WO2020048741A1

WO2020048741A1 - Subscriber station for a serial bus system and method for transmitting a message in a serial bus system

Info

Publication number: WO2020048741A1
Application number: PCT/EP2019/071596
Authority: WO
Inventors: Steffen Walker
Original assignee: Robert Bosch Gmbh
Priority date: 2018-09-04
Filing date: 2019-08-12
Publication date: 2020-03-12
Also published as: DE102018214960A1

Abstract

The invention relates to a subscriber station (20; 30) for a bus system (1) and to a method for transmitting a message with different bit rates in a bus system (1). The subscriber station (20; 30) comprises a transmitter/receiver device (22; 32) for the serial transmission of a message (5) on a bus line (3) to at least one other subscriber station (10; 20; 30) of the bus system (1) or for the serial reception of a message (5) from the bus line (3), wherein the transmitter/receiver device (22; 32) is designed for the serial transmission and/or the serial reception of the message (5) between a first operating mode and a second operating mode, wherein the transmitter/receiver device (22; 32) is designed to generate, in the first operating mode, a first and second data state, each as a bus state (DF1, DF3; DF1, DF2) with different bus levels for two bus cores (41, 42) of the bus line (3), and wherein the transmitter/receiver device (22; 32) is designed to generate, in the second operating mode, a third data state, in addition to the first and second data states, as a bus state (DF1, DF2, DF3) with a bus level for the two bus cores (41, 42) of the bus line (3), which is different from the bus levels for the first and second data states (DF1, DF2).

Description

description

Subscriber station for a serial bus system and method for sending a

Message in a serial bus system

Technical field

The present invention relates to a subscriber station for a serial bus system and a method for sending a message in a serial bus system which operates with a high data rate and a high level of error tolerance.

State of the art

A bus system is frequently used for communication between sensors and control devices, for example in vehicles, in which data is transmitted as messages in the ISO11898-l: 2015 standard as a CAN protocol specification with CAN FD. The messages are between the

Transfer bus participants of the bus system, such as sensor, control unit, encoder, etc.

With an increasing number of functions of a technical system or a vehicle, the data traffic in the bus system also increases. In addition, it is often required that the data can be transferred from the sender to the receiver faster than before. The consequence of this is that the required bandwidth of the bus system will continue to increase.

In order to be able to transmit data with a higher bit rate than with CAN, an option for switching to a higher bit rate within a message was created in the CAN FD message format. In such techniques, the maximum possible data rate is increased by using a higher clock rate in the area of the data fields beyond a value of 1 Mbit / s. Such news are also referred to below as CAN FD frames or CAN FD messages. With CAN FD, the user data length is extended from 8 to up to 64 bytes and the data transfer rates are significantly higher than with CAN.

Even if a CAN or CAN FD-based communication network offers many advantages in terms of its robustness, for example, it has a significantly lower speed compared to one

Data transmission with 100 Base-Tl Ethernet, for example. In addition, the user data length of up to 64 bytes previously achieved with CAN FD is too short for some applications.

Disclosure of the invention

It is therefore an object of the present invention to provide a subscriber station for a serial bus system and a method for sending a message in a serial bus system, which solve the aforementioned problems. In particular, a subscriber station for a serial bus system and a method for sending a message in a serial bus system are to be provided, in which a high data rate and an increase in the amount of user data per frame can be realized with great robustness for errors.

The aforementioned object is achieved by a subscriber station for a serial bus system according to claim 1. The subscriber station has a transceiver for serial transmission of a message on a bus line to at least one other subscriber station of the bus system and / or for serial reception of a message from the bus line, the transceiver being designed for serial transmission and / or for to switch the serial reception of the message between a first operating mode and a second operating mode, the transceiver in the first operating mode being designed to generate a first and a second data state in each case as a bus state with different bus levels for two bus wires of the bus line, and wherein the Transceiver is configured in the second mode, in addition to the first and second Data state to generate a third data state as a bus state with a bus level for the two bus wires of the bus line, which is different from the bus levels for the first and second data states.

With the subscriber station, it is possible in particular in a first

Communication phase to maintain an arbitration known from CAN and still increase the transmission rate considerably compared to CAN or CAN FD. This can be achieved in that by expanding the bus states or symbols from two to three by means of coding and decoding, more data is transmitted per time at a given transmission frequency. This leads to an increase in the baud rate. As a result, the bit rate and thus the transmission speed from the transmitter to the receiver can be increased significantly. However, due to the design of the three different bus states, this is a large one

Robustness guaranteed.

This helps to realize a net data rate of at least 10 Mbps. In addition, the size of the user data can be increased significantly, in particular up to 4096 bytes per frame or more or less if required.

The method carried out by the transceiver can also be used if there is also at least one CAN subscriber station and / or at least one CAN FD subscriber station in the bus system, which send messages according to the CAN protocol and / or CAN FD protocol .

Advantageous further developments of the subscriber station are specified in the dependent claims.

According to one embodiment, the bus states for the first and second data states are symmetrical to one another. According to a special embodiment, the transmitting / receiving device is designed to generate the bus state for the second data state by driving the bus levels for the two bus wires weaker than the bus state for the first data state.

The transmitting / receiving device is optionally designed to generate the bus states in such a way that the bus state for the first data state can overwrite both the bus state for the second data state and the bus state for the third data state.

According to a special embodiment, the transmitting / receiving device is configured to switch to the first operating mode if data of a first phase are to be sent from the message which are to be sent at a first bit rate, and the transmitting / receiving device is configured to switch to the second mode of operation if the message is to send data of a second phase which is to be sent at a second bit rate which is faster than the first bit rate. Here, the transmitting / receiving device may be designed to switch to the first operating mode or the second operating mode according to a predetermined coding if the data of the second phase are to be sent from the message.

It is conceivable that the transmitting / receiving device is designed to switch only to the second operating mode for sending data, if for the

Subscriber station is guaranteed exclusive, collision-free access to the bus line of the bus system for a predetermined time.

The transmitting / receiving device may be designed to send the data for the first and second data states to the bus line in the first operating mode with the same bus level as in the second operating mode.

In particular, the message can have a data field with a variable length, the variable length being between 1 byte and 4096 bytes. The subscriber station described above can be part of a bus system which also comprises a bus line and at least two subscriber stations which are connected to one another via the bus line in such a way that they can communicate with one another in series. Here, at least one of the at least two subscriber stations is a previously described subscriber station.

The aforementioned object is also achieved by a method for sending a message in a serial bus system according to claim 11. The method has the step: serial transmission, with a transmitting / receiving device of a subscriber station of the bus system, a message on a bus line of the bus system, wherein the transmitting / receiving device can additionally be designed for the serial reception of a message from the bus line, the transmission - / receiving device for serial transmission switches between a first operating mode and a second operating mode, the transmitting / receiving device in the first operating mode generating a first and second data status as a bus status with different bus levels for two bus cores of the bus line, and wherein the transmitting / In the second operating mode, the receiving device generates, in addition to the first and second data states, a third data state as a bus state with a bus level for the two bus wires of the bus line which differs from the bus levels for the first and second data states.

The method offers the same advantages as previously in relation to the

Participant station are called.

Further possible implementations of the invention also include combinations of previously or hereinafter not explicitly mentioned with respect to FIG

Embodiments described features or embodiments. The person skilled in the art will also add individual aspects as improvements or additions to the respective basic form of the invention.

drawings The invention is described in more detail below with reference to the accompanying drawing and using exemplary embodiments. Show it:

1 shows a simplified block diagram of a bus system according to a first exemplary embodiment;

Fig. 2 is a diagram illustrating the structure of messages from subscriber stations of the bus system according to the first

Embodiment can be sent;

3 shows a time profile of bus signals CAN_H and CAN_L in the transceiver according to the first exemplary embodiment; and

Fig. 4 shows a time course of a differential voltage VDIFF of the bus signals CAN_H and CAN_L in the transceiver according to the first embodiment.

In the figures, identical or functionally identical elements are provided with the same reference numerals, unless stated otherwise.

Description of the embodiments

1 shows an example of a bus system 1, which is configured in particular fundamentally for a CAN bus system, a CAN FD bus system, a CAN FE bus system, and / or modifications thereof, as described below. The bus system 1 can be used in a vehicle, in particular a motor vehicle, an aircraft, etc., or in a hospital, etc.

1, the bus system 1 has a bus line 3, in particular two twisted bus wires 41, 42, to which a multiplicity of subscriber stations 10, 20, 30 are connected. Messages 4, 5 in the form of signals between the individual subscriber stations 10, 20, 30 can be serially transmitted via the bus line 3 shown very schematically in FIG. 1 in a partial sectional view. The Subscriber stations 10, 20, 30 are, for example, control devices, sensors, display devices, etc. of a motor vehicle.

As shown in Fig. 1, subscriber station 10 has one

Communication control device 11 and a transceiver device 12. The subscriber station 20, on the other hand, has a communication control device 21 and a transceiver device 22. The subscriber station 30 has a communication control device 31 and a transceiver device 32. The transceiver devices 12, 22, 32 of the subscriber stations 10, 20, 30 are each connected directly to the bus line 3 or its bus wires 41, 42, even if this is not illustrated in FIG. 1.

The communication control devices 11, 21, 31 each serve to control communication of the respective subscriber station 10, 20, 30 via the bus line 3 with another subscriber station of the subscriber stations 10,

20, 30, which are connected to the bus line 3.

The communication control device 11 can be designed like a conventional CAN controller. The communication control device 11 creates and reads first messages 4, for example Classic CAN messages 4. The Classic CAN messages 4 are constructed in accordance with the Classic basic format, in which a number of up to 8 data bytes can be included in the message 4. Alternatively, the Classic CAN message 4 is constructed as a CAN FD message, in which a number of up to 64 data bytes can be included, which are also transmitted at a significantly faster data rate than with the Classic CAN message 4. In the latter case it is

Communication control device 11 designed as a conventional CAN FD controller.

The communication control device 21 creates and reads second messages 5, which are modified CAN messages 5, for example. Here, the modified CAN messages 5 are constructed on the basis of a CAN FE format, which is described in more detail with reference to FIG. 2. The communication control device 31 can be designed to provide a Classic CAN message 4 or a CAN FE message 5 for the transceiver 32, or to receive it, as required. The communication control device 31 thus creates and reads a first message 4 or second message 5, the first and second messages 4, 5 differing in their data transmission standard, namely in this case CAN or CAN FE. Alternatively, the Classic CAN message 4 is structured as a CAN FD message. In the latter case, the communication control device 11 is designed like a conventional CAN FD controller.

The transceiver 12 can be like a conventional CAN

Transceiver or CAN FD transceiver. The transceiver 22 can be more precise except for the following

described differences can be implemented as a CAN FE transceiver. The transmitting / receiving device 32 can be designed to provide messages 4 according to the current CAN basic format or messages 5 according to the CAN FE format for the communication control device 31 or to receive them as required. The transmitting / receiving devices 22, 32 are additionally or alternatively like one

conventional CAN FD transceiver can be used.

Each of the transceiver 12, 22, 32 is preferably designed to differentiate the bus states with respect to 0 and 2V differential voltage VDIFF. As a result, a receiving part of the transmitting / receiving device 12, 22, 32 can also recognize all states of the signals, which are described below with reference to FIGS. 3 and 4. Alternatively, the receiving part of the transceiver 12, 22, 32 can be a

perform the appropriate switchover so that messages 5 can be received correctly.

With the two subscriber stations 20, 30 an education and then

Transmission of messages 5 with the CAN FE format and the reception of such messages 5 can be realized. FIG. 2 shows a CAN FE frame 45 for the message 5 as it is sent by the transceiver 22 or the transceiver 32. The CAN FE frame 45 is divided into different fields, namely a start field 451, for CAN communication on the bus line 3

Arbitration field 452, a control field 453, a data field 454, a checksum field 455 and an end field 456.

The start field 451 has, for example, a bit, which is also called a SOF bit and indicates the start of the frame or start of frame. Arbitration field 452 contains an identifier with, for example, 32 bits for identifying the sender of the message. The arbitration field 452 can additionally contain protocol format information consisting of one or more bits, which is suitable for distinguishing CAN FE frames from CAN frames or CAN FD frames.

The control field 453 contains, for example, a 13-bit data length code (data length code) which can then, for example, assume values from 1 to 4096 with a step size of 1, or can also assume values from 0 to 4095. The data length code can also comprise fewer or more bits and the value range and the step-by-step can assume different values. The

Control field 453 can additionally contain protocol format information consisting of one or more bits, which is suitable for distinguishing CAN FE frames from CAN frames or CAN FD frames.

The data field 454 contains the useful data of the CAN FE frame or message 5. Depending on the value range of the data length code, the user data can have, for example, up to 4096 bytes. The checksum field 455 contains a checksum about the data in the data field 454, including the stuff bits, which are inserted by the sender of the message 5 after every 10 identical bits as an inverse bit. The end field 456 contains at least one acknowledge bit and also a sequence of 11 identical bits which indicate the end of the CAN FE frame 45. The at least one acknowledge bit can be used to indicate whether a receiver is in has received an error in the received CAN FE frame 45 or message 5 or not.

In the phases for sending the arbitration field 452 and the end field 456, a physical layer is used as in CAN and CAN-FD. An important point during these phases is that the well known CSMA / CR process

Is used, which simultaneous access of the subscriber stations 10,

20, 30 allowed on the bus line 3 without the higher priority message 4,

5 is destroyed. As a result, further bus subscriber stations 10, 20, 30 can be added to the bus system 1 relatively easily, which is very advantageous.

The consequence of the CSMA / CR method is that there must be so-called recessive states on bus line 3, which can be overwritten by other subscriber stations 10, 20, 30 with dominant states on bus line 3. In the recessive state, there are high-impedance conditions at the individual subscriber stations 10, 20, 30, which, in combination with the parasites of the bus circuitry, results in longer time constants. This leads to a limitation of the maximum bit rate of today's CAN FD physical layer to currently around 2 megabits per second in real vehicle use.

The control field 453 and the data field 454 are only sent to the bus line 3 by a sender of the message 5 when the subscriber station 20 as the sender has won the arbitration and the subscriber station 20 as the sender thus has exclusive access to send the fields 453 to 456 has the bus line 3 of the bus system 1. In the case of arbitration, the identifier in the arbitration field 452 is used bit by bit between the

Subscriber stations 10, 20, 30 negotiated which subscriber station 10, 20, 30 would like to send message 4, 5 with the highest priority and therefore will have exclusive access to bus line 3 of bus system 1 for the next time to send fields 453 to 455 .

The arbitration at the beginning of a frame 45 or the message 4, 5 and the acknowledgment in the end field 456 at the end of the frame 45 or the message 4, 5 is only possible if the bit time is significantly more than twice as much is as long as the signal transit time between any two subscriber stations 10, 20, 30 of the bus system 1. Therefore, the bit rate in the arbitration phase when the fields 451, 452, 456 are transmitted is chosen to be slower than in the other fields of the frame 45.

3 shows voltage profiles of bus signals 412, 422 according to a second exemplary embodiment. For the sake of simplicity, only that part of the bus signals 412, 422 is shown which is set for the transmission of the fields 453, 454, 455 on the bus line 3. In a CAN or CAN FD bus system, the bus signals 412, 422 are referred to as CAN-H and CAN_L and are each fed separately into the bus wires 41, 42. 4 shows the resulting differential voltage VDIFF = CAN_H - CAN_L.

The bus signals 412, 422, which occur in the arbitration phase when the fields 451, 452, 456 are transmitted, can be derived from the illustration in FIG. 3 and / or FIG. 4, as explained below.

For the implementation of the bus signals 412, 422 of FIG. 3, a physical layer is used for the entire frame 45 of FIG. 2, which has the aforementioned arbitration phase for fields 451, 452 and 456 as well as a long and faster data phase for fields 453, 454, 455 allowed. Here, the transceivers 22, 32 for generating the bus signals 412, 422 for a message 5 work partially symmetrically in all communication phases.

3 shows the resulting bus signals 412, 422 in all three possible bus states DF1, DF2, DF3 in such a transceiver 22, 32. The amplitude U_D1 of the

Differential voltage of the bus state DF1 and the amplitude U_D2 of the

Differential voltage of the bus state DF2 is the same. In contrast, the amplitude of the differential voltage U_D3 of the bus state DF3 has the value 0.

Communication is carried out with the three different bus states DF1, DF2, DF3 in the data phase, ie in fields 453 to 455, after arbitration has been completed. The bus state DF1 has a positive differential voltage VDIFF = U_D2 (V_Plus - V_Minus) result. The bus state DF2 results in a negative differential voltage Vdiff = -U_D2. The bus state DF3 results in a differential voltage VDIFF = U_D3 = 0. With the two

Different two bus states DF1 G, positive dominant "), DF3 G, negative dominant") is communicated in the arbitration phase, ie in fields 451, 452, 456. This is done as previously described with reference to FIG. 2.

The bus states DF2, DF3 can be overwritten by other subscriber stations, for example the subscriber stations 10, 30 for signaling an error, for example in the acknowledgment in the end field 456 at the end of the frame 45. However, this overwriting can only be recognized in relation to the bus state DF3 G, negative dominant “) if the relevant transceiver 12 12, 32 in the receiving section also contains the bus states DF1 G, positive dominant”), DF3 G, negative dominant “) Are distinguishable.

Thus, in the present exemplary embodiment, each of the transceivers 22, 32 switches in a first operating mode between the two bus states DF1, DF3 for message 5 when data of the arbitration phase or first phase 456, 451, 452 are to be sent from message 5 . In addition, each of the transceivers 22, 32 switches to a second

Operating mode with the three different bus states DF1, DF2, DF3 for message 5 if data 5 of the data phase or second phase 453, 454, 455 are to be sent from message 5.

Each of the transceivers 22, 32 thus switches between up to three different bus states DF1, DF2, DF3 in order to send the message 5 or the frame 45. Here, the two bus states DF1, DF2 are symmetrical to each other. Of course, more than the three bus states mentioned are possible, for example by introducing at least one additional bus state DF1, DF2, DF3 with a level which, for example, lies between the level of the bus states DF1, DF2 and the level of the

Bus state DF3 are. Additionally or alternatively, it is conceivable that at least a bus state is introduced with levels which are, for example, above the level of the bus states DF1, DF2 and the level of the bus state DF3.

By expanding the bus states or symbols from two to at least three by means of coding and decoding, more data can be transmitted per time at a given transmission frequency. This leads to an increase in the baud rate, as previously mentioned.

Here, all three bus states DF1, DF2, DF3 can be used at least to send data field 454. In addition, the three bus states DF1, DF2, DF3 can also be used in fields 453, 455, as described above. The bit rate can thus be increased by coding.

In addition, the configuration of the transceivers 22, 32 in the present exemplary embodiment can achieve the same advantages as previously described with reference to the first exemplary embodiment.

According to a second exemplary embodiment, the frequency of the signals 412, 422 is reduced. As a result, an improvement in the EMC behavior can be achieved. The coding described in more than two bus states enables the bit rate to be kept constant despite the lower frequency.

According to a third exemplary embodiment, the second bus state DF2 still has a negative differential voltage VDIFF, but a lower bus level than the first bus state DF1. In this case, the second bus state DF2 can also be safely overwritten by the first bus state DF1. The first and second bus states DF1, DF2 can thus be used in at least some of the fields 451, 452, 456 or in the entire arbitration phase. In addition, even with such three bus states DF1, Df2, DF3, the bit rate can be increased in the data phase by the coding described above in more than two bus states, or the bit rate can be kept constant despite the lower frequency. The arbitration in all of the exemplary embodiments and their modifications compared to classic CAN and CAN FD therefore takes place unchanged in accordance with the CSMA / CR method. During the arbitration, there are still only two bus states, "positive dominant" and "recessive". As a result, the effort for the introduction and conversion to the bus system according to the invention is reduced. By suitable

Measures can also enable the CAN FE frames to coexist with the CAN and / or CAN FD frames or a tolerance of the CAN and CANFD subscriber stations to the CAN FE frames.

The previously described new development "CAN FE" therefore has the following properties in comparison to CAN or CAN FD:

a) Acceptance and, if necessary, adaptation of proven properties that are responsible for the robustness and user-friendliness of CAN and CAN FD, in particular frame structure with identifier and arbitration according to the CSMA / CR process, b) Increase in the net data transfer rate to approximately 10 megabits per Second, c) increasing the size of the user data per frame to a greater length than with CAN or CAN FD, in particular a maximum of 4 kbytes,

d) Optional: Complete or partial waiver of sending error frames when errors are detected.

All previously described configurations of the bus system 1, the

Subscriber stations 10, 20, 30 and the method carried out by the subscriber stations 10, 20, 30 can be used individually or in all possible combinations. In particular, all the features of the previous

described embodiments and / or their modifications can be combined as desired. Additionally or alternatively, the following are in particular

Modifications possible.

The previously described bus system 1 according to the exemplary embodiments is described using a bus system based on the CAN protocol. However, the bus system 1 according to the exemplary embodiments can also be another type of communication network, in which data is serial with two

different bit rates are transferable. It is beneficial, but not

inevitable requirement that in the bus system 1 at least for certain periods of time exclusive, collision-free access by one

Subscriber station 10, 20, 30 is guaranteed on a common channel.

The number and arrangement of the subscriber stations 10, 20, 30 in the bus system 1 of the exemplary embodiments is arbitrary. In particular, the

Subscriber station 10 in bus system 1 is eliminated. It is possible for one or more of the subscriber stations 20 or 30 to be present in the bus system 1.

Claims

Expectations

1) subscriber station (20; 30) for a serial bus system (1), with

a transmitting / receiving device (22; 32) for the serial transmission of a message (5) on a bus line (3) to at least one further subscriber station (10; 20; 30) of the bus system (1) and / or for the serial reception of a message ( 5) from the bus line (3), the transmitting / receiving device (22; 32) being designed to switch between a first operating mode and a second operating mode for serial transmission and / or for serial reception of the message (5),

The transmitting / receiving device (22; 32) is designed in the first operating mode to generate a first and a second data state as a bus state (DF1, DF3) with different bus levels for two bus wires (41, 42) of the bus line (3), and

wherein the transmitting / receiving device (22; 32) is configured in the second operating mode, in addition to the first and second data states, a third data state as bus state (DF1, DF2, DF3) with a bus level for the two bus wires (41, 42) To generate bus line (3), which differs from the bus levels for the first and second data state (DF1, DF2).

2) subscriber station (20; 30) according to claim 1, wherein the bus states (DF1, DF2) for the first and second data state are symmetrical to each other.

3) subscriber station (20; 30) according to claim 1 or 2, wherein the transceiver (22; 32) is configured to the bus state (DF2) for the second data state by weaker driving the bus level for the two bus wires (41, 42 ) to be generated as the bus state (DF1) for the first data state. 4) subscriber station (20; 30) according to any one of the preceding claims, wherein the transceiver (22; 32) is designed to generate the bus states (DF1 to DF3) such that the bus state (DF1) for the first data state both can overwrite the bus state (DF2) for the second data state and the bus state (DF3) for the third data state.

5) subscriber station (20; 30) according to any one of the preceding claims, wherein the transceiver (22; 32) is configured to switch to the first operating mode when data of a first phase (456; 451 ; 452) are to be sent, which are to be sent at a first bit rate, and

wherein the transceiver (22; 32) is configured to switch to the second mode of operation if the message (5) is to be used to transmit data of a second phase (453; 454; 455) which is to be transmitted at a second bit rate which is faster than the first bit rate.

6) subscriber station (20; 30) according to claim 5, wherein the transceiver (22; 32) is configured to switch according to a predetermined coding in the first mode or the second mode when the data from the message (5) the second phase (453; 454; 455) are to be sent.

7) subscriber station (20; 30) according to any one of the preceding claims, wherein the transceiver (22; 32) is designed to switch only to the second mode for transmitting data when for the subscriber station (20; 30) for Exclusive, collision-free access to the bus line (3) of the bus system (1) is guaranteed for a predetermined time.

8) subscriber station (20; 30) according to any one of the preceding claims, wherein the transmitting / receiving device (22; 32) is configured, the data for the first and second data state (DF1, DF2) in the to send the first operating mode to the bus line (3) with the same bus level as in the second operating mode.

9) Subscriber station (20; 30) according to one of the preceding claims, wherein the message (5) has a data field (454) with a variable length, the variable length being between 1 byte and 4096 bytes.

10) Bus system (1), with

a bus line (3), and

at least two subscriber stations (10; 20; 30) which are connected to one another via the bus line (3) in such a way that they can communicate with one another in series,

wherein at least one of the at least two subscriber stations (10; 20; 30) is a subscriber station (20; 30) according to one of the

preceding claims.

11) Method for sending a message (5) in a serial bus system (1), the method comprising the step:

serial transmission, with a transmission / reception device (22; 32) of a subscriber station (20; 30) of the bus system (1), a message (4; 5) on a bus line (3) of the bus system (1), the transmission / Receiving device (22; 32) can be configured in addition to the serial reception of a message (5) from the bus line (3),

wherein the transceiver (22; 32) switches between a first operating mode and a second operating mode for serial transmission,

wherein the transceiver (22; 32) in the first operating mode a first and a second data state as each

Bus state (DF1, DF3; DF1, DF2) with different bus levels for two bus wires (41, 42) of the bus line (3) generated, and

wherein the transmitter / receiver device (22; 32) in the second operating mode in addition to the first and second data status, a third data status as bus status (DF1, DF2, DF3) with a Bus level for the two bus wires (41, 42) of the bus line (3) is generated, which differs from the bus levels for the first and second data states (DF1, DF2).