DE102012003000A1 - System for diagnosing fault of vehicle, comprises central processing resource, which is configured such that it communicates wirelessly with vehicle, and communication unit, which is fixed in vehicle - Google Patents

Abstract

The system comprises a central processing resource (100), which is configured such that it communicates wirelessly with a vehicle (180), and a communication unit (181), which is fixed in the vehicle for providing information corresponding to the functional condition or operating information of a set of units (185) in the vehicle to receive and to transmit data (DF,DR) to the central processor resource. The central processing resource transmits a set of diagnostic queries through a wireless communication unit (160). Independent claims are also included for the following: (1) a method for diagnosing fault of a vehicle; and (2) a computer program for a computer readable storage unit.

Description

BACKGROUND OF THE INVENTION AND PREFERRED TECHNOLOGY

The present invention generally relates to solutions for fault diagnosis of vehicles. In particular, the invention relates to a system according to the preamble of claim 1 and a method according to the preamble of claim 5. A further subject of the invention is a computer program according to claim 9 and a computer readable medium according to claim 10.

It is generally desired to minimize the times during which a vehicle is in service to perform service and repair work. This is especially true for commercial vehicles, such as trucks and buses, for which a maximum degree of utilization is desired. Therefore, today there are various solutions to detect any defects in a vehicle remotely and remedy if possible remotely. Even if a defect can not be resolved locally, it is usually an advantage to be able to detect a defect before the affected vehicle is brought to a workshop or before a repairer goes to the affected vehicle. As a result, the repair can be prepared so that the operation interruption time can be minimized.

US 2005/0251304 and US 2006/0122748 describe examples of technical solutions that can be used to remotely diagnose a vehicle from a central location.

In addition, it presents JP 2009-150798 a remote diagnosis system in which a storage unit in a vehicle locally stores state information and any error codes. The locally stored information is then transmitted to a server, for example via a wireless connection, for processing and creating a fault diagnosis. This relieves the data processing resources in the vehicle.

US 7,668,643 provides a system in which data describing the exhaust emissions of a vehicle are stored locally in the affected vehicle. This data is then transmitted wirelessly to a remote server to assess the vehicle's exhaust system and to diagnose any defects therein. This makes it easy to control compliance with regulatory requirements for the emission of polluting gases and particulates.

PROBLEMS IN THE PRIOR ART

The known solutions for the remote diagnosis of vehicles, however, are problematic, inter alia, for the reasons mentioned below. Either the vehicle transmits only an error code (or a simple status list) to a central server or a direct communication link between the vehicle and the central server is required. In the first case mentioned above, the possibilities for a thorough analysis of the condition of the vehicle are very limited. In the above-mentioned second case, the analysis of the vehicle state requires an alternate exchange of information between the central server and the vehicle. The outcome of a particular question is critical to deciding which question to ask next, and so on. Such a policy may be difficult to accomplish due to insufficient quality and / or capacity of the communication link between the server and the vehicle. This connection is often made via a wireless interface. If the communication link between the server and the vehicle is interrupted in at least one direction (for example, when the vehicle is decommissioned), the procedure may be temporarily unworkable. If the procedure is resumed after that, further delays may occur due to re-initiation, etc.

SUMMARY OF THE INVENTION

The object of the present invention is to provide a solution which alleviates the above-mentioned problems and thereby enables a more effective, flexible and stable remote diagnosis of a motor vehicle.

According to one aspect of the invention, the object is achieved by the system described in the introduction, wherein the central processor resource is configured to transmit a set of diagnostic questions to a selected vehicle via a wireless communication link. The communication device in the selected vehicle is also configured to receive the above set of diagnostic questions and, in response to an accepted set of diagnostic questions, cause execution of each diagnostic question of the above set. The respective resulting response data are generated. The communicator is configured to assemble the above resulting response data and the above set of diagnostic questions into a diagnostic file. Alternatively, the communication organ provides identification data for the diagnostic questions and above resulting response data in a diagnostic file together. In any case, the communication device is configured to initiate the transmission of the diagnostic file after its compilation over the wireless communication link to the central processor resource.

This system is advantageous because it does not require a direct connection between the central processor resource and the communication device in the vehicle. In addition, several diagnostic questions can be edited in the vehicle at the same time. By capturing the diagnostic questions and the resulting response data in the diagnostic file (either directly or through a unique identifier), there is no risk of misunderstanding and a retry if the diagnostic file is received relatively late after the Diagnostic issues arrive at the central processor resource (for example, because the vehicle was out of service).

According to one embodiment of this aspect of the invention, the central processor resource and the communication device are configured for asynchronous communication. As a result, neither the central processor resource from the communication organ nor the communication device from the central processor resource requires a message within a certain response time. Consequently, it is not necessary to reserve transmission resources between the central processor resource and the communication organ. In addition, there is no danger that the communication procedure terminates because of an unanswered or delayed response.

According to another embodiment of this aspect of the invention, the central processor resource is configured to generate a later set of diagnostic questions for a selected vehicle based on a diagnostic file previously obtained from that selected vehicle. This allows the central processor resource to progressively refine the vehicle's diagnosis based on the outcome of earlier diagnoses.

According to another embodiment of this aspect of the invention, the central processor resource is connected to a memory unit configured to store the diagnostic questions in the above-mentioned earlier-received diagnostic file along with the associated resulting response data. This is advantageous because the central processor resource can thereby maintain a complete history of all diagnostic questions for all vehicles, so that even extremely lengthy diagnostic procedures can be accomplished without re-polling being required.

According to another embodiment of this aspect of the invention, the communication device in the above-mentioned selected vehicle is configured to cause the execution of each diagnostic question in the above-later-transmitted set of diagnostic questions, generating the respective later resulting response data. The communication device is also configured to assemble the above-mentioned later resulting response data and the later-referenced set of diagnostic questions (or diagnostic questions) into a later diagnostic file, and transmit the above-mentioned later diagnostic file to the central processor resource over the wireless communication link causes. This ensures that the central processor resource is kept up-to-date with the transmitted diagnostic questions and associated response data.

According to another aspect of the invention, the purpose is achieved by the method described at the beginning of the present document wherein a set of diagnostic questions is communicated from the central processor resource to the vehicle via a wireless communication link. In response to the input of the above-mentioned set of diagnostic questions in the communication organ, each diagnostic question is executed in the above-mentioned sentence in the vehicle, generating the respective resulting response data. The communication device compiles the above resulting response data and the above-mentioned set of diagnostic questions (or characteristics for the diagnostic questions) in a diagnostic file and transmits the diagnostic file via the wireless communication link to the central processor resource. The advantages of this method and the preferred embodiments of this method can be seen from the above description with reference to the proposed system.

According to a further aspect of the invention, the purpose is achieved by a computer program that can be downloaded directly into the internal memory of a computer and that contains software for controlling the steps according to the method proposed above when this program is executed in a computer.

According to another aspect of the invention, the purpose is achieved by a computer readable medium having a program stored thereon that enables a computer to control the steps according to the method proposed above.

DRAWING SUMMARY

The present invention will now be explained in detail by means of embodiments described as examples and with reference to the accompanying drawings.

shows a schematic of a proposed remote diagnostic system.

illustrates by way of example the principle of the remote diagnosis method according to embodiments of the invention.

Fig. 12 shows a flowchart of the general method according to the invention, which is performed by the proposed central processor resource.

shows a flow chart of the general method according to the invention, which is performed by the proposed communication body in each vehicle.

DESCRIPTION OF EMBODIMENTS OF THE INVENTION

First up referring to a scheme of a proposed system for remote diagnostics of vehicles. The system includes a centralized processor resource 100 and one in the affected vehicle 180 located communication body 181 ,

The central processor resource 100 is configured to be wireless with at least one vehicle 180 via at least one wireless communication link 160 communicated. Preferably, the connection belongs between the central processor resource 100 and the vehicle 180 also a fixed communication network 150 / several fixed communication networks 150 to which the central processor resource 100 connected.

The communication organ 181 receives information about a health state and / or operational information regarding a set of devices 185 in vehicle 180 , such as with respect to so-called ECU (= Electronic Control Unit / s = electronic control unit (s)), which can each be set up so that they one / more components and / or function / s in the vehicle 180 can control. Either is the communication organ 181 directly to an in-vehicle network, such as a CAN bus, connected to which the units 185 belong, or the communication organ 181 communicates with the units 185 via at least one unit in between 182 such as an interface unit (CAN Controller Area Network). The communication organ 181 also transmits data regarding the health of the devices 185 and / or operational information regarding these units to the central processor resource 100 , The central processor resource 100 is specifically configured to issue a set of DR diagnostic questions over the wireless communication link 160 to the vehicle 180 to convey. Conveniently, the vehicle 180 selected based on a unique identity (for example, an IP address or a phone number).

The communication organ 181 of the selected vehicle 180 is configured to accept the above-mentioned set of diagnostic questions DR and to go through the procedure described below in response to an accepted set of diagnostic questions DR. First, the execution of the individual diagnostic questions is initiated in the above-mentioned set of diagnostic questions DR. In each case, the resulting response data is generated, whereby a response is normally given for each diagnostic question. However, complicated diagnostic questions can lead to relatively large answers. Of course, each diagnostic question may contain a multi-step question sequence. In any case, the communication organ 181 the above-mentioned resultant response data and the above-mentioned set of diagnosis questions DR in a diagnosis file DF containing information about the questions asked and the answers thereto. Last, the communication organ causes 181 the transmission of the diagnostic file DF to the central processor resource 100 over the wireless communication link 160 , This transmission takes place either directly with the communication organ 181 or via one / more intervening unit (s), for example via a radio interface, to the wireless communication link 160 is adjusted.

The central processor resource 100 is advantageously to a first database 120 connected, the information about several vehicles 180 contains, for example, belong to a vehicle fleet. The information in the first database 120 In addition to the above unique vehicle IDs, it is useful to include known information about the equipment and functionality of the vehicles 180 ,

To minimize the amount of data sent by the communication device 181 to the central processor resource 100 can be transmitted in the first database 120 Advantageously, identification information for the diagnostic questions DR are stored, which were transmitted to the individual vehicles, so that the central processor resource 100 based on this identification information the relevant diagnostic questions DR can derive. In this way, it can be avoided that the diagnosis questions DR themselves become the central processor resource 100 be sent back.

Moreover, it is advantageous that the central processor resource 100 Access to a second database 130 which contains data for creating adequate diagnostic questions DR.

It is also preferred that the central processor resource 100 is configured to work in accordance with the instructions of a software residing in the processor resource 100 is performed. Therefore it is advantageous that the central processor resource 100 has a memory module M or is connected to a memory module M containing the software which, when stored in the central processor resource 100 is executed causes the above-described procedure to be performed.

Preferably, the central processor resource 100 and the communication organ 181 for asynchronous communication via the wireless communication link 160 configured. This means that neither the central processor resource 100 from the communication organ 181 still the communication organ 181 from the processor resource 100 requires a message within a certain response time. By contrast, in so-called synchronous communication, for example, an abort signal is often generated when the receiver unit does not receive a response within the prescribed response time. Consequently, during this response time, the receiver unit must wait for a response that may never come. This waiting is avoided by the proposed asynchronous communication procedure. Instead, every message contains the communication organ 181 always both information regarding the diagnosis questions DR and the associated response data. The communication from the communications body 181 contains either the diagnostic questions DR itself or contains the above-mentioned identification information for the diagnostic questions DR, based on the central processor resource 100 can derive the relevant diagnostic questions DR. The last-mentioned solution is of course advantageous since it contains the amount of data in the message from the communication organ 181 is relatively low.

In addition, the central processor resource 100 to a storage unit 120 in which former diagnostic questions DR are stored together with the associated resulting response data. This will avoid having an active session in the affected units, ie in the vehicle 180 and in the central processor resource 100 , must be maintained.

The proposed principle for the remote diagnosis method according to embodiments of the invention will now be described with reference to an illustrative example in FIG explained. Left in is the flow in the central processor resource 100 shown during the flow in the communication organ 181 is illustrated on the right.

First, the central processor resource is generated 100 a set of diagnostic questions dr1, dr2, ..., dri, the communication organ 181 be transmitted in a selected vehicle. The diagnostic questions dr1, dr2,..., Dri are then executed there and then a resulting set of response data a1, a2,..., Ai is generated there. These data are from the communication organ 181 with the diagnostic questions dr1, dr2, ..., dri in a first diagnostic file DF1 compiled to the central processor resource 100 is transmitted. Because more information is required to create an adequate diagnosis of the vehicle, the central processor resource generates 100 on the basis of the received diagnostic file DF1, a second set of diagnostic questions dr (i + 1), ..., drj, to the communication organ 181 is transmitted. After the receipt of this second sentence in the communication organ 181 the second set of diagnostic questions dr (i + 1),..., drj is carried out analogously to the procedure described above, wherein a resulting set of response data a (i + 1),..., aj assigned to this diagnostic query set is generated. Normally, the procedure then continues, so that a later set of diagnostic questions for the vehicle is generated based on information from at least one diagnostic file previously obtained from the vehicle. The central processor resource 100 continuously stores the contents of each received diagnostic file until the central processor resource 100 decides that an adequate diagnosis can be made for the affected vehicle. At the in In the example shown, this situation is reached when a diagnostic file DFp has been received containing information regarding the diagnostic questions dr (k + n + 1), ..., drm and the associated resulting sets of responses thereto to a (k + n + 1). , ..., am.

Now, in summary, the general method according to the invention, that of the central processor resource 100 and the communication organ 181 is carried out with reference to the flowchart in respectively. described.

First, in a first step 310 the procedure of the central processor resource 100 a set of diagnostic questions DR, used to diagnose a selected vehicle 180 serve, generated and to this selected vehicle 180 transmitted. In a subsequent step 320 it is checked if a diagnostic file DF with the above called set of diagnostic questions from the vehicle 180 was obtained. If so, a step follows 330 , Otherwise, the procedure returns to step 320 back and stay there. In step 330 It examines whether the diagnostic file DF provided the desired information or if further information is required to enable the central processor resource 100 an adequate diagnosis of the vehicle 180 can create. In practice, this is a relatively complicated analysis involving various decision-making steps. However, these decision-making steps are to preserve the clarity in not shown. When in step 330 If the available information is found to be sufficient, the procedure is terminated. Otherwise, follow step 340 , In this case, a set of diagnostic questions DR is generated and the vehicle 180 then the procedure goes to step 320 returns.

In a first step 410 the procedure of the communication organ 181 in the vehicle 180 a check is made as to whether a set of diagnostic questions DR has been received. If so, a step follows 420 , Otherwise, the procedure returns to step 410 back and stay there. In step 420 For example, the individual diagnostic questions are executed in the above-mentioned sentence DR, with the associated resulting response data being generated. The abovementioned response data are compiled with the above-mentioned set of diagnostic questions DR (or diagnosis data for the diagnostic questions) in a diagnostic file DF, which in a subsequent step 430 to the central processor resource 100 is transmitted. Thereafter, the procedure returns to step 410 back.

The reference to and described method steps can be controlled with a programmed computer. While the embodiments of the invention described above with reference to the drawings incorporate a computer and computer-implemented processes, the invention extends to a computer program, and more particularly to a computer program on or within a carrier useful in practicing the invention , The program may be implemented as source code, as object code, as a middle code between a source code and an object code, for example in partially compiled form, or in any other suitable form to be used to implement the process according to the invention. The carrier can be any unit or device that can be used as the carrier medium for the program. The carrier may include a storage medium such as a flash memory, a ROM (Read Only Memory), a CD (Compact Disc), a semiconductor ROM, an EPROM (Electrically Programmable ROM), an EEPROM (Erasable EPROM), or a magnetic storage medium such as a floppy disk or a hard disk. In addition, the carrier may be a transmittable medium, such as an electrical or optical signal transmitted via an electrical or optical cable, or by radio or otherwise. If the program carrier is a signal transmitted directly by cable or other device or organ, the carrier may be such a cable, device or organ. Alternatively, the carrier may be an integrated circuit in which the program is embedded and which may be used to execute or execute the relevant processes.

The invention is not limited to the embodiments described with reference to the figures, but may be freely varied within the scope of the following claims.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2005/0251304 [0003]
• US 2006/0122748 [0003]
• JP 2009-150798 [0004]
• US 7668643 [0005]

Claims (10)

System for diagnosing a vehicle ( 180 ) with: a central processor resource ( 100 ) that is configured to connect wirelessly to at least one vehicle ( 180 ), and one in the vehicle ( 180 ) communication device ( 181 ), which serves to provide information regarding a functional status and / or operating information of a set of units ( 185 ) in the vehicle ( 180 ) and receive data (DF, DR) relating to the above-mentioned functional state and / or operating information to the central processor resource ( 100 ), characterized in that the central processor resource ( 100 ) is configured to communicate over a wireless communication link ( 160 ) a set of diagnostic questions (DR) to a selected vehicle ( 180 ) and that the communication body ( 181 ) of the selected vehicle ( 180 ) is configured to accept the above-mentioned set of diagnostic questions (DR) and, in response to an accepted set of diagnostic questions (DR), cause the execution of each diagnostic question (dr1, ..., dri) in the above-mentioned sentence (DR) generates the respective resulting response data (a1, ..., ai), the above-mentioned resultant response data (a1, ..., ai) and the above-mentioned set of diagnostic questions (DR) or identification data for the above-mentioned set of diagnostic questions (DR) a diagnostic file (DF) and transfer the diagnostic file (DF) to the central processor resource ( 100 ) via the wireless communication link ( 160 ). The system of claim 1, wherein the central processor resource ( 100 ) and the communication organ ( 181 ) are configured for asynchronous communication so that neither the central processor resource ( 100 ) from the communication organ ( 181 ) nor the communication organ ( 181 ) from the central processor resource ( 100 ) requires a message within a certain response time. A system according to any one of the preceding claims, wherein the central processor resource ( 100 ) is configured to generate a later set of diagnostic questions (dr (i + 1), ..., drj) for a selected vehicle ( 180 ) based on at least one of this vehicle ( 180 ) generated earlier diagnostic file (DF1). The system of claim 3, wherein the central processor resource ( 100 ) to a storage unit ( 120 ) configured to answer the diagnostic questions (dr (i + 1), ..., drj) together with the associated resulting response data (a (i + 1), ..., aj) in the above stores the previously received diagnostic file (DF1). Method for diagnosing a vehicle ( 180 ), where the vehicle ( 180 ) a communication organ ( 181 ), which serves to provide information regarding a health status and / or operational information of a set of entities ( 185 ) in the vehicle ( 180 ) and receive data (DF, DR) relating to the above-mentioned functional state and / or operating data to a central processor resource ( 100 ), characterized by: transmitting a set of diagnostic questions (DR) from the central processor resource ( 100 ) to the vehicle ( 180 ) via a wireless communication link ( 160 ), Receiving the above-mentioned set of diagnostic questions (DR) in the communication device ( 181 in the vehicle, and in response thereto, executing each diagnosis question (dr1, ..., dri) in the above-mentioned sentence (DR), thereby generating the respective resulting response data (a1, ..., ai), compilation of the above-mentioned resultant response data ( a1, ..., an) and the above-mentioned set of diagnostic questions (DR) or of identification data for the above-mentioned set of diagnostic questions (DR) in a diagnostic file (DF) and transmission of the diagnostic file (DF) to the central processor resource ( 100 ) via the wireless communication link ( 160 ). Method according to claim 5, which comprises an asynchronous communication between the central processor resource ( 100 ) and the communication body ( 181 ) and where neither the central processor resource ( 100 ) from the communication organ ( 181 ) nor the communication organ ( 181 ) from the central processor resource ( 100 ) requires a message within a certain response time. Method according to one of claims 5 or 6, which comprises the generation of a later set of diagnostic questions (dr (i + 1), ..., drj) in the central processor resource ( 100 ) for a selected vehicle ( 180 ) based on at least one of this vehicle ( 180 ) contains previously received diagnostic file (DF1). Method according to claim 7, comprising the storage of diagnostic questions (dr (i + 1), ..., drj) in the above-mentioned previously received diagnostic file (DF1) together with the associated resulting response data (a (i + 1), .. ., aj) in a memory unit ( 120 ) to the central processor resource ( 100 ) connected. A computer program downloadable directly into the internal memory (M) of a computer and including software for controlling the steps of any one of claims 5 to 8 when said program is executed in a computer. A computer readable medium (M) having a program stored thereon enabling a computer to control the steps of any one of claims 5 to 8.

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