EP1285349A2

EP1285349A2 - Method for exchanging data between several stations

Info

Publication number: EP1285349A2
Application number: EP01940465A
Authority: EP
Inventors: Robert Griessbach
Original assignee: Bayerische Motoren Werke AG
Current assignee: Bayerische Motoren Werke AG
Priority date: 2000-05-26
Filing date: 2001-05-12
Publication date: 2003-02-26
Also published as: DE10026246A1; WO2001093065A2; KR20030022130A; JP2003535533A; US7197592B2; WO2001093065A3; US20040030748A1; KR100746413B1

Abstract

The invention relates to a method for exchanging data between several stations belonging to various data bus systems. According to the invention, the data bus systems are spatially and physically separate from each other. The stations exchange data via control devices, which are respectively associated with a data bus system and which are interconnected by means of a quicker data bus, when said data bus is not busy.

Description

Procedure for data exchange between several participants

The invention relates to a method for data exchange between a plurality of subscribers who belong to different data bus systems.

In modern vehicles, several preferably standardized data bus systems are increasingly being used. For example, a data bus system adapted to this application is used for engine and chassis components, and a different data bus system that is particularly suitable for audio and telecommunications purposes. The data exchange between the different data bus systems takes place via gateways.

Attempting to transfer this bus system architecture from higher-priced vehicles to lower-class vehicles results in high costs. The reason for this is, on the one hand, the high costs of the standard bus for engine and chassis components and, on the other hand, the costs for a gateway, which are high due to the necessary computer. The development of a dedicated electrical system structure for vehicles of the lower classes poses the problem that the adoption of individual components of the higher-priced vehicles is largely impossible due to the lack of compatibility. There is also a conflict of objectives. To reduce costs, the data rate can be reduced and the number of bus participants increased. This results in long response times and little flexibility with regard to the number of participants from vehicle to vehicle. Each addition of a new participant, e.g. due to a subsequently installed component, requires a considerable adjustment effort.

The invention has for its object to provide a method for data exchange between the participants of different data bus systems, which despite a large number of participants, which also vary depending on the vehicle, has a high level of performance.

The invention solves this problem with the features of claim 1.

The method according to the invention is modular and inexpensive. It enables basic components to be used in all vehicles across several model series from one manufacturer. The higher-quality vehicles can be equipped as required with additional components without being more expensive than comparable series systems.

The prerequisite for this is the existence of the faster data bus. This can be, for example, a data bus as described in DE 19636441 A and DE 19636442 A. This data bus is characterized by a data rate of more than 5 Mbit / s and is suitable, for example, for passive safety systems that include airbags, belt tensioners, etc., as well as the associated sensors and actuators and their control units.

These associated control units are located at various points in the vehicle, e.g. in the area of the center tunnel and the B-pillars, also in the door or on the steering column. All of these control units are connected to the data bus, which is under very little load in normal situations, i.e. outside of a crash or violent misuse phase. The same applies to the utilization of the processors in the control units.

According to the invention, these control units are also used for other functions. These functions belong to other functionalities, for example the body electronics on the one hand and relate for example to the light control, the wiper control, the central locking and the window regulator control and on the other hand the data bus system for engine and chassis components. Instead of a gateway for the transition between the data bus systems, the gateway functionality is divided between the two already existing control devices of the faster data bus, with the possibility of providing any computing power that may be required with the computer that is already present in the control device.

In addition, there is the possibility of dividing each of the two data bus systems into smaller sub-data bus systems, which each transfer their data to this data bus via one of the control devices connected to the faster data bus, or take it over from it.

The scope of the body electronics can be divided into the light control and the wiper control on the one hand and the central locking and the window regulator control on the other. These are each part of a sub-data bus system, which has a sufficient response time due to the small number of participants (e.g. a control unit and connected consumers in light control) and is also functional at a low data rate, i.e. provides the connected participants with the required data quickly and securely. There is also the possibility of directly connecting control units that are part of the body electronics or engine management with higher communication requirements to the faster data bus.

With such an on-board network structure, a separate data bus for the components of the body electronics and the engine management system can be dispensed with, since these components are connected to the faster data bus either directly or via control units connected to them anyway. Above all, this leads to a loss of the gateway functionality and thus of separate gateways. In the single figure, the data bus structure according to the invention and an on-board electrical system of a vehicle implemented with it are shown and the communication method carried out with them is described.

The block diagram shown in the figure contains, among other things, a control unit module SGM and control units designated S1 to S4. Together, these components are connected by a faster data bus "Sl-Bus" for a passive safety system with a data rate of 5Mbit / s, for example. Control units marked with "K" are connected to the control units SGM and S1 to S3, each of which is a separate one Sub-data bus system assigned to body electronics, K-bus cluster 1, K-bus cluster 2, K-bus cluster 3 and K-bus cluster 4. Furthermore, a data bus system C-bus assigned to the engine management system is connected to the control unit S4 with subscribers C. The Components SGM and S1 to S4 thus contain the functions of the passive safety system, the basic functions of the body electronics and functions of the engine management. Within the sub-data bus systems, some control units K are separate for further explanations with K1 or K2, within the C-bus a control unit with C1 characterized.

Regarding the basic functions of the body electronics, the control units SGM and S1 to S3 adapt the data of the participants of their connected sub-data bus systems in their format to the data format of the faster data bus. The control unit S4 does this for the data of the C-bus participants. The control units SGM and S1 to S4 also convert the data of the faster data bus from this format to the data format of the connected sub-data bus system or C-bus system.

For this purpose, the data of all sub-data bus system participants and the participants of the C-bus system and the faster data bus Sl-Bus are provided with a unique identifier. The identifiers of the participants in the connected sub-data bus system or the C bus system are stored in the respective control unit. The particular advantage of the data bus structure according to the invention is that the number of telegrams per sub-data bus is significantly less than in the case of a data bus with only one line and the waiting time until a possible bus access is small due to the small number of subscribers. Furthermore, the participants of different data bus systems can communicate with one another without the need for a separate gateway computer.

In order to obtain a system that is as flexible as possible, it is necessary that sub-data bus subscribers (usually K-bus subscribers) and C-bus subscribers always have access to all required information of the overall system. In addition, it should be possible to "switch" a K-bus node from one sub-data bus to another without a fundamental change. So that it is z. B. easily possible to place a window switch block in a vehicle series in the door, in the other on the center console.

The K and C bus addresses in the overall system are unique. The corresponding C or K bus telegrams are converted according to a fixed rule to bus telegrams of the faster data bus with corresponding unique IDs. In the control units SGM and S1 to S4, codable "mini gateway tables" then only implement the telegrams that are also required in the respective (sub) data bus system. When "moving" a control unit from one K sub-data bus system to another, only these gateway tables then have to be recoded. The overall system behavior thus remains absolutely unchanged.

Data exchange within the overall system is explained using an example.

The transmission of a K-bus telegram TK1 from node K1 in K-bus cluster 1 to node K2 in K-bus cluster 2 is described as an example. The faster data bus is called Sl-Bus. K1 sends the telegram TK1 on K-bus cluster 1, triggered z. B. by pressing a button. SGM receives TK1 and packs the telegram TK1 into the data field of an S1 bus telegram.

All Sl-Bus participants receive TK1 in Sl-Bus format and look in their respective gateway tables to see whether TK1 should be translated to the associated K-Bus cluster. S1 unpacks TK1 from the Sl-Bus format and transmits TK1 to the K-Bus cluster 2. K2 receives TK1.

If the telegrams of the K-bus participants have a larger one. Telegram length than that of the data of the SI bus, e.g. B. 32 bytes of user data compared to 12 bytes of user data is a segmented, i.e. repeated transmission of defined telegram parts required.

If for some reason KK rather than K2 should receive TK1, then only TK1 needs to be deleted from the gateway table of S1 and entered in the gateway table of S4.

Claims

Procedure for data exchange between several participants

1. A method for data exchange between a plurality of participants belonging to different data bus systems, characterized in that the data bus systems are spatially and physically separate from one another and that the participants are each assigned to a data bus system and are connected to one another via a faster data bus

Control units exchange data during the time in which the faster data bus is not occupied.

2. The method according to claim 1, characterized in that the participants of a data bus system are arranged in total in at least two spatially and physically separate sub-data bus systems, and that each sub-data bus system is connected to the faster data bus via an associated control device.

3. The method according to claim 1 or 2, characterized in that the control units adapt the data of the participants of the connected data bus system in their format to the data format of the faster data bus or convert this format to the data format of the connected data bus system.

4. The method according to any one of claims 1 to 3, characterized in that the participants of the data bus systems and the participants of the faster data bus have a unique identifier.

5. The method according to any one of claims 1 to 4, characterized in that the identifiers of the participants in the connected data bus system are stored in the respective control unit.

6. The method according to any one of claims 1 to 5, characterized in that the identifiers of the participants in the (not) connected data bus system are stored in the respective control unit.

7. The method according to any one of claims 1 to 6, characterized in that the identifiers of the (not) connected participants are contained in a programmable memory.

8. The method according to claim 7, characterized in that the data transfer from the respective data bus system to the faster data bus and vice versa is controlled by means of the memory content.

9. The method according to any one of claims 1 to 8, characterized in that the respective control devices do not forward the data of the connected data bus system to the faster data bus in the event of a fault in this data bus system.