EP1994723A1

EP1994723A1 - Data communication method using a communication subscriber that is situated in a motor vehicle with dynamic address allocation

Info

Publication number: EP1994723A1
Application number: EP07711819A
Authority: EP
Inventors: Guenter Bruenner; Martin Baumgartner; Klaus Rebhan
Original assignee: Bayerische Motoren Werke AG
Current assignee: Bayerische Motoren Werke AG
Priority date: 2006-03-13
Filing date: 2007-03-07
Publication date: 2008-11-26
Also published as: DE102006011829B4; WO2007104453A1; US20090070488A1; DE102006011829A1; US8677019B2

Abstract

The invention relates to a data communication method between a first communication subscriber that is situated in a motor vehicle and a second communication subscriber that is situated outside the motor vehicle. According to said method, the first communication subscriber can be addressed by the second communication subscriber by means of a network address. In said method, the network address of the first communication subscriber is defined by an address management unit situated outside the motor vehicle and is transmitted to the first communication subscriber.

Description

METHOD FOR DATA COMMUNICATION WITH A COMMUNICATION PARTICIPANTS PARTICIPATING IN A MOTOR VEHICLE WITH DYNAMIC ADDRESS AWARD

The invention relates to a method for data communication between a first communication station arranged in a motor vehicle and a second communication station arranged outside the motor vehicle, in which the first communication station can be addressed by the second communication station by means of a network address.

Various methods for data communication between a first communication station arranged in a motor vehicle and a second communication station arranged outside the motor vehicle are known from the prior art. For connecting the motor vehicle with an external or outside the motor vehicle arranged communication participants is usually a bus system in the form of a so-called OBD access (OBD = on-board diagnostics) is used.

Such OBD access allows a point-to-point connection to an outside of the motor vehicle arranged communication participants, however, brings some disadvantages. The amount of transferable data rates is limited and relatively low due to the bus system. For the data transfer special hardware is required, which brings additional costs. In addition, a separate communication infrastructure must be set up. Furthermore, it is only possible to communicate with a single communication partner at a time.

Various approaches are known from the prior art, technologies that have become standard in other technical fields to use for methods of the type mentioned. For example, it is known to provide an Ethemet interface in the motor vehicle and, using an Ethernet connection, to exchange data between a first communication station arranged in a motor vehicle and a second communication station arranged outside the motor vehicle. A special variant of such a process is described in WO 2005/076103 A2. A disadvantage of all known methods of this type, however, is that they go hand in hand with a high level of technical complexity, since usually completely separate additional communication mechanisms must be provided either on the vehicle side parallel to the previous OBD interface or existing communication structures (eg CAN bus) through corresponding devices and methods for interface adaptation must be extended.

In addition, in the known from the prior art method of the type mentioned the disadvantage that no unique addressing of a large number of motor vehicles is possible because the number of available in a network or sub-network addresses usually limited is.

The object of the invention is to provide a simple method for data communication between a first arranged in a motor vehicle communication subscriber and a second arranged outside the motor vehicle communication subscriber, which allows the addressing of a large number of motor vehicles.

This object is achieved by a method according to claim 1. Preferred embodiments and advantageous developments of the invention will become apparent from the dependent claims.

According to the invention, the network address of the first communication subscriber is determined by an address management unit arranged outside the motor vehicle and transmitted by the address management unit to the first communication user. This enables dynamic address assignment. The first communication user can be addressed by means of the dynamically assigned network address for other communication users.

Preferably, the network address is assigned to a central gateway (ZGW) of the motor vehicle, via which the entire data communication of the motor vehicle runs to the outside or from the outside. Since usually only a single such ZGW is present in the motor vehicle, the assigned network address then effectively refers to the motor vehicle as such. So it is the motor vehicle itself by means of him dynamic allocated network address for other communication participants, such as a diagnostic tester, addressable. The ZGW is in such a case the first communication participant within the meaning of the invention.

In principle, several network users arranged in a single motor vehicle can also be assigned a network address. However, this case is not considered here without restriction of the general public.

In the case of dynamic address allocation, as is made possible by the invention, a motor vehicle to be integrated into a network is not assigned a permanently unique network address of its own. Rather, one and the same network address can be assigned at different times to different motor vehicles. The address assignment is then comparable to that in a for other technical areas already known from the prior art DHCP server (DHCP = Dynamic Host Configuration Protocol).

A network address assigned to a motor vehicle need only be unique within the respective network. The number of available network addresses of a network, which is usually limited, then only needs to be sufficiently large that all motor vehicles that are to be integrated simultaneously in the network, different network addresses can be assigned. Non-unique network addresses must be available to all potentially in-network vehicles.

Preferably, the address management unit is designed as a DHCP server. This offers the advantage that state-of-the-art and reasonably priced devices and methods for implementing the invention can find application.

According to a preferred embodiment of the invention, for requesting a network address, a request message containing a unique vehicle identifier of the motor vehicle is transmitted to the address management unit by a communication user arranged at the motor vehicle, for example the ZGW. Preferably, the request message essentially consists of the unique vehicle identifier itself. In principle, the request message can also be provided by a the communication device arranged the motor vehicle are sent, which is not identical to the first communication participant in the sense of the invention. Preferably, however, the request message is sent by the ZGW.

By sending the request message, a motor vehicle can effectively log on to the network as soon as it is physically connected to it. He is then assigned a network address, through which it is addressable for other network participants. Instead of a request message that contains a vehicle identifier or consists essentially in this vehicle identifier, any other request message can in principle be sent for this purpose. However, it offers advantages if a unique vehicle identifier is known by the address management unit. Namely, an association between the unique vehicle identifier and the assigned network address is made possible.

Preferably, assignment data for the association between the unique vehicle identifier sent for the request and the subsequently determined network address are stored in the address management unit.

This makes it possible, even with dynamic address assignment to clearly determine which motor vehicle is assigned which network address. The storage can be done for example in list or table form. Preferably, the assignment is also possible with hindsight, i. It can be determined which motor vehicle was assigned to which network address. For example, for each ever or in a certain period of time integrated into the network motor vehicle, a network history are stored at the address management unit, which documents at what time the motor vehicle or its vehicle identifier which network address was assigned.

The address management unit is predestined, due to the fact that it assigns the network addresses to motor vehicles integrated in the network, to store such assignment data for later use, for instance for the possibility of interrogation by a network subscriber. The address management unit can therefore also fulfill the task of an address switching unit, in which the network identifier belonging to a vehicle identifier can be queried by other communication users. However, according to a preferred embodiment of the invention, the functionality of the reproduction of assignment data is shifted to a separate address switching unit executed separately by the address management unit on request of a network participant. Preferably, assignment data for the association between the unique vehicle identifier sent for the request and the subsequently determined network address are stored in an address switching unit in which the network address belonging to a vehicle identifier can be interrogated by other communication users. For this purpose, the assignment data can be transmitted from the address management unit to the separately executed address switching unit.

The reproduction of assignment data by the address switching unit is then comparable to the functionality of a DNS server already known from the prior art for other technical areas (DNS = Domain Name Server). Preferably, the address switching unit is designed as a DNS server. This offers the advantage that state-of-the-art and reasonably priced devices and methods for implementing the invention can find application.

The unique vehicle identifier is preferably the chassis number of the motor vehicle. The chassis number is a widely used and proven identifier for identifying a motor vehicle. From the prior art methods and devices are known to store the chassis number of a motor vehicle in data form in the motor vehicle and possibly output communication technology.

The determination or assignment of the network address by the address management unit can also be carried out according to a preferred embodiment of the invention depending on the vehicle identifier. The assigned network address may, for example, depend on the vehicle identifier in such a way that a certain vehicle is preferably allocated a specific network address, for example a network address which has already been allocated to the same vehicle earlier.

Preferably, in the invention, the communication between the first and the second communication subscriber via a standard interface, in particular an Ethernet interface. The communication between the first and the second communication subscriber preferably takes place via a standard protocol, in particular TCP / IP. The assignment according to the invention of a network address, for example an IP address, allows the use of most modern network technologies and the associated devices and methods. The uses of standard devices and methods usually brings great cost advantages and high reliability, especially in high volumes. In addition, very high data rates are transferable. For example, a data transmission via Ethernet with up to twenty times the data rate compared to OBD.

Using the respective communication technology, the invention allows a comfortable addressing of all communication users. If the communication technology used so provides, the simultaneous communication of a communication subscriber with several other communication participants is also possible. Thus, the integration of vehicles into a network according to the invention, in particular an Ethernet network, allows a diagnostic tester to communicate simultaneously with a plurality of vehicles and / or for a plurality of diagnostic testers to communicate simultaneously with a vehicle.

According to a preferred embodiment of the invention, an input data stream transmitted by the second communication user during data communication is converted on the vehicle side in the first communication user into a diagnostic data stream in the data format of a conventional diagnostic communication by means of a vehicle access application. The diagnostic data stream is therefore reconstructed on the vehicle side.

It is advantageous in this case to modify the structures of a conventional OBD access, which are usually already present today and often prescribed by law, as little as possible both on the vehicle side and on the side of the second communication subscriber, for example a diagnostic tester.

The diagnostic messages present in the second communication subscriber, for example a diagnostic tester, in the data format of a conventional diagnostic communication, ie in the conventional diagnostic message format, are therefore preferably only preprocessed, for example packetized, in the diagnostic tester by means of the selected standard technology, for example TCP / IP over Ethernet, to that first communication participants can be transmitted. During preprocessing, the data only has to be viewed up to the transport level (and above). The data processing in the lower communication levels is done by the standard components of the standard technology used. The data stream arriving at the first communication station is converted back into the diagnostic message format by the corresponding processing steps of the vehicle access application which are inverse to the preprocessing. Here, too, the consideration can be limited to the transport level. As a result, in the case of the first communication participant, the same diagnosis messages are present which were initially present on the other side of the communication connection at the second communication participant. The thus reconstructed diagnostic data stream can then be further processed in the same manner on the vehicle side, as is known from conventional diagnostic communication. It is thus a very simple vehicle-side implementation of the method possible in which hardly or no vehicle components must be changed.

Since the diagnostic messages present at the second communication subscriber need only be adapted to the transmission technology used and must be at the end of the transmission link at the first communication participant, the described method provides a very slim transmission protocol with very low overhead for the transmission of standardized diagnosis messages. Thus, standard diagnostic messages can be transferred without delay, secured, without large intermediate buffers in the vehicle and out of the vehicle. Preferably, a multiplexer (control bytes) allows the extension to other types of data as diagnostic messages.

Preferably, the OBD access, in particular the OBD connector, of the motor vehicle can continue to be used in a conventional manner. In the simplest case, a separate connection is provided for the other communication technology used, eg Ethernet. According to a particularly preferred embodiment of the invention, however, free contacts of the OBD connector are used, to which the signals of the other communication technology used, eg Ethernet, are launched. It must then be provided no additional connector. The conventional OBD connection and the additional communication connection, eg Ethernet, are combined in one plug-in connection. It This saves the cost of additional connectors. It also eliminates the time and expense of actually plugging multiple plugs.

For in-vehicle distribution of the signals of different data ports (e.g., conventional OBD port and Ethernet), a gateway unit similar to the CFFS described in WO 2005/076103 A2 can be used on the vehicle side.

According to a development of the invention, the unique vehicle identification of the motor vehicle can also be queried by a network subscriber arranged outside the motor vehicle. Preferably, for this purpose, a query message is sent to the network address assigned to the motor vehicle by the querying network subscriber. The motor vehicle responds to this query message with a response message containing the unique vehicle identifier of the motor vehicle. It is also a non-directional query of all vehicles in a network or network segment by means of broadcast possible (for example, request on the broadcast address, all vehicles in a subnet answer).

The querying network subscriber can basically be any other network subscriber, for example another motor vehicle integrated in the network. The query can also be linked to the condition of an authorization. The query can be permitted, for example, only those network users who have a separate authorization to do so.

The polling network participant may also be a network-side vehicle detection service. In this case, based on the received vehicle identifications of various vehicles, a list of several, preferably all, current or ever or in a certain period registered in the network motor vehicles are created. This can be advantageous, for example, for documentation purposes in vehicle production or vehicle service.

Purpose of the query of the vehicle identifier by the querying network subscriber may be to allow an association between vehicle identifiers and network addresses. The list of a vehicle recognition service preferably also permits an assignment between the vehicle identifiers and one or more assigned network addresses. Such an association between the network address and the received vehicle identifier is generally easily possible for the querying network subscriber if the latter has previously addressed the respective motor vehicle deliberately via its network address and has then received the vehicle identifier as an immediate response. Nevertheless, it may be advantageous if, in addition to the vehicle identifier, the network address is also transmitted to the polling network subscriber. The assignment can be further simplified. Moreover, the network subscriber receiving the vehicle identification, for example a vehicle recognition service, can thereby also make an association between the network address and the vehicle identification in cases in which the vehicle identification has been sent to him unsolicited or at the request of another network subscriber. For example, it may be advantageous for a motor vehicle, after the assignment of a network address by the address management unit, to automatically transmit its unique vehicle identifier together with the assigned network address to a vehicle recognition service. If this is done in such a way for all motor vehicles registered on the network, the vehicle recognition service is fully informed about the association between network addresses and vehicle identifications. As another example, in the case where the vehicle identification is sent unsolicited or at the request of another network participant to a vehicle detection service, it is also conceivable that a query without detailed consideration of the respective network address is sent to all currently registered in the network vehicles.

Such a vehicle detection service, as described above, is preferably provided in addition to an address management unit and possibly an address switching unit. It can also completely or partially fulfill the task of an address switching unit if the assignment list of the vehicle recognition service allows an association between vehicle identifications and network addresses which can be interrogated by other communication users. An address switching unit may also serve for queries of the type which network address is assigned to which vehicle identification, while a vehicle recognition service is used for queries of the type which motor vehicle is currently integrated in a network. The possibility of direct query or controlled by another event output of the vehicle identifier access to an address management unit or an address switching unit can be avoided if such a unit is overloaded, unavailable or failed.

It is also possible to connect a diagnostic tester directly (without network) to the motor vehicle. In the case of such a direct connection of motor vehicle and diagnostic tester, the direct query of the vehicle identifier can also be used to determine the vehicle identifier by the diagnostic tester.

In a particular case, it may also be simpler for a network subscriber to make a direct query of the unique vehicle identifier with a current or potential communication partner than to inquire with the address management unit or the address switching unit. Furthermore, network subscribers who are not authorized to query the assignment data of the address management unit or of the address switching unit can be given the option of querying the unique vehicle identifier of a current or potential communication partner in individual cases.

It should be noted that the possibility of direct query of the vehicle identifier can also be advantageous regardless of the invention in the method of the type mentioned.

The second communication subscriber according to the invention is designed according to a preferred embodiment of the invention as a diagnostic tester. The diagnostic tester can then address a motor vehicle with which it is to be connected, for example for diagnostic purposes, using its network address. If only the vehicle identifier of the motor vehicle is known in the diagnostic tester, the current network address assigned to the vehicle identifier can optionally be queried by an address switching unit. If a vehicle recognition service is available, it may also be requested by the diagnostic tester at the vehicle recognition service whether the relevant motor vehicle is currently integrated in the network. A preferred embodiment of the invention will be described in more detail below with reference to the drawings. The drawings show each schematically

1 shows the communication-technical layers of a diagnostic message to be sent,

Fig. 2 shows the essential processing steps of a preferred embodiment of a vehicle access application and

3 shows the essential signal flows in a preferred embodiment of a method according to the invention.

3 shows the essential signal flows in a preferred embodiment of a method according to the invention. The central gateway (CCW) 1 of a motor vehicle communicates with a diagnostic tester 2 for diagnostic purposes. The diagnostic communication is shown by arrow 3. The diagnostic communication takes place via an Ethemet connection.

For communication in the network, the vehicle is assigned an IP address.

It should be a variety of different vehicles with the diagnostic tester 2 connectable. Due to the large number of vehicles, the assignment of the IP address must be done dynamically. In the present case, the vehicle is assigned an IP address by the DHCP server 5 when the vehicle is connected to the network. In this process, the vehicle transmits its chassis number, also called VIN (vehicle identification number) (arrow 6), to the DHCP server 5. The DHCP server tells the vehicle or the CCW 1 in return an IP address (arrow 7).

In addition, the DHCP server 5 assignment data for assignment between VIN and assigned IP address to a not specifically graphically represented DNS server on. The DNS server is thus later able to output the network address to a specific chassis number. For the identification of the vehicle in the network two independent mechanisms are provided. First, an identification via the DHCP server 5 and the above-mentioned DNS server.

On the other hand, a vehicle detection service 4 is provided on the network side. After the IP address has been assigned, the ZGVV 1 of the vehicle sends by broadcast (arrow 8) the chassis number of the vehicle to the network-side vehicle recognition service 4. This broadcast 8 is received and evaluated by the network-side vehicle recognition service 4. The network-side vehicle recognition service 4 uses the received chassis numbers to create a list of all vehicles currently connected to the network with chassis number and IP address.

The ZGW 1 of the vehicle also provides on separate external query (arrow 9) the chassis number of the vehicle to the network-side vehicle detection service. 4

The function of the component VCM 10 (Vehicle Configuration Management) likewise shown in FIG. 3 and connected to the ZGW 1 is essentially known from the prior art. The function VCM 10 provides the chassis number in this example. The component UGW 11 likewise shown in FIG. 3 and connected to the ZGW 1 essentially corresponds to a CFFS known from WO 2005/076103 A2. Unlike FIG. 3, functions VCM 10 and UGW 11 may also be performed by ZGW 1.

FIG. 1 and FIG. 2 show details of the diagnostic communication 3 between the ZGW 1 and the diagnostic tester 2.

Fig. 1 shows the communication-technical layers of a diagnostic message to be sent. Initially, the diagnostic message is present as such (layer "application") in the diagnostic tester For packaging, each diagnosis message is provided with a header (packet header, layer "packetization"). For transport via the Ethemet connection, several diagnostic messages, including the respective packaging headers, are provided with a TCP header. The result is a data stream at the transport level ("Transport" layer), a special consideration of the preprocessing of the items to be sent Diagnostic data in the diagnostic tester only needs to be up to the transport level (and above). The data processing in the lower communication levels (layers "Internet" and "Data Link" in Fig. 1) is handled by standard Ethernet components integrated into the diagnostic tester.

The data stream at the transport level is transmitted to the CCW 1 of the motor vehicle by means of the Ethemet connection.

2 shows the essential processing steps of a vehicle-side vehicle access application. The vehicle access application 200 is executed by the ZGW 1. FIG. 2 shows, inter alia, the processing of the data stream arriving via the Ethemet connection, which arrives on a diagnostic port 100 of the vehicle access application 200.

Also in the vehicle, in particular in the ZGW 1, Ethernet standard components are provided for diagnostic communication (arrow 3 in Fig. 3). The Ethernet standard components are to be taken from the data stream created at diagnostic level 2 at the transport level.

From the data stream arriving on the diagnostic port 100 of the vehicle access application 200, the diagnostic messages that were previously present at the diagnostic tester are reconstructed. For this purpose, the individual packets (in each case a diagnosis message provided with a packaging header) are first extracted in a de-wrapper 101. A subsequent socket handler 102 also separates the individual diagnostic messages from the particular packet header. The diagnostic messages are thus at the output of the vehicle access application 200 in the same form as if they had entered the vehicle in a conventional manner and can be further processed in a manner known in the art without the need for special hardware components.

In the case depicted in FIG. 2, the diagnostic messages are forwarded to a UGW 11, which essentially corresponds to a CFFS known from WO 2005/076103 A2. It can also be seen in FIG. 2 that the connection of the motor vehicle to the vehicle recognition service 4 already described in connection with FIG. 3 is also implemented in the vehicle access application 200 in the present case. Upon receipt of an IP address or upon a separate request, the vehicle access application 200 sends the vehicle identifier 103 via the vehicle identification port 104.

About the in Fig. 2 also recognizable control data stream can be transmitted data which are independent of the diagnostic data stream and which are not mapped by means of diagnostic communication. An example of this is the query of terminal information, which is present as a CAN message 105 and is transmitted to the tester 2 via the control data stream from the motor vehicle. In this case, the control port 106 is used. In the case of multiple testers, the response to a request is assigned to the requesting tester by means of an allocation table 107. The packet format in the control data stream is selected identical to the format of the diagnostic data stream, a multiplexer allows the addition of further control messages.

Claims

claims

Method for data communication between a first communication user arranged in a motor vehicle and a second communication user arranged outside the motor vehicle, in which the first communication user is addressable by the second communication user by means of a network address, characterized in that the network address of the first communication user is determined by an outside of Motor vehicle arranged address management unit is set and is transmitted to the first communication participant.

2. The method according to claim 1, characterized in that for requesting a network address, a request message, in particular containing a unique vehicle identifier of the motor vehicle, is transmitted from a arranged at the motor vehicle communication subscriber to the address management unit.

3. The method according to any one of claims 1 or 2, characterized in that opening data for the assignment between the unique vehicle identifier sent for the request and the subsequently determined network address are stored in the address management unit.

4. The method according to any one of claims 1 to 3, characterized in that assignment data for the assignment between the unique vehicle identifier sent to the request and the subsequently determined network address are stored in an address switching unit, in which the belonging to a vehicle identifier network address is queried by other communication participants ,

5. The method according to any one of claims 1 to 4, characterized in that the second communication subscriber is designed as a diagnostic tester.

6. The method according to any one of claims 1 to 5, characterized in that the communication between the first and the second communication subscriber via a standard interface, in particular an Ethemet interface, takes place.

7. The method according to any one of claims 1 to 6, characterized in that the communication between the first and the second communication subscriber via a standard protocol, in particular TCP / IP, takes place.

8. The method according to claim 6 or 7, characterized in that on the vehicle side at the first communication participant during data communication from the second communication participant transmitted input data stream is converted by means of a vehicle access application in a diagnostic data stream in the data format of a conventional diagnostic communication.

9. The method according to any one of claims 1 to 8, characterized in that the address management unit is designed as a DHCP server and / or that the address switching unit is designed as a DNS server.

10. The method according to any one of claims 1 to 9, characterized in that the unique vehicle identifier is a chassis number.