JP2018132979A - Software update system, and server - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide update of on-vehicle equipment software by OTA (Over The Air) in radio easy to use by users.SOLUTION: A telematics center 100 includes an update software distribution unit 113 configured to distribute update software for updating ECU software to a software update device 210, and an update item management unit 112 configured to manage the update software distributed by the update software distribution unit 113 based on priority of the ECU software update. The software update device 210 includes a storage device 215 for storing the update software distributed from the telematics center 100, and an ECU software updating unit 214 configured to update the ECU software using the update software stored in the storage device 215.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a software update system and a server.

  In recent years, the scale of software installed in electronic control units (ECUs) for automobiles has increased due to advances in driving support functions and automatic driving technology. Along with this, the number of recalls caused by software defects in the ECU and the number of recalled vehicles are increasing. On the other hand, with the advancement of communication networks, connected cars in which cars are connected wirelessly to center systems and the like are also showing signs of widespread use.

  Under such circumstances, wireless remote software update technology (OTA: Over the Air), which has been used for mobile phones and televisions, is applied to automobiles, and software for in-vehicle devices such as ECUs is updated remotely. There is a growing need for remote software update technology for automobiles. Patent Document 1 discloses a system for remotely updating software of a telematics in-vehicle terminal as an example of an in-vehicle device.

JP2015-41334A

  In the system disclosed in Patent Literature 1, when there are a plurality of in-vehicle devices to be updated with software, appropriate software update management cannot be performed. Therefore, the software update of the in-vehicle device by OTA that is easy for the user to use cannot be realized.

A software update system according to the present invention includes a software update device mounted on a vehicle and a server that communicates with the software update device via a network, and manages software updates of a control device mounted on the vehicle. The server is based on an update software distribution unit that distributes update software for updating software of the control device to the software update device, and a priority for software update of the control device, An update item management unit that manages the update software distributed by the update software distribution unit, and the software update device stores a vehicle-side storage device that stores the update software distributed from the server , The update software stored in the vehicle-side storage device. Having a software updating unit for updating software of the control unit used.
A server according to the present invention manages software update of a control device mounted on a vehicle, and an update software distribution unit that distributes update software for updating the software of the control device to the vehicle; And an update item management unit that manages the update software distributed by the update software distribution unit based on the priority of the control device for software update.

  ADVANTAGE OF THE INVENTION According to this invention, the update of the software of the vehicle equipment by OTA which is easy to use for a user is realizable.

It is a figure which shows the structural example of the software update system which concerns on the 1st Embodiment of this invention. It is a figure which shows an example of the table showing the structure of the data stored in DB of a telematics center in the 1st Embodiment of this invention. It is a figure which shows an example of the table showing the structure of the data stored in DB of a telematics center in the 1st Embodiment of this invention. It is a figure which shows the flow of the download process of the software for update performed in the 1st Embodiment of this invention. It is a figure which shows the flow of the ECU software update process performed in the 1st Embodiment of this invention. It is a figure which shows the flow of the recovery process performed in the 1st Embodiment of this invention. It is a figure which shows the flow of the recovery process performed in the 1st Embodiment of this invention. It is a figure which shows an example of the screen displayed on the input / output device of a telematics center in the 1st Embodiment of this invention. It is a figure which shows an example of the screen displayed on the input / output device of the navigation terminal mounted in the vehicle in the 1st Embodiment of this invention. It is a figure which shows the flow of the ECU software update process performed in the 2nd Embodiment of this invention. It is a figure which shows the flow of the update item confirmation process performed in the 3rd Embodiment of this invention. It is a figure which shows an example of the screen displayed on the input / output device of a telematics center in the 3rd Embodiment of this invention.

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

(First embodiment)
FIG. 1 is a diagram showing a configuration example of a software update system according to the first embodiment of the present invention. The software update system shown in FIG. 1 manages software updates of various ECUs mounted on the vehicle 200, and includes a telematics center 100 that is a server and a software update device 210 mounted on the vehicle 200. The telematics center 100 and the software update device 210 are connected to each other via a communication unit 220 mounted on the network 300 and the vehicle 200. This connection enables communication between the telematics center 100 and the software update device 210. Examples of the network 300 include a short-range wireless communication such as a mobile phone network, an Internet network, and a wireless LAN (Local Area Network), or a combination of a plurality of these. In FIG. 1, only one vehicle 200 on which the software update device 210 is mounted is illustrated. However, the number of such vehicles 200 is not limited to one, and a plurality of vehicles 200 each include the software update device 210. It may be mounted and connected to the telematics center 100.

  The telematics center 100 distributes update software for updating software of various ECUs mounted on the vehicle 200 to the vehicle 200 via the network 300. The telematics center 100 includes a central processing unit 110, a storage device 120, an input / output device 130, and a communication unit 140.

  The central processing unit 110 includes, for example, a CPU (Central Processing Unit), a RAM (Random Access Memory), and the like, and executes a process for realizing the functions of the telematics center 100 by executing a predetermined operation program. The central processing unit 110 includes a configuration information management unit 111, an update item management unit 112, an update software distribution unit 113, and a recovery software distribution unit 114 as its functions.

  The configuration information management unit 111 manages each information of a vehicle configuration DB 121, a vehicle type configuration DB 122, and a function configuration DB 123, which will be described later, stored in the storage device 120, and registers, changes, and deletes each information as necessary. The update item management unit 112 manages an update item indicating the content of software update for each ECU of the vehicle 200. The update software distribution unit 113 distributes the update software to the vehicle 200 in response to a request from the vehicle 200. The recovery software distribution unit 114 distributes the recovery software for returning the software of the ECU to the state before the update to the vehicle 200 when any of the ECUs mounted on the vehicle 200 fails to update the software. . The operations of these components will be described in detail later.

  The storage device 120 includes, for example, an HDD (Hard Disk Drive), an SSD (Solid State Drive), a flash memory, a ROM (Read Only Memory), and the like. The storage device 120 stores a program executed by the central processing unit 110, a data group necessary for executing the program, and the like. The data group stored in the storage device 120 includes a vehicle configuration DB 121, a vehicle type configuration DB 122, a function configuration DB 123, an update item management DB 124, a progress management DB 125, and the like.

  The vehicle configuration DB 121 stores vehicle configuration information that is information for managing ECUs and software versions installed in each vehicle 200. The vehicle type configuration DB 122 stores vehicle type configuration information that is information for managing ECUs mounted on each vehicle 200 in units of vehicle types. The functional configuration DB 123 stores functional configuration information that is information for managing how each ECU affects the operation of the vehicle 200. The update item management DB 124 accumulates information for managing the software update item of the ECU. The update item management DB 124 stores not only software update item information but also update software for distribution to each vehicle 200. The update software is stored in the update item management DB 124 by being registered in advance via the input / output device 130 or the like. The progress management DB 125 accumulates information for managing in which vehicle the update has already been completed after actually starting the distribution of the update software to each vehicle 200.

  The input / output device 130 includes a combination of a touch panel, a keyboard, a mouse, and the like, and functions as an input unit and a display unit.

  The communication unit 140 includes a network card that conforms to a communication standard used in the network 300. The network card conforms to a communication standard required for wired communication such as a wired LAN (Local Area Network), wireless communication such as a wireless LAN, or both. The communication unit 140 transmits / receives data to / from the vehicle 200 based on various protocols via the network 300.

  The vehicle 200 includes a software update device 210, a communication unit 220, a navigation terminal 230, an engine ECU 240, an ABS ECU 241, a steering ECU 242, a suspension ECU 243, an airbag ECU 244, an automatic operation ECU 245, a keyless entry ECU 246, An air conditioner control ECU 247 and an audio ECU 248 are provided.

  Engine ECU 240 manages the engine operation of vehicle 200. The ABS ECU 241 manages the ABS (Antilock Break System) of the vehicle 200. The steering ECU 242 manages steering control of the vehicle 200. The suspension ECU 243 manages suspension control of the vehicle 200. The airbag ECU 244 manages the operation control of the airbag of the vehicle 200. The automatic driving ECU 245 manages operation control of the automatic driving of the vehicle 200. The keyless entry ECU 246 manages the control of the keyless entry of the vehicle 200. The air conditioner control ECU 247 controls the air conditioner of the vehicle 200. Audio ECU 248 controls the operation of audio equipment of vehicle 200. Each device is connected by an in-vehicle network such as a CAN (Controller Area Network). Further, as shown in FIG. 1, each of the ECUs is connected to a different bus-type CAN network depending on its function sharing. The software update device 210 has a hub function for these bus-type networks.

  Note that the ECU capable of updating software installed in the vehicle 200 is not limited to that shown in FIG. For example, an ECU having a function of supporting control and safety of the vehicle 200 such as an ECU for brake control and an ECU for electronic mirror control may be mounted on the vehicle 200 in addition to the ECUs shown in FIG. Each ECU has built-in software for operating itself. This software is stored in each storage device of each ECU.

  The software update device 210 includes a central processing unit 211 and a storage device 215.

  The central processing unit 211 includes, for example, a CPU and a RAM, and performs a process for realizing the function of the software update device 210 by executing a predetermined operation program. The central processing unit 211 includes an update item confirmation unit 212, an update software request unit 213, and an ECU software update unit 214 as its functions.

  The update case confirmation unit 212 inquires of the telematics center 100 whether there is a case that requires software update. When there is a software update item, the update software request unit 213 requests the telematics center as update data for update software and update execution requirements. The ECU software update unit 214 updates the ECU software based on the received software and update execution requirements, and transmits the execution result to the telematics center 100.

  The storage device 215 includes, for example, an HDD, an SSD, a flash memory, and a ROM, and stores a program executed by the central processing unit 211, a data group necessary for program execution, and the like. Furthermore, the storage device 215 also stores update software distributed from the telematics center 100, the above-described recovery software distributed from the telematics center 100 when software update of any ECU fails. .

  The communication unit 220 includes a network card that conforms to a communication standard used in the network 300. The network card conforms to wireless communication such as a wireless LAN, for example. The communication unit 220 transmits / receives data to / from the telematics center 100 based on various protocols via the network 300. Here, communication by the communication unit 220 is limited to a wireless method. Therefore, for example, when the communication unit 220 uses a mobile phone network, the communication unit 220 is out of the communication range because the vehicle 200 is parked in the underground parking lot, and the communication unit 220 cannot communicate with the telematics center 100. there is a possibility.

  The navigation terminal 230 includes a central processing unit 231, a storage device 233, and an input / output device 234 that includes a combination of a touch panel, a keyboard, a mouse, and the like.

  The central processing unit 231 is composed of, for example, a CPU and a RAM, and executes a process for realizing the function of the navigation terminal 230 by executing a predetermined operation program. The central processing unit 231 includes an update information display unit 232 as its function. The update information display unit 232 performs display on the input / output device 234 based on the update information transmitted from the telematics center 100. When an input for permitting software update is made by the user using the input / output device 234, the license information is acquired and transmitted to the telematics center 100.

  The storage device 233 includes, for example, an HDD, an SSD, a flash memory, and a ROM, and stores a program executed by the central processing unit 231 and a data group necessary for program execution.

  The software update device 210 and the navigation terminal 230 may be the same device. Further, the navigation terminal 230 is not mounted on the vehicle 200, and a mobile terminal such as a smartphone may be used as the navigation terminal 230, for example. In this case, it is conceivable that the communication unit 220 exists on the mobile terminal side, and the software update apparatus 210 communicates with the mobile terminal by using a connector such as OBD (On Board Diagnostics).

  FIG. 2 is a diagram illustrating an example of a table representing the structure of data stored in the vehicle configuration DB 121, the vehicle type configuration DB 122, and the functional configuration DB 123 of the telematics center 100 in the first embodiment of the present invention.

  The vehicle configuration DB 121 stores VIN (Vehicle Identification Number) 400, vehicle type ID 401, ECU type 402, ECU ID 403, and software version 404 data. The VIN 400 is an identifier that can uniquely identify the vehicle 200. The vehicle type ID 401 is an identifier that can uniquely identify the vehicle type of the vehicle 200 having the VIN 400. The ECU type 402 is an identifier that can uniquely specify the type of ECU mounted on the vehicle 200 having the VIN 400. The ECU ID 403 is an identifier that can uniquely identify the ECU mounted on the vehicle 200 having the VIN 400. The software version 404 is an identifier that can uniquely specify version information of software installed in the ECU specified by the ECU ID 403.

  The vehicle type configuration DB 122 stores data of a vehicle type ID 410, an ECU type 411, an ECU category 412, a function category 413, and an offline recovery function 414. The vehicle type ID 410 is data common to the vehicle type ID 401 of the vehicle configuration DB 121, and is an identifier that can uniquely identify the vehicle type of each vehicle 200. The ECU type 411 is data common to the ECU type 402 of the vehicle configuration DB 121 and is an identifier that can uniquely identify the type of ECU mounted on each vehicle 200. The ECU category 412 is information indicating a category to which the ECU specified by the ECU type 411 belongs. The function category 413 is information indicating a category of functions that the ECU assumes in the control of the vehicle 200. The offline recovery function 414 is information indicating whether or not the ECU supports an offline recovery method.

  In the vehicle type configuration DB 122, the ECU category 412 reflects the network configuration of each ECU in the vehicle 200 in the software update system shown in FIG. That is, as described above, each ECU mounted on the vehicle 200 is connected to a different bus-type CAN network according to its function sharing, and the software updating apparatus 210 has a hub function. Each ECU category represented by the ECU category 412 is configured in units of the bus CAN network. In general vehicles, connections between ECUs have such a network configuration, and names such as a powertrain system, a chassis system, and a safety system are given to each network. The ECU category 412 represents the ECUs mounted on the vehicle 200 divided into a plurality of groups in accordance with this network form.

  Further, the function category 413 in the vehicle type configuration DB 122 represents the importance of the function of each ECU, that is, how much influence the function of each ECU has on the operation of the vehicle 200. For example, the vehicle 200 cannot be started unless the engine ECU 240 is operated, but the vehicle 200 can travel normally even if the air conditioner control ECU 247 is not operated, and the vehicle 200 can be directly operated. There is no significant impact. The function category 413 represents the difference in function of each ECU with respect to the control of the vehicle 200, and the ECU mounted on the vehicle 200 is divided into a plurality of groups in a form that does not necessarily match the ECU category 412. It expresses.

  The above-described dividing method of the ECU category 412 and the function category 413 is not limited to dividing into five groups as shown in FIG. 2, and dividing into groups having fewer or more than five groups. Also good.

  The function configuration DB 123 stores data of a function category 420, within-range movement availability 421, speed limit 422, function limit 423, and user notification content 424. The function category 420 is data common to the function category 413 of the vehicle type configuration DB 122, and represents the importance of the function that each ECU plays. The area movement permission / inhibition 421 is information indicating whether or not the vehicle 200 can be moved when an ECU belonging to the category specified by the function category 420 becomes inoperable. The speed limit 422 is information indicating whether or not the speed limit should be imposed on the movement of the vehicle 200 when the ECU becomes inoperable. The function restriction 423 is information indicating whether or not the function restriction should be imposed on the vehicle 200 when the ECU becomes inoperable. The user notification content 424 is information representing a message when a special notification is given to the user when the ECU becomes inoperable.

  In the storage device 120, for each vehicle 200, information as described above is stored in the vehicle configuration DB 121, the vehicle type configuration DB 122, and the function configuration DB 123, respectively. These pieces of information are used by the configuration information management unit 111 to identify ECUs to which update software is distributed. Further, as described above, the influence on the operation of the vehicle 200 when the software update of any ECU fails is shown.

  FIG. 3 is a diagram illustrating an example of a table representing the structure of data stored in the update item management DB 124 and the progress management DB 125 of the telematics center 100 in the first embodiment of the present invention.

  The update item management DB 124 stores data of an update item ID 500, an ECU ID 501, an update file name 502, and an applied version 503. The update case ID 500 is an identifier that can uniquely identify a case that requires a software update for a plurality of vehicles 200 such as a recall. The ECU ID 501 is an identifier that can uniquely identify the ECU to be updated by the update case specified by the update case ID 500, and corresponds to the ECU ID 403 of the vehicle configuration DB 121. The file name 502 is information indicating the file name of the update software distributed to the update target ECU specified by the ECU ID 501. The application version 503 is information indicating the software version of the ECU after being updated by applying the update software indicated by the file name 502.

  The progress management DB 125 stores update case ID 510, VIN 511, status 512, update date 713, and update execution position 514. The update case ID 510 is data common to the update case ID 500 of the update case management DB 124. The VIN 511 is an identifier that can uniquely identify the vehicle 200 targeted by the update case specified by the update case ID 510, and corresponds to the VIN 400 of the vehicle configuration DB 121. The status 512 is information indicating how much progress the update item specified by the update item ID 510 is in the vehicle 200 specified by the VIN 511. For example, the status 512 manages the progress status of the update item based on the status of whether the download of the update software has been completed, whether the installation permission has been obtained from the user (during installation), and whether the installation has been completed. . The update date / time 713 is information indicating the update execution date / time when the update of the update case is completed. The update execution position 514 is information indicating the position information of the vehicle 200 when the update item is updated.

  Each data of the update item management DB 124 is input via the input / output device 130 by the administrator of the telematics center 100 or the like before the telematics center 100 distributes the update software to the vehicle 200. As the manager, for example, an operator of the telematics center 100, an ECU manufacturing manager, or the like can be considered. When the update matter management unit 112 accepts the input of the ECU ID to be updated and the update software file and version information used for the update, the update matter management unit 112 newly generates an ID for the update matter, Based on this, each data is accumulated in the update item management DB 124. Thereafter, the update case management unit 112 searches the vehicle configuration DB 121 for a vehicle 200 having the same ECU ID 403 stored in the ECU ID 501 of the update case management DB 124, and determines the VIN 400 value of the corresponding vehicle 200 as the update case ID 500. Are stored in the progress management DB 125 as VIN 511 and update ID 510, respectively.

  FIG. 4 is a diagram showing the flow of the update software download process executed in the first embodiment of the present invention. The processing shown in FIG. 4 includes an update item confirmation unit 212 and an update software request unit 213 of the software update device 210 mounted on the vehicle 200, an update item management unit 112 and an update software distribution unit 113 of the telematics center 100. Is done.

  In FIG. 4, the update item confirmation unit 212 detects the engine start of the vehicle 200 using information from the engine ECU 240 (step S600). When engine start is detected in step S600, the update matter confirmation unit 212 makes an inquiry about the update matter to the telematics center 100 in order to confirm whether there is an update matter that has not yet been updated (step S600). S601). At this time, the update item confirmation unit 212 collects the ID and software version information from all ECUs of the vehicle 200 connected to the software update device 210. Then, based on the collected information and the VIN of the vehicle 200, vehicle configuration information indicating the current configuration of the vehicle 200 is generated, given to an inquiry to the telematics center 100, and transmitted from the communication unit 220.

  The update matter inquiry transmitted from the vehicle 200 in step S601 is received by the communication unit 140 in the telematics center 100 (step S610). When an update case inquiry is received in step S610, the update case management unit 112 of the telematics center 100 first updates the vehicle configuration information corresponding to the inquiry source vehicle 200 (step S611). Here, the update case management unit 112 searches the vehicle configuration DB 121 for a record having the same value VIN400 as the VIN of the vehicle 200 represented by the vehicle configuration information received together with the update case inquiry in step S610. Then, regarding the ECU ID 403 included in the retrieved record, the software version 404 value of the received vehicle configuration information is compared with the value of the software version 404, and if these values are different, the value of the software version 404 of the corresponding record is received. Overwrite with the software version of the vehicle configuration information. At this time, if an ECU is added to the vehicle 200, one record corresponding to the ECU may be added. Further, when the software version of the vehicle configuration information received for all the records matches the value of the software version 404, it is not necessary to execute the overwriting process.

  Next, the update case management unit 112 checks whether or not there is an update case for the inquiry source vehicle 200 (step S612). Here, the update case management unit 112 confirms whether or not the VIN of the vehicle 200 represented by the vehicle configuration information received together with the update case inquiry in step S610 is registered in the VIN 511 of the progress management DB 125. The presence / absence of an update case for the vehicle 200 is confirmed. If the presence / absence of the update case can be confirmed in step S612, the update case management unit 112 transmits the confirmation result to the inquiry source vehicle 200 from the communication unit 140 (step S613).

  The confirmation result of the update case transmitted from the telematics center 100 in step S613 is received by the communication unit 220 in the software update device 210 of the vehicle 200 (step S602). When the confirmation result of the update item is received in step S602, the update item confirmation unit 212 of the software updating apparatus 210 determines the presence or absence of the update item based on the confirmation result (step S603). As a result, when it is determined that there is no update case (S603: No), it is determined that there is no update software to be downloaded for the current engine start, and the processing of FIG.

  On the other hand, when it is determined that there is an update case (S603: Yes), the update software request unit 213 requests the telematics center 100 for update software for the update target ECU (step S604).

  The update software request transmitted from the vehicle 200 in step S604 is received by the communication unit 140 in the telematics center 100 (step S614). When the update software request is received in step S614, the update software distribution unit 113 of the telematics center 100 sends the update software for the target update case and the update information according to the ECU configuration of the vehicle 200 to the communication unit. 140 is transmitted to the requesting vehicle 200 (step S615). Here, the update software distribution unit 113 confirms again whether or not the VIN of the requesting vehicle 200 is registered in the VIN 511 of the progress management DB 125 as in step S612, and is the same as the update item ID 510 of the corresponding record. By searching the update item management DB 124 for a record whose value is recorded in the update item ID 500, an update file name 502 indicating the file name of the update software necessary for software update is extracted. Further, a record having the same value VIN400 as the VIN of the requesting vehicle 200 is searched from the vehicle configuration DB 121, and a record in which the same value as the vehicle type ID 401 of the corresponding record is recorded in the vehicle type ID 410 is searched from the vehicle type configuration DB122. The record in which the same value as the function category 413 of the corresponding record in the vehicle type configuration DB 122 is stored in the function category 420 is searched from the function configuration DB 123. And by extracting each data of the record respectively searched in vehicle type composition DB122 and functional composition DB123, vehicle type composition information and functional composition information corresponding to request origin vehicle 200 are extracted, and these are put together, vehicle Update information corresponding to the ECU configuration of 200 is generated. This update information represents the influence on the operation of the vehicle 200 when the software update fails for each ECU mounted on the requesting vehicle 200. When the update software file name is extracted and update information corresponding to the ECU configuration of the vehicle 200 can be generated in this way, the update software distribution unit 113 acquires the update software corresponding to the extracted file name from the update item management DB 124. It is extracted and transmitted to the requesting vehicle 200 together with the generated update information.

  In step S614, the update software distribution unit 113 may transmit only the update software to the vehicle 200 and may not transmit update information. In that case, update information according to the ECU configuration of the vehicle 200 may be stored in advance in the storage device 215 of the software update device 210 in the vehicle 200. In addition to the processing shown in FIG. 4, update information may be transmitted from the telematics center 100 to the software update device 210 periodically or as necessary.

  The software for update and the update information transmitted from the telematics center 100 in step S615 are received by the communication unit 220 in the software update device 210 of the vehicle 200 (step S605). When the update software and the update information are received in step S605, the update software request unit 213 of the software update device 210 accumulates these data in the storage device 215 (step S606). Thereafter, the update software request unit 213 notifies the telematics center 100 that the download of the update software has been completed (step S607).

  When the download completion notification transmitted from the vehicle 200 is received in step S607, the update matter management unit 112 of the telematics center 100 searches the progress management DB 125 for a record in which the VIN of the notification source vehicle 200 is registered. The record status 512 is updated (step S616). Then, a command to start installation is transmitted to the notification source vehicle 200 (step S617).

  The installation start command transmitted from the telematics center 100 in step S617 is received by the communication unit 220 in the software update device 210 of the vehicle 200 (step S608). When the installation start command is received in step S608, the update item confirmation unit 212 of the software update device 210 ends the process of FIG. 4 and enters a standby state until the engine of the vehicle 200 is turned off.

  When the process of FIG. 4 described above has failed to update the software of the ECU to be updated from the telematics center 100 to the software update device 210 of the vehicle 200 and the software of the ECU have failed. The update information regarding the influence on the operation of the vehicle 200 is distributed.

  FIG. 5 is a diagram showing a flow of ECU software update processing executed in the first embodiment of the present invention. The processing shown in FIG. 5 is performed by the ECU software update unit 214 of the software update device 210 mounted on the vehicle 200, the update information display unit 232 of the navigation terminal 230, and the update item management unit 112 of the telematics center 100.

  In FIG. 5, ECU software update unit 214 detects the engine stop of vehicle 200 using information from engine ECU 240 (step S700). If engine stop is detected in step S700, the ECU software update unit 214 checks whether there is an update item that has not yet been updated among update items for which update software has been downloaded by the process of FIG. (Step S701). As a result, when it is determined that there is no incomplete update item (S701: No), there is no ECU software update process to be executed when the engine is stopped at this time, and thus the process of FIG. 5 ends.

  On the other hand, if it is determined that there is an incomplete update item (S701: Yes), the update information display unit 232 notifies the user that installation of the update software is started using the input / output device 234. (Step S702). Here, the update information display unit 232 confirms the update contents by referring to the update software downloaded from the telematics center 100 and stored in the storage device 215 in step S605 of FIG. Then, the confirmed update content is output to the input / output device 234 of the navigation terminal 230 and displayed on the screen, thereby giving an update notification to the user. Further, at this time, the option of whether or not to permit the update is also displayed on the screen, and the user is made to select one of the options in the input / output device 234.

  When the update notification to the user is made in step S702, the ECU software update unit 214 determines whether or not an update permission has been obtained based on a user input operation to the input / output device 234 (step S703). As a result, if the update permission is not obtained from the user (S703: No), the ECU software update unit 214 notifies the telematics center 100 to that effect (step S706), and then the engine of the vehicle 200 Enter standby until it is off. When this notification is received from the vehicle 200, the update matter management unit 112 of the telematics center 100 searches the progress management DB 125 for a record in which the VIN of the notification source vehicle 200 is registered, and sets the status 512 of the corresponding record to “user permission”. Update to “waiting for acquisition” (step S711). Thereafter, the process of FIG. 5 is repeated until an update permission is obtained from the user.

  On the other hand, when an update permission is obtained from the user (S703: Yes), the ECU software update unit 214 starts updating the EUC software using the downloaded update file to the telematics center 100. (Step S704). When the update start notification is received, the update matter management unit 112 of the telematics center 100 searches the progress management DB 125 for a record in which the VIN of the notification source vehicle 200 is registered, and sets the status 512 of the record to “update start”. (Step S710).

  After performing the update start notification in step S704, the ECU software update unit 214 uses the update software downloaded from the telematics center 100 and stored in the storage device 215 in the update software download process described in FIG. The ECU software to be updated is updated (step S705). Then, the update execution result is notified to the telematics center 100 (step S706), and then the standby state is entered until the engine of the vehicle 200 is turned off. When this notification is received from the vehicle 200, the update matter management unit 112 of the telematics center 100 searches the progress management DB 125 for a record in which the VIN of the notification source vehicle 200 is registered, and updates the status 512 of the corresponding record ( Step S711). At this time, if the notification that the update execution result is normal is received, the status 512 of the corresponding record is updated to “update normal completion”, and if not, the status 512 of the corresponding record is set to “update failed”. Update to

  By the process of FIG. 5 described above, the software of the ECU to be updated is updated using the downloaded update software.

  Depending on the state of the vehicle 200, the communication unit 220 may be out of the communication range as described above, and communication may not be possible between the software update device 210 and the telematics center 100. In such a case, the telematics center 100 cannot receive the update start notification in step S704 or the update execution result notification in step S706 from the software update device 210. As a result, the update matter management unit 112 of the telematics center 100 cannot execute the processes of step S710 and step S711. Therefore, when the notification from the software update device 210 cannot be obtained, the update matter management unit 112 suspends the processing in step S710 and step S711 until the vehicle 200 becomes communicable, and the communicable state is established. You may make it perform these processes when it becomes.

  Next, a recovery process that is executed when the ECU 200 fails to update the ECU software will be described. 6 and 7 are diagrams showing the flow of recovery processing executed in the first embodiment of the present invention. The processing shown in FIGS. 6 and 7 includes the ECU software update unit 214 of the software update device 210 and the update information display unit 232 of the navigation terminal 230 mounted on the vehicle 200, the update item management unit 112 of the telematics center 100, and the recovery. This is performed by the software distribution unit 114.

  In FIG. 6, ECU software update unit 214 detects engine start of vehicle 200 using information from engine ECU 240 (step S800). When engine start is detected in step S800, the ECU software update unit 214 confirms whether or not the ECU software update process described in FIG. 5 has been executed when the engine of the vehicle 200 was stopped (immediately before) (step S801). . As a result, if the ECU software update process has not been executed (S801: No), the processes in FIGS. 6 and 7 are terminated. After this, the processing shown in FIG. 4 may be performed.

  On the other hand, when the ECU software update process has been executed (S801: Yes), the ECU software update unit 214 checks whether or not the process result has failed (step S802). As a result, if the previous ECU software update process has failed (S802: Yes), that is, if the update target ECU software has not been updated normally at the time of the previous engine stop, the process proceeds to step S803. Proceed to On the other hand, if the previous ECU software update process has been successful (S802: No), that is, if the update target ECU software has been successfully updated at the time of the previous engine stop, the process is performed as shown in FIG. The process proceeds to S905.

  In step S803, the ECU software update unit 214 determines whether or not the ECU that has failed to update the software cannot perform recovery on its own. Here, the ECU software update unit 214 performs the determination in step S803 based on the update information downloaded from the telematics center 100 and stored in the storage device 215 in step S605 of FIG. Specifically, by using the ECU type of the ECU as a search key, the offline recovery function 414 corresponding to the ECU is searched from the vehicle type configuration information included in the update information, and the content is confirmed, whereby the ECU It is determined whether or not recovery by itself is impossible. As a result, when the content of the offline recovery function 414 corresponding to the ECU is “True”, the ECU determines that the recovery can be performed by itself (step S803: No), and the process is performed in step S804. Proceed to On the other hand, when the content of the offline recovery function 414 corresponding to the ECU is “False”, the ECU determines that the recovery cannot be performed by itself (step S803: Yes), and the process proceeds to step S805.

  In step S804, the ECU software update unit 214 determines to perform offline recovery for the ECU. After this determination, the ECU software update unit 214 proceeds with the process to step S903 in FIG.

  In step S805, the ECU software update unit 214 determines whether or not the communication unit 220 mounted on the vehicle 200 is out of the communication range, that is, whether or not the software update device 210 and the telematics center 100 are in a communication disabled state. Determine whether. As a result, when the communication unit 220 is within the communication range and the software updating apparatus 210 and the telematics center 100 can communicate (step S805: No), the process proceeds to step S806. On the other hand, when the communication unit 220 is out of the communication range and the software update device 210 and the telematics center 100 cannot communicate (step S805: Yes), the process proceeds to step S807.

  In step S806, the ECU software update unit 214 determines to execute online recovery for the ECU. After this determination, the ECU software update unit 214 advances the process to step S901 in FIG.

  In step S807, the ECU software update unit 214 determines whether or not online recovery of the ECU that failed to update the software is feasible by moving the vehicle 200 into the communication range. Here, the ECU software update unit 214 performs the determination in step S807 based on the update information downloaded from the telematics center 100 and stored in the storage device 215 in step S605 of FIG. Specifically, using the ECU type of the ECU as a search key, the function category 413 corresponding to the ECU is searched from the vehicle type configuration information included in the update information, and the ECU confirms the content of the function category 413. Identify the functional category to which it belongs. Then, by using the identified function category as a search key, the within-range movement propriety 421 corresponding to the ECU is searched from the function configuration information included in the update information, and the content is confirmed, so that the ECU is not used. Next, it is determined whether or not the vehicle 200 can be moved within the communication range. As a result, when the content of the within-range movement permission / inhibition 421 corresponding to the ECU is “False”, it is determined that it is impossible to move the vehicle 200 into the communication range without using the ECU (step S100). S807: No), the process proceeds to step S808. On the other hand, when the content of within-range movement permission / inhibition 421 corresponding to the ECU is “True”, it is determined that the vehicle 200 can be moved within the communication range without using the ECU (step S807: Yes), the process proceeds to step S809.

  In step S808, the ECU software updating unit 214 determines that the recovery of the ECU is abandoned because the vehicle 200 cannot travel and the vehicle 200 cannot be moved into the communication range. After this determination, the ECU software update unit 214 advances the process to step S905 in FIG.

  In step S809, the ECU software update unit 214 prompts the user to move the vehicle 200 to the communication range. Here, the ECU software update unit 214 uses the update information display unit 232 and the input / output device 234 of the navigation terminal 230 to notify the user. Specifically, a message that the software update device 210 should move to a position where the software update device 210 can communicate with the telematics center 100 is displayed by image display or sound of the input / output device 234 according to the control of the update information display unit 232. By outputting, the user is prompted to move the vehicle 200 into the communication range. Further, at this time, the ECU software updating unit 214 determines whether or not there is a restriction on the operation of the moving vehicle 200 based on the update information downloaded from the telematics center 100 and stored in the storage device 215 in step S605 of FIG. If it is determined that there is a restriction, the contents are notified to the user. Specifically, the speed limit 422, the function limit 423, and the user notification content 424 corresponding to the ECU are searched from the function configuration information included in the update information using the function category specified in step S807 as a search key. Then, based on the retrieved data contents, it is confirmed whether or not there is a speed restriction or a function restriction on the operation of the moving vehicle 200, and the notice contents to the user are confirmed to control the update information display unit 232. The user is notified by the image display and sound of the corresponding input / output device 234. After making these notifications, the ECU software update unit 214 waits until the vehicle 200 is moved into the communication range, and advances the process to step S900 in FIG.

  In step S900 of FIG. 7, the ECU software update unit 214 periodically checks whether or not the communication unit 220 mounted on the vehicle 200 is in a communication range.

  When the communication unit 220 is in the communication range (S900: Yes) or when it is determined to perform online recovery in step S806 in FIG. 6, the ECU software update unit 214 recovers the software of the target ECU. To request the telematics center 100 for recovery software (step S901). When receiving this request, the update matter management unit 112 of the telematics center 100 searches the progress management DB 125 for a record in which the VIN of the notification source vehicle 200 is registered, and updates the status 512 of the record to “being recovered”. (Step S910). Then, data for returning the software of the ECU to the state before update, such as software data before update, is extracted from the update case management DB 124 and transmitted to the vehicle 200 as recovery software (step S911).

  The recovery software transmitted from the telematics center 100 in step S911 is received by the communication unit 220 in the software update device 210 of the vehicle 200 (step S902). When the recovery software is received in step S902, the ECU software update unit 214 of the software update device 210 uses the received recovery software to execute a recovery process for the ECU that failed to update the software (step S903). Then, the recovery result is notified to the telematics center 100 (step S904).

  When the notification of the recovery result is received from the software update device 210 of the vehicle 200, the update matter management unit 112 of the telematics center 100 searches the progress management DB 125 for a record in which the VIN of the notification source vehicle 200 is registered, and the corresponding record Status 512 is updated to “recovery complete” (step S912).

  After notifying the recovery result in step S904, the ECU software updating unit 214 uses the update information display unit 232 and the input / output device 234 of the navigation terminal 230 to display a screen for notifying the user of the recovery result. (Step S905). Here, the input / output device 234 displays a screen indicating whether the result of the recovery process executed in step S903 was success or failure. If the recovery result is unsuccessful, the vehicle 200 continues to move only under speed restriction or function restriction, and there are restrictions on the operation of the vehicle 200. Therefore, in such a case, for example, the contact information of the dealer and the route to the dealer are displayed on the input / output device 234 so that the user can perform fundamental recovery processing at the dealer of the nearest vehicle 200. May be. In addition, after the completion of the recovery process shown in FIGS. 6 and 7, the update software download process described in FIG. 4 is executed, so that the vehicle configuration information is transmitted to the telematics center 100 to confirm the update case. Also good.

  If it is determined in step S808 in FIG. 6 that the recovery is abandoned, in step S905, the ECU software update unit 214 displays a screen for notifying the user that the recovery is abandoned. In this case, since the vehicle 200 cannot run and the user cannot use the vehicle 200, the user can contact the dealer of the nearest vehicle 200 and perform a fundamental recovery process. For example, the contact information of the dealer may be displayed on the input / output device 234.

  If it is determined in step S804 in FIG. 6 that recovery by offline power is performed, in step S903, the ECU software update unit 214 performs the recovery process in step S903 offline without using the recovery file. Run. If this recovery process fails, the process returns to step S805 in FIG. 6 to check whether the communication unit 220 is out of the communication range, thereby confirming whether online recovery can be performed. For example, the processing after step S806 may be executed.

  In step S900 of FIG. 7, if the communication unit 220 does not enter the communication range even after a predetermined time has elapsed, the ECU software update unit 214 may end the processes shown in FIGS. In that case, before the end of the process, as in the case where the recovery result described above is unsuccessful, the contact information of the dealer, The route to the dealer may be displayed on the input / output device 234.

  When the ECU 200 fails to update the ECU 200 in the vehicle 200 as described above, the content of the recovery process is based on the update information downloaded from the telematics center 100 and stored in the storage device 215. Is determined. Thereby, the operation of the ECU software update unit 214 in the recovery process is controlled.

  FIG. 8 is a diagram showing an example of a screen displayed on the input / output device 130 of the telematics center 100 in the first embodiment of the present invention. For example, a screen as shown in FIG. 8 is displayed on the input / output device 130 as a screen showing function categories to which a plurality of ECUs mounted on the vehicle 200 belong.

  The screen shown in FIG. 8 includes screen areas indicated by reference numerals 1000, 1010, and 1020, respectively. The screen area 1000 shows the information of the vehicle type configuration DB 122 visualized. In the screen area 1000, based on the vehicle type ID 410, ECU type 411, and ECU category 412 information in the vehicle type configuration DB 122, the types and categories of all ECUs mounted on the vehicle 200 are displayed in units of vehicle types using a tree-shaped diagram. It is represented. The screen areas 1010 and 1020 show the information recorded in the vehicle type configuration DB 122 and the functional configuration DB 123 for any of the ECUs selected in the screen area 1000 (in the example of FIG. 8, the automatic driving ECU 245). Is. In the screen area 1010, the contents of each information of the ECU type 411, the ECU category 412, the function category 413, and the offline recovery function 414 of the vehicle type configuration DB 122 corresponding to the ECU are displayed. In the screen area 1020, the contents of each information of the function category 420 of the function configuration DB 123 corresponding to the ECU, the movement possibility / inhibition 421, the speed limit 422, the function limit 423, and the user notification contents 424 are displayed. In the screen areas 1010 and 1020, the administrator of the telematics center 100 can change the contents of the vehicle configuration DB 122 and the functional configuration DB 123 by overwriting arbitrary information via the input / output device 130.

  FIG. 9 is a diagram showing an example of a screen displayed on the input / output device 234 of the navigation terminal 230 mounted on the vehicle 200 in the first embodiment of the present invention.

  In FIG. 9, a screen 1100 is an example of a screen displayed on the input / output device 234 in order to prompt the user to move the vehicle 200 to the communication range in step S809 of FIG. A screen 1100 is composed of screen areas indicated by reference numerals 1101, 1102, and 1103, respectively. The screen area 1101 is an area indicating that the communication unit 220 is currently out of the communication area and that it is necessary to move the vehicle 200 to the communication area in order to perform online ECU software recovery. A screen area 1102 is an area indicating the radio wave status of the communication unit 220. A screen area 1103 is an area showing a function restriction state of the vehicle 200. The screen 1100 shows a situation in which, for example, the automatic operation ECU 245 has failed to update the software, and the vehicle 200 is in an area outside the communication range due to these screen areas. In this case, since the software update of the automatic driving ECU 245 has failed, the automatic driving function is forcibly turned off in the vehicle 200, but the manual driving is not affected. Therefore, displaying screen 1100 prompts the user to manually move vehicle 200 to the communication area.

  In FIG. 9, a screen 1110 is an example of a screen displayed on the input / output device 234 when it is detected in step S900 of FIG. The screen 1110 displays a message notifying the user that online software recovery of the automatic operation ECU 245 is started by communicating with the telematics center 100.

  In FIG. 9, a screen 1120 is an example of a screen displayed on the input / output device 234 in step S905 of FIG. 7 when the ECU software is successfully recovered. The screen 1120 displays a message notifying the user that the software recovery of the automatic operation ECU 245 has been successful.

  In addition, although the example in the case of recovering the software of automatic operation ECU245 is shown in the example of a screen shown in FIG. 9, you may change the display content of a screen according to ECU made into recovery object.

  According to the 1st Embodiment of this invention demonstrated above, there exist the following effects.

(1) The software update system of this embodiment manages the update of the software of ECU which is the vehicle equipment mounted in the vehicle 200. The software update device 210 mounted in the vehicle 200, and the software update device 210 And a telematics center 100 that performs communication via the network 300. The telematics center 100 includes an update software distribution unit 113 that distributes update software for updating the software of the ECU to the software update device 210. The software update device 210 stores the update software distributed from the telematics center 100, and stores the update information related to the influence on the operation of the vehicle 200 when the ECU software update fails, and the storage device 215 An ECU software update unit 214 that updates the ECU software using the update software stored in the device 215, and controls the operation of the ECU software update unit 214 based on the update information stored in the storage device 215. To do. Since it did in this way, the software update of the vehicle equipment by OTA which is easy to use for a user is realizable.

(2) Based on the update information, the ECU software update unit 214 of the software update device 210 determines the content of the recovery process that is performed when the ECU software update fails (steps S803 to S809). Since it did in this way, the content of the recovery process can be determined appropriately.

(3) The telematics center 100 includes a recovery software distribution unit 114 that distributes recovery software for returning the ECU software to a state before update to the software update device 210. When the software update device 210 can communicate with the telematics center 100 (step S805: No), the ECU software update unit 214 of the software update device 210 requests the telematics center 100 to distribute the recovery software in the recovery process. (Step S901). On the other hand, when the software updating apparatus 210 cannot communicate with the telematics center 100 (step S805: Yes), it is determined whether or not the vehicle 200 can move based on the update information in the recovery process (step S807). As a result, if the vehicle 200 can be moved, the software update device 210 urges the user to move the vehicle 200 to a position where the software update device 210 can communicate with the telematics center 100 (step S809). (Step S900: Yes), the telematics center 100 is requested to distribute recovery software (step S901). Since it did in this way, even if it is a case where the software update apparatus 210 cannot communicate with the telematics center 100 because of the position of the vehicle 200, a vehicle 200 is moved to a user and an online recovery process is implement | achieved. Can do.

(4) When the ECU software updating unit 214 prompts the user to move the vehicle 200 in step S809, the ECU software updating unit 214 determines whether there is a restriction on the operation of the vehicle 200 based on the update information. As illustrated on the screen 1100 in FIG. 9, the contents are notified to the user. Since it did in this way, even when there is a restriction | limiting with respect to operation | use of the vehicle 200 since ECU for recovery is unusable, the user can move the vehicle 200 safely.

(5) The update software distribution unit 113 of the telematics center 100 distributes update information together with the update software to the software update device 210 (step S615). The storage device 215 of the software update device 210 stores the update software and update information distributed from the telematics center 100 (step S606). Since it did in this way, the update information according to the ECU structure of the vehicle 200 can be memorize | stored in the memory | storage device 215. FIG.

(6) The plurality of ECUs mounted on the vehicle 200 are grouped into a plurality of function categories according to the degree of influence on the operation of the vehicle 200, for example, function categories C1 to C5. The update information includes information on a function category 413 that is information indicating which of a plurality of function categories each of a plurality of ECUs mounted on the vehicle 200 belongs to. Since it did in this way, the influence degree to operation | use of the vehicle 200 of each ECU can be shown in update information easily.

(7) The telematics center 100 includes an input / output device 130 that displays a screen as illustrated in FIG. 8 as a display device that displays a function category to which a plurality of ECUs mounted on the vehicle 200 belong. Since it did in this way, the function of each ECU can be shown to the administrator of the telematics center 100 in an easy-to-understand manner.

(Second Embodiment)
In the first embodiment, an example has been described in which the ECU software to be updated is updated in a state where the engine of the vehicle 200 is stopped, that is, in a state where the vehicle 200 is not used. In contrast, in the second embodiment, an example will be described in which the ECU software to be updated is updated if possible even when the vehicle 200 is traveling. Note that the configuration of the software update system and the update software download process in the second embodiment are the same as those described in FIGS. 1 to 4 in the first embodiment. Therefore, the description about these is abbreviate | omitted below.

  FIG. 10 is a diagram showing a flow of ECU software update processing executed in the second embodiment of the present invention. The process shown in FIG. 10 is performed by the ECU software update unit 214 of the software update device 210 and the update information display unit 232 of the navigation terminal 230 mounted on the vehicle 200 and the update item management unit 112 of the telematics center 100. In the present embodiment, the process of FIG. 10 is executed instead of the process described in FIG. 5 in the first embodiment.

  In FIG. 10, upon receiving an installation start command from the telematics center 100, the ECU software updating unit 214 immediately determines in step S1200 without waiting until the engine of the vehicle 200 is stopped. In step S1200, ECU software update unit 214 determines whether or not the ECU software to be updated can be updated while vehicle 200 is traveling. This determination can be performed by the same method as step S807 in FIG. 6 described in the first embodiment. That is, whether or not the vehicle 200 can be driven without using the ECU by confirming the contents of the within-range movement permission / inhibition 421 of the function category to which the ECU belongs in the functional configuration information included in the update information. Determine. As a result, when the content of the within-range movement permission / inhibition 421 corresponding to the ECU is “False”, it is determined that it is impossible to drive the vehicle 200 without using the ECU (step S1200: No). ), The process of FIG. In this case, as in the first embodiment, the software update of the ECU is attempted after the engine is stopped. On the other hand, when the content of the within-range movement permission / inhibition 421 corresponding to the ECU is “True”, it is determined that the vehicle 200 can be traveled without using the ECU (step S1200: Yes). The process proceeds to step S1201.

  In step S1201, the update information display unit 232 uses the input / output device 234 to notify the user that installation of the update software is started. Further, at this time, the update information display unit 232 restricts the operation of the traveling vehicle 200 based on the update information stored in the storage device 215 as in step S809 of FIG. 6 described in the first embodiment. If it is determined that there is a restriction, the contents are notified to the user. In other words, based on the contents of the speed limit 422, the function limit 423, and the user notification content 424 corresponding to the ECU among the function configuration information included in the update information, the speed limit and the function limit for the operation of the vehicle 200 that is running. In addition to confirming the presence / absence, the contents of notification to the user are confirmed, and the user is notified by image display and sound of the input / output device 234 according to the control of the update information display unit 232. Similarly to step S702 in FIG. 7, an option for whether or not to permit the update is also displayed on the screen, and the user is allowed to select one of the options in the input / output device 234.

  When the update notification to the user is given in step S1201, the ECU software update unit 214 determines whether or not an update permission has been obtained based on the user input operation to the input / output device 234 (step S1202). As a result, if the update permission is not obtained from the user (S1202: No), the ECU software update unit 214 notifies the telematics center 100 to that effect (step S1205), and then the engine of the vehicle 200 Enter standby until it is off. When this notification is received from the vehicle 200, the update matter management unit 112 of the telematics center 100 searches the progress management DB 125 for a record in which the VIN of the notification source vehicle 200 is registered, and sets the status 512 of the corresponding record to “user permission”. Update to “waiting for acquisition” (step S1211). Thereafter, the process of FIG. 10 is repeated until an update permission is obtained from the user.

  On the other hand, when an update permission is obtained from the user (S1202: Yes), the ECU software update unit 214 starts updating the EUC software using the downloaded update file to the telematics center 100. (Step S1203. When this update start notification is received, the update matter management unit 112 of the telematics center 100 searches the progress management DB 125 for a record in which the VIN of the notification source vehicle 200 is registered. Status 512 is updated to “update start” (step S1210).

  When the update start notification is made in step S1203, the ECU software update unit 214 updates the ECU software to be updated using the update software downloaded from the telematics center 100 and stored in the storage device 215 (step S1203). S1204). At this time, the update process of step S1204 is executed regardless of whether or not the vehicle 200 is traveling. Then, the update execution result is notified to the telematics center 100 (step S1205). When this notification is received from the vehicle 200, the update matter management unit 112 of the telematics center 100 searches the progress management DB 125 for a record in which the VIN of the notification source vehicle 200 is registered, and updates the status 512 of the corresponding record ( Step S1211). At this time, if the notification that the update execution result is normal is received, the status 512 of the corresponding record is updated to “update normal completion”, and if not, the status 512 of the corresponding record is set to “update failed”. Update to If the update fails, the recovery process described in FIGS. 6 and 7 in the first embodiment may be executed.

  If the ECU software to be updated has no influence on the running of the vehicle 200 even when the vehicle 200 is running, the download is performed after obtaining the user's consent. The update of the ECU software can be executed using the already used update software.

  According to the second embodiment of the present invention described above, the ECU software update unit 214 of the software update device 210 is based on the update information stored in the storage device 215 and the vehicle 200 is updated during the update of the ECU software. Is determined to be movable (step S1200). As a result, when it is determined that the vehicle 200 can move (step S1200: Yes), the ECU software is updated while the vehicle 200 is traveling (step S1204). Since it did in this way, the software of ECU can be updated during the driving | running | working of the vehicle 200. FIG.

(Third embodiment)
In the first embodiment, in response to an inquiry from the vehicle 200, it is confirmed whether or not the VIN of the vehicle 200 is registered in the VIN 511 of the progress management DB 125, and the confirmation result is notified to the vehicle 200. The example in which the presence / absence of an update item is notified without considering the processing load of the center 100 has been described. On the other hand, in the third embodiment, an example in which the presence / absence of an update matter is notified in consideration of the processing load of the telematics center 100 will be described. The configuration of the software update system according to the third embodiment is the same as that described with reference to FIGS. 1 to 3 in the first embodiment. Therefore, the description about these is abbreviate | omitted below.

  FIG. 11 is a diagram showing the flow of update item confirmation processing executed in the third embodiment of the present invention. The process shown in FIG. 11 is performed by the update item management unit 112 of the telematics center 100. In the present embodiment, in the update software download process described in the first embodiment, the process of FIG. 11 is executed instead of the process of step S612 of FIG.

  In FIG. 11, the update case management unit 112 checks whether there is an update case for the inquiry source vehicle 200 by the same method as in step S612 of FIG. 4 (step S1301). Next, the update item management unit 112 determines whether or not an update item exists based on the confirmation result in step S1301 (step S1302). As a result, if there is no update item (S1302: No), the process proceeds to step S1310.

  On the other hand, when there is an update case (S1302: Yes), the update case management unit 112 among the vehicle type configuration information included in the update information, the function category 413 corresponding to the ECU to be updated in the update case. The function category of the ECU is confirmed based on the contents of (Step S1303). Hereinafter, the function category of the ECU confirmed in step S1303 will be referred to as function category Cx. That is, in the example of the vehicle type configuration DB 122 and the function configuration DB 123 shown in FIG. 2, the value x in the function category Cx is any one of 1 to 5. In this embodiment, the value of x in this function category Cx is regarded as the priority of software update of the ECU, and the subsequent processing is executed. That is, in the example of FIG. 2, for example, the engine ECU 240 and the steering ECU 242 whose function category is C1 has a software update priority of 1, and the audio ECU 248 whose function category is C5 has a software update priority. 5 is assumed. In this way, the priority for updating the software of each ECU can be set based on the function category to which each of the plurality of ECUs mounted on the vehicle 200 belongs. In this case, the smaller the numerical value of the priority, the higher the priority of software update of the ECU.

  Next, the update matter management unit 112 searches the status 512 for all the vehicles 200 registered in the progress management DB 125, and the update matter record whose progress is not yet downloaded, that is, the status 512 is “download completed”. ”Or a record that is not in the subsequent state is extracted (step S1304). Then, from the update item ID 510 of each extracted record, the function item 413 is extracted by searching the update item management DB 124, the vehicle configuration DB 121, and the vehicle type configuration DB 122 in this order, so that each ECU of the ECU corresponding to the update item that has not been downloaded yet. Find the functional category. Based on the function category of each ECU thus obtained, the number of update cases that have not been downloaded for each of the function categories C1 to C5 is counted (step S1305). Then, the ratio of each count number of the function categories C1 to C5 to the total number of update cases that have not been downloaded is calculated (step S1306). The ratio of the count number calculated for each function category in this way corresponds to the processing load of the telematics center 100 required for distributing the update software of each ECU belonging to the function category. That is, by executing the processing of steps S1304 to S1306 in the update item management unit 112, the processing load of the telematics center 100 required for distributing the update software can be calculated for each functional category of the ECU.

  Subsequently, the update matter management unit 112 assigns a priority equal to or higher than the function category Cx to which the update target ECU extracted in step S1303 belongs based on the ratio of the count number of each function category calculated in step S1306. The total ratio (A%) of the count numbers of the functional categories that are possessed is calculated (step S1307). Here, for example, the ratio of the count number calculated in step S1306 is 24%, 12%, 28%, 20%, 16% in order from C1 to C5, and the functional category of the ECU to be updated is C3. In this case, A = 24 + 12 + 28 = 64% is calculated by summing the ratios of the count numbers of C1, C2, and C3. Thereby, based on the priority, that is, the function category of each ECU mounted on all the vehicles 200 registered in the progress management DB 125, the ECU targeted for the update case confirmed in step S1301, and the update software ECUs that have not yet been downloaded and that have the same or higher priority as the priority can be identified as the processing load calculation target of the telematics center 100. And about these specified ECU, the processing load of the telematics center 100 required for distribution of the software for update can be calculated.

  When the total ratio A% is calculated in step S1307, the update case management unit 112 checks whether the current remaining capacity of the telematics center 100 is equal to or more than the calculated A% (step S1308). As a result, if the remaining power is A% or more (S1308: Yes), the process proceeds to step S1309, and if it is less than A% (S1308: No), the process proceeds to step S1310. Note that the surplus capacity of the telematics center 100 described here is an index indicating the current processing load with respect to the processing capability of the telematics center 100. For example, the central processing that constitutes the telematics center 100 A value obtained by subtracting the CPU usage rate of the processing apparatus 110 from 100% is conceivable. Note that the remaining processing load of the telematics center 100 may be calculated from the usage rate of the storage device 120, the usage rate of the communication unit 140, or the like, instead of the usage rate of the CPU, or may be calculated by combining a plurality of these. good. Further, when the telematics center 100 is constructed on a cloud server, the usage fee of the cloud server may be taken into consideration.

  For example, if the remaining capacity of the telematics center 100 is 80% and A = 64% as described above, the remaining capacity is A% or more, so that an affirmative determination is made in step S1308 and the process proceeds to step S1309. In this case, the update matter management unit 112 determines that the telematics center 100 has a margin for processing the update matter confirmed in step S1301, that is, the update matter for the ECU of the functional category Cx (C3 in this example). For this reason, it is determined to transmit the result of “there is a target case” to the inquiry source vehicle 200 (step S1309).

  On the other hand, if the remaining power of the telematics center 100 is 50% and A = 64% as described above, the remaining power is less than A%, so the determination in step S1308 is negative and the process proceeds to step S1310. In this case, the update matter management unit 112 has another update matter that should be prioritized over the update matter confirmed in step S1301, that is, the update matter for the ECU of the functional category Cx (C3 in this example), and the telematics center 100 Judge that the remaining power should be left. Therefore, it is determined to transmit the result “no target case” to the inquiry source vehicle 200 even though the target case actually exists (step S1310). Similarly, when it is determined in step S1302 that there is no update case, in step S1310, it is determined to transmit a result of “no target case”.

  The update case management unit 112 executes the processes described above for each ECU targeted in the update case confirmed in step S1301. As a result, ECUs that actually distribute the update software and that are to be updated are selected in order of priority within the range of the remaining capacity according to the current processing load of the telematics center 100. After executing the process of step S1309 or S1310 for all ECUs in the update case, the update case management unit 112 advances the process to step S613 in FIG. 4 and transmits the result determined in step S1309 or S1310 to the vehicle 200.

  By the process of FIG. 11 described above, the update case management unit 112 has the processing load of the telematics center 100 and information corresponding to the update information of the vehicle 200 stored in the telematics center 100, that is, the update case in the vehicle type configuration DB 122. The update software distributed by the update software distribution unit 113 can be managed based on the information of the function category 413 corresponding to. In other words, even when an update case exists for a certain vehicle 200, the update is first performed in consideration of the remaining capacity of the telematics center 100 with the importance of the ECU function targeted by each update case as an axis. It can be determined whether or not to extend. As a result, in a situation where a plurality of update cases are registered in the telematics center 100, the processing load of the telematics center 100 is taken into consideration, and the plurality of update cases are straddled, and the function importance of the ECU to be updated is determined. Update software can be distributed preferentially. Therefore, even when a large number of update cases with low priority are registered, the software update system can be maintained without lowering the infrastructure of the telematics center 100 by lowering the distribution priority thereof.

  In the update case confirmation processing of FIG. 11, the priority may be determined by another method instead of determining by the function category. For example, each update item may be dealt with by separately giving priority information in a form associated with the update item ID 500 of the update item management DB 124. Further, a mechanism for automatically determining the priority based on other information such as the vehicle type ID 401 of the vehicle configuration DB 121 and the file size of the update software instead of the function category may be introduced.

  Furthermore, the processing shown in FIG. 11 may be executed periodically by the telematics center 100 instead of being executed every time there is an inquiry from the vehicle 200 in step S612 of FIG. In that case, the result determined in step S1309 or S1310 may be stored in the storage device 120, and the result may be transmitted from the telematics center 100 to the vehicle 200 in response to an inquiry from the vehicle 200, or from the telematics center 100. The periodically transmitted result may be stored in the storage device 215 in the vehicle 200.

  Furthermore, in the present embodiment, an example has been described in which the update item confirmation process shown in FIG. 11 is executed in step S612 in FIG. However, in addition to this, for example, by executing the update case confirmation process of FIG. 11 in step S615 of FIG. 4, the distribution of the update software is temporarily refused according to the processing load of the telematics center, or the download communication It may be used as a method of narrowing the band. In the first embodiment, the example in which permission from the user is obtained via the input / output device 234 in step S702 in FIG. 5 has been described. However, the portable terminal owned by the user is notified by means such as mail. Permission from the user can also be obtained by a response to this notification. In such a case, when the notification order to the user is determined, the method described with reference to FIG. 11 is used, so that the update case having a high priority based on the function category is notified preferentially. good.

  FIG. 12 is a diagram showing an example of a screen displayed on the input / output device 130 of the telematics center 100 in the third embodiment of the present invention.

  In the graph displayed on the screen 1400 in FIG. 12, the horizontal axis indicates the time, and the vertical axis indicates the processing load of the entire telematics center 100 and the ratio of the processing load for each functional category. Note that the ratio of the processing load for each function category corresponds to the ratio of the count number of each function category calculated in step S1306 in FIG. In this screen 1400, it is assumed that the telematics center 100 executes the update item confirmation processing based on FIG. 11 at a certain time interval, for example, every minute, and displays the calculation result on the input / output device 130.

  On the screen 1400, for example, at time T3, the total processing load ratio of the function categories C1 and C2 is about 50%, whereas the processing load of the entire telematics center 100 is about 65%. The remaining capacity is 35%. For this reason, in the process based on FIG. 11, at time T3, only when the function category of the ECU to be updated is C1, the process branches to Yes in step S1308, and to No in other cases C2-C5. It will be branched. In FIG. 12, the functional category of the ECU to be updated for which the determination result in step S <b> 1308 is No is shaded. That is, for example, at time T3, only the function category C1 is not shaded, and the function categories C2 to C5 are shaded.

  According to the third embodiment of the present invention described above, the update matter management unit 112 of the telematics center 100 is based on the processing load of the telematics center 100 and the update information stored in the telematics center 100. Update software distributed by the software distribution unit 113 is managed (steps S1303 to S1310). Since it did in this way, the distribution management of the software for update from the telematics center 100 to the vehicle 200 can be performed in consideration of the processing load of the telematics center 100.

  Moreover, according to the 3rd Embodiment of this invention demonstrated above, there exist the following effects.

(1) The software update system of this embodiment manages the update of the software of ECU which is the vehicle equipment mounted in the vehicle 200. The software update device 210 mounted in the vehicle 200, and the software update device 210 And a telematics center 100 that performs communication via the network 300. The telematics center 100 includes an update software distribution unit 113 that distributes update software for updating the ECU software to the software update device 210, and an update software distribution unit 113 based on the priority of the ECU software update. And an update item management unit 112 that manages the update software to be distributed. The software update device 210 includes a storage device 215 that stores update software distributed from the telematics center 100, an ECU software update unit 214 that updates the software of the ECU using the update software stored in the storage device 215, Have Since it did in this way, the software update of the vehicle equipment by OTA which is easy to use for a user is realizable.

(2) The vehicle 200 includes a plurality of ECUs having different functions, that is, an engine ECU 240, an ABS ECU 241, a steering ECU 242, a suspension ECU 243, an air bag ECU 244, an automatic operation ECU 245, a keyless entry ECU 246, an air conditioner control ECU 247, and an audio ECU 248. Has been. The update item management unit 112 sets priorities based on the importance of the functions to which the plurality of ECUs belong. Specifically, the plurality of ECUs mounted on the vehicle 200 are grouped into a plurality of function categories, such as function categories C1 to C5, according to the degree of influence on the operation of the vehicle 200, for example. The update matter management unit 112 sets priorities based on the function categories to which the plurality of ECUs mounted on the vehicle 200 belong, respectively (step S1303). Since it did in this way, the priority of each ECU can be set appropriately.

(3) The telematics center 100 includes a storage device 120 that stores a plurality of update software corresponding to a plurality of ECUs mounted on the vehicle 200. The update matter management unit 112 selects at least one of the plurality of ECUs as an update target ECU based on the processing load of the telematics center 100 and the priority of the ECU for software update (steps S1303 to S1310). Specifically, the update matter management unit 112 calculates the processing load of the telematics center 100 required for distribution of the update software for at least one of the plurality of ECUs mounted on the vehicle 200 (step S1304). To S1307). Then, the remaining capacity of the server according to the current processing load of the telematics center 100 is compared with the calculated processing load of the telematics center 100 (step S1308), and an ECU to be updated is determined based on the comparison result (step S1308). S1309, S1310). In step S615, the update software distribution unit 113 distributes the update software corresponding to the ECU to be updated selected by the update case management unit 112 to the software update device 210. Since it did in this way, considering the processing load of the telematics center 100, ECU which updates software can be selected appropriately.

(4) In step S1307, the update case management unit 112 specifies an ECU that is a calculation target of the processing load of the telematics center 100 based on the priority. Since it did in this way, the processing load of the telematics center 100 can be calculated appropriately.

(5) The telematics center 100 can communicate with a plurality of vehicles 200 each equipped with a software updating device 210 via the network 300. In step S 1307, the update case management unit 112 identifies an ECU that is a calculation target of the processing load of the telematics center 100 from among the ECUs mounted on the plurality of vehicles 200. Since it did in this way, ECU used as calculation object of processing load can be specified appropriately from various ECUs carried in a plurality of vehicles 200 with various vehicle types.

  The embodiment and various modifications described above are merely examples, and the present invention is not limited to these contents as long as the features of the invention are not impaired. Moreover, although various embodiment was described above, this invention is not limited to these content. Other embodiments conceivable within the scope of the technical idea of the present invention are also included in the scope of the present invention.

DESCRIPTION OF SYMBOLS 100: Telematics center 110: Central processing unit 111: Configuration information management part 112: Update item management part 113: Update software delivery part 114: Recovery software delivery part 120: Storage device 121: Vehicle configuration DB
122: Vehicle configuration DB
123: Functional configuration DB
124: Update matter management DB
125: Progress management DB
130: Input / output device 140: Communication unit 200: Vehicle 210: Software update device 211: Central processing unit 212: Update item confirmation unit 213: Update software request unit 214: ECU software update unit 215: Storage device 220: Communication unit 230: Navigation terminal 231: Central processing unit 232: Update information display unit 233: Storage device 234: Input / output device 240: Engine ECU
241: ABS ECU
242: Steering ECU
243: Suspension ECU
244: Airbag ECU
245: Automatic operation ECU
246: Keyless entry ECU
247: Air conditioner control ECU
248: Audio ECU

Claims (9)

A software update system comprising a software update device installed in a vehicle and a server that communicates with the software update device via a network, and manages software updates of a control device installed in the vehicle,
The server
An update software distribution unit for distributing update software for updating software of the control device to the software update device;
An update matter management unit for managing the update software distributed by the update software distribution unit based on the priority of the control device for software update;
The software update device includes:
A vehicle-side storage device that stores the update software distributed from the server;
A software update system comprising: a software update unit that updates software of the control device using the update software stored in the vehicle-side storage device. The software update system according to claim 1,
The vehicle is equipped with a plurality of the control devices each having a different function,
The update item management unit is a software update system that sets the priority based on the importance of the function of each of the plurality of control devices. The software update system according to claim 2,
The plurality of control devices are grouped in advance into a plurality of functional categories according to the degree of influence on the operation of the vehicle,
The update item management unit is a software update system in which the priority is set based on the function category to which a plurality of the control devices respectively belong. In the software update system according to claim 3,
The software update system, wherein the server includes a display device that displays the function categories to which a plurality of the control devices respectively belong. In the software update system according to any one of claims 2 to 4,
The server includes a server-side storage device that stores a plurality of the update software corresponding to the plurality of control devices,
The update matter management unit selects at least one of the plurality of control devices as an update target control device based on the processing load of the server and the priority,
The update software distribution unit is a software update system that distributes the update software corresponding to the update target control device selected by the update item management unit to the software update device. The software update system according to claim 5,
The update matter management unit
For at least one of the plurality of control devices, calculate the processing load of the server required to distribute the update software,
A software update system that compares the remaining capacity of the server according to the current processing load of the server and the calculated processing load of the server, and determines the control device to be updated based on the comparison result. The software update system according to claim 6,
The update item management unit is a software update system that identifies a control device as a calculation target of the processing load of the server based on the priority. The software update system according to claim 6 or 7,
The server is capable of communicating with a plurality of the vehicles each equipped with the software update device via the network,
The update item management unit is a software update system that identifies a control device that is a calculation target of a processing load of the server from among the control devices that are respectively mounted on a plurality of the vehicles. A server for managing software updates of a control device mounted on a vehicle,
An update software distribution unit for distributing update software for updating software of the control device to the vehicle;
A server comprising: an update item management unit that manages the update software distributed by the update software distribution unit based on a priority of the control device for software update.

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