition failure item, and ends the history update process when the difference item is not included in the acquisition failure item.

The history update unit 72 determines whether or not the difference item is included in the acquisition failure item in S470, which is shifted when the difference item is included in the history failure item. The history update unit 72 shifts the process to S480 when the difference item is included in the acquired failure item, and shifts the process to S490 when the difference item is not included in the acquired failure item.

The history update unit 72 shifts to the case where the difference item is included in both the history failure item and the acquisition failure item. In S480, the history failure item and the difference item not included in the history failure item are set as a diagnostic item indicating a failure. The synchronization information included as is generated, and the process is transferred to S510. In this step, the history update unit 72 may generate synchronization information including the acquired failure item and the difference item not included in the acquired failure item as a diagnostic item indicating the failure.

The history update unit 72 generates synchronization information including the history failure item as a diagnostic item indicating the failure in S490, which shifts when the difference item is included in the history failure item and the difference item is not included in the acquisition failure item. , The process shifts to S510.

The history update unit 72 generates synchronization information including the acquired failure item as a diagnostic item indicating the failure in S500, which shifts when the difference item is not included in the history failure item and the difference item is included in the acquired failure item. The process is transferred to S510.

In S510, the history update unit 72 stores the synchronization information as new history information in the server storage device 27. The history update unit 72 may store the new history information and the detection time information included in the transmission information in the server storage device 27.

In the subsequent S520, the history update unit 72 transmits new history information to the in-vehicle device 11 (that is, the ECU 50) via the server communication unit 26. The history update unit 72 ends the history update process.

(3) Server-side inspection unit The server-side inspection unit 73 carries out an OBD vehicle inspection based on the history information. For example, the server-side inspection unit 73 may be configured to determine that the OBD vehicle inspection has failed when a diagnostic item indicating a failure is stored in the history information.

[2-4. Operation]
The communication system 1 configured as described above operates as shown in FIG. 9 before and after the communication blackout.

In the initial state, the ECU 50 and the server control unit 20 are in a communicable state.
In A1, the ECU 50 detects the specific DTC as the specific failure information and stores it in another memory 55. As a result, the specific DTC held in the vehicle is updated.

In A2, the ECU 50 transmits the specific DTC as the transmission information and the detection time information.
In A3, the server control unit 20 stores the specific DTC included in the received transmission information in the server storage device 27 as history information. The server control unit 20 may store the detection time information together with the specific DTC.

Here, it is assumed that the ECU 50 and the server control unit 20 cannot communicate with each other. That is, it is assumed that communication blackout has occurred.
In A4, the ECU 50 again detects the specific DTC as the specific failure information and stores it in another memory 55. As a result, the specific DTC held in the vehicle is updated. However, since communication is not possible, the ECU 50 cannot transmit the transmission information including the updated specific DTC to the server 12.

In A5, the specific DTC as the specific failure information is deleted. For example, the tool 13 may output an erase instruction, and the ECU 50 may erase the specific DTC stored in another memory 55 according to the erase instruction. Alternatively, the specific DTC stored in the other memory 55 may be erased by removing the battery 57 by the user.

Here, it is assumed that the ECU 50 and the server control unit 20 are in a state where communication is possible again. In other words, it is assumed that the interruption has been resolved.
In A6, since the interruption has been resolved, the ECU 50 transmits transmission information including the specific DTC, the detection time information, and the erasure information stored in the other memory 55.

In A7, the server control unit 20 compares the specific DTC information as the history information already stored in the server storage device 27 at the time of A3 with the specific DTC included in the transmission information received from the ECU 50 at the time of A6. And generate synchronization information. The server control unit 20 stores the synchronization information as new history information in the server storage device 27.

In A8, the server control unit 20 transmits new history information to the ECU 50. The ECU 50 stores new history information (that is, a specific DTC represented by synchronization information) transmitted from the server control unit 20 in another memory 55.

Next, in the communication system 1 that operates as described in A1-A8, the specific failure information stored in the other memory 55 by the ECU 50 in the vehicle and stored in the server storage device 27 by the server control unit 20 in the server 12. An example of the transition of the history information to be performed will be described.

As shown in FIG. 10, the specific failure information stored in the vehicle and the history information stored by the server control unit 20 in the server 12 are stored using the specific DTC table. n diagnostic items are predetermined, and n specific DTCs corresponding to each diagnostic item (that is, n specific DTCs from the first specific DTC d ₁ to the n specific DTC d _n ) are predetermined. There is. A "1" is stored in the corresponding storage area for the specific DTC corresponding to the diagnostic item in which the failure is detected, and a "0" is stored in the corresponding storage area for the specific DTC corresponding to the diagnostic item in which the failure is not detected. It will be remembered.

In A1 described above, it is assumed that "1" is stored in the storage area corresponding to the n-1th specific DTC in the specific DTC table in the vehicle. It is assumed that the erasure information is not stored.
In A2 described above, transmission information including the specific DTC table is transmitted. Erase information is not included in the transmitted information.

In the above-mentioned A3, since the transmission information does not include the erasure information, the specific DTC table included in the transmission information is stored in the server storage device 27 as new history information. As a result, the specific failure information (that is, the specific DTC table) stored in the vehicle and the history information (that is, the specific DTC table) stored in the server 12 match.

Here, since the acquired failure item and the history failure item are compared and no difference item is detected, in the above-mentioned A4, in the vehicle, a failure is detected for the diagnostic item corresponding to the first specific DTC, and the specific DTC table is updated. To.

In A5 described above, it is assumed that the vehicle has received an erasing instruction for erasing the n-1 specific DTC from the tool 13. As a result, in the vehicle, the specific DTC table is updated according to the deletion instruction. That is, in the specific DTC table, "0" is stored in the storage area corresponding to the n-1th specific DTC.

Since communication is not possible at the time points A4 and A5, the specific DTC table stored in the vehicle and the specific DTC table stored in the server 12 do not match.
In A6 described above, the transmission information including the specific DTC table is transmitted in the vehicle due to the cancellation of the interruption. The transmission information includes a tool erasure history as erasure information.

In the above-mentioned A7, since the transmission information includes the erasure information, the server 12 generates the synchronization information.
That is, in B1, the server control unit 20 compares the acquired failure item with the history failure item and identifies the difference item. Here, the diagnostic item corresponding to the first specific DTC corresponds to the acquired failure item. Further, the diagnostic item corresponding to the n-1 specific DTC corresponds to the history failure item. There are two differences, the diagnostic item corresponding to the first specific DTC and the diagnostic item corresponding to the n-1 specific DTC. That is, one difference item is included in both the acquired item and the history item.

In B2, the server control unit 20 determines that the difference item is included only in the history failure item, the difference item is included only in the acquisition failure item, and the difference item is included in both. Generate synchronization information for each. The server control unit 20 does not generate synchronization information if there are no differences.

In the example of FIG. 10, the difference item is included in both the acquisition item and the history item.
Here, for the diagnostic item in which "0" is stored in the history failure item and "1" is stored in the acquired failure item, the synchronization information is updated with the information of the acquired failure item. That is, for the diagnostic item corresponding to the first specific DTC, "1" is stored in the synchronization information.

On the other hand, for the diagnostic item in which "1" is stored in the historical failure item and "0" is stored in the acquired failure item, the synchronization information is updated with the information of the historical failure item. That is, "1" is stored in the synchronization information for the diagnostic item corresponding to the n-1 specific DTC.

In this way, a specific DTC table in which "1" is stored in both the diagnostic item corresponding to the first specific DTC and the diagnostic item corresponding to the n-1 specific DTC is generated as synchronization information. In other words, the diagnostic item included in the historical failure item (that is, the diagnostic item corresponding to the first specific DTC) and the difference item included only in the acquired failure item (that is, the diagnostic item corresponding to the n-1 specific DTC). ) Is generated as a diagnostic item indicating a failure.

That is, when the difference item is included in the acquired failure item, synchronization information including at least all the diagnostic items included in the acquired failure item as the diagnostic item representing the failure is generated. Moreover, when the difference item is included in the history failure item, synchronization information including at least all the diagnosis items included in the history failure item as the diagnosis item indicating the failure is generated.

In the above-mentioned A7, the synchronization information generated in this way is stored in the server storage device 27 as new history information.
In the above-mentioned A8, the synchronization information is transmitted from the server 12 to the vehicle, and the synchronization information is stored in the other memory 55 as new specific failure information in the vehicle. As a result, the specific DTC table stored in the vehicle and the specific DTC table stored in the server 12 match.

[3. effect]
According to the embodiment described in detail above, the following effects are obtained.
(3a) In the in-vehicle device 11, the ECU 50 stores the specific failure information in another memory 55 and transmits the specific failure information to the server 12. In the server 12 that communicates with the in-vehicle device 11, the server control unit 20 stores the specific failure information as history information in the server storage device 27. Here, the server control unit 20 generates synchronization information in which both the acquired failure item and the history failure item are diagnostic items indicating the failure, and stores the synchronization information in the server storage device 27 as new history information. To do.

In general, communication may be interrupted between the ECU 50 and the server control unit 20. During communication blackout, the server control unit 20 cannot acquire specific failure information from the ECU 50. For example, if the specific failure information is improperly erased by the ECU 50 when a communication blackout occurs, a vehicle inspection is performed based on the specific failure information transmitted from the ECU 50 after the communication blackout is resolved. There is a risk of improperly passing the inspection.

In the communication system 1, the server control unit 20 generates synchronization information in which both the acquired failure item and the history failure item are diagnostic items representing the failure, and stores the synchronization information as new history information. That is, the synchronization information includes both a diagnostic item representing a failure before the specific failure information is acquired and a diagnostic item representing a failure after the specific failure information is acquired as a diagnostic item representing the failure.

As a result, even if a communication blackout occurs and the specific failure information is improperly deleted by the ECU 50 during the communication blackout, it is inappropriate for vehicle inspection (that is, OBD vehicle inspection) by using the synchronization information. It is possible to suppress passing the test. Further, even if a communication blackout occurs and new specific failure information is generated by the ECU 50 during the communication blackout, it is possible to suppress improper passing of the OBD vehicle inspection by using the synchronization information. it can.

(3b) In S260, the ECU 50 may repeatedly transmit the transmission information every time the specific failure information is acquired. Further, in S260, the ECU 50 may transmit transmission information at least when it is determined that the interruption has been resolved. As a result, at least when a disruption resolution state occurs, a history failure item representing specific failure information detected in the vehicle before the communication interruption and an acquisition item representing the specific failure information detected in the vehicle after the interruption is resolved. Sync information is generated based on. As a result, the same effect as in (3a) can be obtained during communication blackout.

(3c) The ECU 50 may be configured such that the erasure history unit 64 stores the erasure information in another memory 55 in S30 or S130 when it is determined that the specific failure information has been erased. When it is determined that the erase information has been acquired, the server control unit 20 may generate synchronization information and store new specific failure information as new history information. As a result, even if the specific failure information is improperly erased by the in-vehicle device 11, it is possible to suppress improper passing of the OBD vehicle inspection by performing the OBD vehicle inspection using the synchronization information. ..

Further, when it is determined that the erase information has not been acquired, the server control unit 20 does not generate the synchronization information, but instead uses the specific failure information acquired in S400 as new history information in the server storage device 27. You may memorize it. As a result, the synchronization information is generated and stored as new history information only when the erase information is acquired, so that the load on the server control unit 20 can be reduced.

(3d) In S10, the ECU 50 may determine that the specific failure information has been erased when the erase instruction is received. As a result, synchronization information can be generated when the specific failure information is deleted by the deletion instruction. That is, synchronization information can be generated when there is a possibility that the specific failure information has been improperly deleted. Then, by carrying out the OBD vehicle inspection using the synchronization information, it is possible to suppress improper passing of the OBD vehicle inspection.

(3e) In S110, the ECU 50 may determine that the specific failure information has been erased when the power supply by the battery 57 is interrupted. As a result, synchronization information can be generated when the specific failure information is erased by removing the battery. That is, synchronization information can be generated when there is a possibility that the specific failure information has been improperly deleted. Then, by carrying out the OBD vehicle inspection using the synchronization information, it is possible to suppress improper passing of the OBD vehicle inspection.

(3f) The server control unit 20 may generate synchronization information based on the difference items. For example, in S480 and S490, when the difference item is included in the history failure item, the server control unit 20 may generate synchronization information including at least the diagnosis item included in the history failure item as the diagnosis item indicating the failure. Good. As a result, even if the specific failure information is improperly deleted in the vehicle during the communication interruption, the synchronization information reflects the specific failure information before the specific failure information is improperly deleted. As a result, the same effect as in (3c) can be obtained.

(3g) The server control unit 20 may generate synchronization information based on the difference items. For example, in S480 and S500, when the difference item is included in the acquired failure item, the server control unit 20 may generate synchronization information including at least the diagnostic item included in the acquired failure item as a diagnostic item representing the failure. Good. As a result, if the specific failure information is updated in the vehicle during the communication interruption, the updated specific failure information is reflected in the synchronization information. As a result, the OBD vehicle inspection can be properly performed.

(3h) In S510, the server control unit 20 may overwrite the synchronization information as new history information in the server storage device 27 and store it. As a result, the OBD vehicle inspection can be performed using the history information stored in the server storage device 27.

(3i) The server control unit 20 may transmit new history information to the ECU 50 in S520. The ECU 50 may overwrite and store the new history information as new specific failure information in the other memory 55.

As a result, the specific failure information stored in the vehicle and the history information (that is, synchronization information) stored in the server 12 match. That is, the same applies to the case where the OBD vehicle inspection is performed on the vehicle using the specific failure information and the case where the server 12 performs the OBD vehicle inspection using the history information (that is, synchronization information) by the server side inspection unit 73. Results can be obtained.

The communication system 1 in the above embodiment corresponds to the failure detection system, the ECU 50 corresponds to the electronic control device, the server control unit 20 corresponds to the external device, the other memory 55 corresponds to the vehicle storage device, and the server. The storage device 27 corresponds to an external storage device. The battery 57 corresponds to a power device.

Further, in the ECU 50, the diagnosis unit 61 corresponds to the storage execution unit, the diagnosis transmission unit 65 corresponds to the transmission execution unit and the cancellation determination unit, and the erasure history unit 64 corresponds to the erasure determination unit and the erasure storage unit. S10 and S110 correspond to the processing as the erasure determination unit, S230 corresponds to the processing as the elimination determination unit, and S260 corresponds to the processing as the transmission execution unit. Further, in the server control unit 20, the history update unit 72 corresponds to an external acquisition unit, an external history unit, an acquisition determination unit, an external update unit, a difference unit, and a generation unit.

S400 corresponds to the processing as the external acquisition unit, and S410-S510 corresponds to the processing as the external history unit. S410 and S420 correspond to the processing as the acquisition determination unit, S440-S510 corresponds to the processing as the external update unit, S440 and S450-S470 correspond to the processing as the difference part, and S480, S490 and S500 correspond to the processing. Corresponds to processing as a generator. In addition, the tool erasure history and the battery removal history correspond to the erasure information.

[4. Other embodiments]
Although the embodiments of the present disclosure have been described above, the present disclosure is not limited to the above-described embodiments, and can be implemented in various modifications.

(4a) In the above embodiment, the ECU 50 is configured to transmit transmission information including the corresponding specific DTC to the server 12 each time the diagnosis unit 61 detects a specific failure. However, the present invention is not limited to this. For example, the ECU 50 may be configured to collectively transmit the specific DTCs stored in the other memory 55 to the server 12 as transmission information for each predetermined cycle. As a result, the processing load of the ECU 50 and the communication frequency between the ECU 50 and the server 12 can be reduced.

(4b) In the above embodiment, the OBD diagnosis is performed by the server-side inspection unit 73 of the server 12, but the present disclosure is not limited to this. For example, the ECU 50 may be configured to perform OBD diagnosis based on specific failure information stored in another memory 55.

(4c) In the above embodiment, an example has been described in which the server control unit 20 generates synchronization information when the interruption is resolved and stores the synchronization information as new history information in the server storage device 27. Disclosure is not limited to this. For example, the server control unit 20 may be configured to generate synchronization information whenever it receives transmission information and store the synchronization information in the server storage device 27 as new history information. Further, when the server control unit 20 receives the transmission information, the synchronization information is generated only when the transmission information includes the erasure information, and the synchronization information is stored in the server storage device 27 as new history information. It may be configured.

(4d) The control unit (ie, ECU 50, server control unit 20) and its method described in the present disclosure are a processor and memory programmed to perform one or more functions embodied by a computer program. It may be realized by a dedicated computer provided by configuring. Alternatively, the control unit and method thereof described in the present disclosure may be realized by a dedicated computer provided by configuring a processor with one or more dedicated hardware logic circuits. Alternatively, the control unit and method thereof described in the present disclosure may be a combination of a processor and memory programmed to perform one or more functions and a processor composed of one or more hardware logic circuits. It may be realized by one or more dedicated computers configured. The computer program may also be stored on a computer-readable non-transitional tangible recording medium as an instruction executed by the computer. The method for realizing the functions of each part included in the control unit does not necessarily include software, and all the functions may be realized by using one or more hardware.

(4e) A plurality of functions possessed by one component in the above embodiment may be realized by a plurality of components, or one function possessed by one component may be realized by a plurality of components. .. Further, a plurality of functions possessed by the plurality of components may be realized by one component, or one function realized by the plurality of components may be realized by one component. Further, a part of the configuration of the above embodiment may be omitted. In addition, at least a part of the configuration of the above embodiment may be added or replaced with the configuration of the other above embodiment.

(4f) In addition to the above-mentioned communication system 1, in-vehicle device 11, server 12, ECU 50, and server control unit 20, a program for operating the ECU 50, a program for operating the server control unit 20, and these programs are recorded. The present disclosure can also be realized in various forms such as a non-transitional actual recording medium such as a semiconductor memory and a failure detection method.

1 communication system, 12 servers, 20 server controls, 27 server storage devices, 50 ECUs, 55 other memories.

Claims (8)

A failure detection system (1) including at least an electronic control device (50) mounted on a vehicle and an external device (20) installed outside the vehicle and communicating with the electronic control device.
The electronic control device is
A storage execution unit (61) that repeatedly acquires specific failure information representing a diagnosis result for at least one predetermined diagnosis item for diagnosing the state of the vehicle and stores the specific failure information in the vehicle storage device.
A transmission execution unit (65, S260) configured to transmit transmission information including the specific failure information stored by the storage execution unit to the external device.
With
The external device is
An external acquisition unit (72, S400) configured to repeatedly acquire the transmission information, and
An external history unit (72, S410-S510) configured to store the specific failure information included in the transmission information acquired by the external acquisition unit as history information in an external storage device.
With
The external history unit
The acquisition failure item, which is the diagnostic item of the specific failure information included in the transmission information acquired by the external acquisition unit and represents the failure, and the transmission information are acquired by the external acquisition unit. Synchronized information is generated in which both the diagnosis item of the history information previously stored in the external storage device and the history failure item which is the diagnosis item indicating the failure are used as the diagnosis item indicating the failure. , An external update unit (72, S440-S510) configured to store the synchronization information as new history information in the external storage device.
Fault detection system with. The failure detection system according to claim 1.
The electronic control device
A resolution determination unit (65, S230) configured to determine whether or not a communication blackout has occurred with the external device and the communication blackout has been resolved.
With more
The transmission execution unit transmits the transmission information at least when it is determined that the interruption has been resolved.
In the external device
The external update unit is the acquisition failure item of the specific failure information included in the transmission information acquired by the external acquisition unit when the interruption is resolved, and the history failure item. The failure is caused by both the history information and the history failure item stored in the external storage device before the transmission information is acquired by the external acquisition unit when the interruption is resolved. A failure detection system that generates synchronization information as a diagnostic item to be represented and stores the synchronization information as the new history information. The failure detection system according to claim 1 or 2.
The electronic control device is
An erasure determination unit (64, S10, S110) configured to determine whether or not the specific failure information stored in the vehicle storage device has been deleted.
An erasing storage unit (64) configured to store erasing information indicating that the specific failure information has been erased in the vehicle storage device when it is determined that the specific failure information has been erased.
With more
The transmission execution unit transmits the transmission information including the specific failure information and the erasure information.
In the external device
The external history unit
Acquisition determination unit (72, S410, S420) configured to determine whether or not the erasure information has been acquired from the electronic control device.
With more
The external update unit is a failure detection system that generates the synchronization information when it is determined that the erasure information has been acquired and stores the synchronization information as the new history information. The failure detection system according to claim 3.
In the electronic control device,
The erasure determination unit (64, S10) is a failure detection system that determines that the specific failure information has been erased when an erasure instruction for erasing the specific failure information is received. The failure detection system according to claim 3 or 4.
In the electronic control device,
The erasure determination unit (64, S110) is a failure detection system that determines that the specific failure information has been erased when at least the power supply by the power device that supplies power to the vehicle storage device is interrupted. The failure detection system according to any one of claims 1 to 5.
In the external device
The external update unit
The diagnostic item representing the failure included in the acquired failure item is compared with the diagnostic item representing the failure included in the historical failure item, and the difference item which is a different diagnostic item is detected. Differences (S440, S450-S470) and
A generation unit (S480, S490, S500) configured to generate the synchronization information based on the difference item, and
Fault detection system with. The failure detection system according to claim 6.
In the external device
When the difference item is included in the history failure item, the generation unit (S480, S490) generates the synchronization information including at least all the diagnosis items included in the history failure item as the diagnosis item indicating the failure. Failure detection system. The failure detection system according to claim 6 or 7.
In the external device
When the difference item is included in the acquired failure item, the generation unit (S480, S500) generates the synchronization information including at least all the diagnostic items included in the acquired failure item as the diagnostic item representing the failure. Failure detection system.

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