A method for transmitting data in a motor vehicle from an application using an Ethernet transport protocol between nodes of the motor vehicle includes: the application transmitting data via an Ethernet-based network at cyclic intervals; deactivating local transmitters and receivers of a node in non-use periods, in which no data need to be transmitted; activating again the local transmitters and receivers of the node when data are pending transmission; transferring the local transmitters and receivers from an operating active mode to a quiescent mode in a deactivation time; transferring the local transmitters and receivers from the quiescent mode to the operating active mode in an activation time; and the application lowering the transmission frequency at least until a prescribed limit value is reached based at least in part on a requirement to save energy.

An agricultural machine having a tractor and an implement hitched thereto and a method for operating same. The method comprising connecting a control device on the tractor and a control unit on the implement to a data bus. The control device processes a plurality of implement operation parameters and the control unit is assigned to a functional element of the implement. Furthermore, establishing data communication between the control device and the control unit through the bus, comprising, transmitting a response data message from the control unit to the control device indicating the control unit being configured to provide present parameter values for only a subset of implement operation parameters, but not a subset of remaining implement operation parameters. Further, future data collecting messages transmitted from the control device to the control unit are limited to requesting present parameter values for the subset of implement operation parameters.

A media converter including first and second physical layer devices and a processor. The first physical layer device is configured to store first data indicating a first status including an indication that the first communication link is active or inactive. The second physical layer device is configured to store second data indicating a second status including an indication that the second communication link is active or inactive. The processor is configured to determine whether the first status indicates that the first communication link is active or inactive, in response to a determination that the first status indicates that the first communication link is active, determine whether the second status indicates that the second communication link is active or inactive, and, in response to a determination that the second status indicates that the second communication link is inactive, change the first data to indicate that the first communication link is inactive.

System, methods and apparatus are described that support multimode operation of a data communication interface. A method includes receiving a first code word transmitted while a physical interface of the device is configured to operate in a low-power mode of operation, reconfiguring the physical interface in response to the first code word such that it operates in a high-speed mode, transmitting data while the physical interface operates in the high-speed mode of operation, receiving a second code word transmitted while the physical interface operated in the high-speed mode of operation, and reconfiguring the physical interface in response to the second code word, such that it operates in the low-power mode of operation. The first code word, the second code word, and the data may be transmitted in signals bound by a common voltage range. In one example, the voltage range is less than 600 millivolts.

An in-vehicle network system includes a first control unit, a second control unit, and a network connecting the first control unit to the second control unit. The first control unit performs a process of transmitting data, which is target of high-speed processing, having a first data length obtained by dividing transmission data by the first data length or obtained by adding predetermined data to the transmission data as high-speed processing. The second control unit performs a process of receiving reception data at a first processing speed that is a low speed when the second control unit determines that a data length of the reception data is not the first data length, and performs a process of receiving the reception data at a second processing speed higher than the first processing speed when the second control unit determines that the data length of the reception data is the first data length.

A subscriber station for a serial bus system. The subscriber station has a communication control device, and a re-integration module for re-integrating the communication control device into a communication on the bus to temporally synchronize the communication control device to a signal transmitted from the at least one other subscriber station of the bus system, which signal is created based on a frame for communication in the bus system. The re-integration module checks at least one predetermined re-integration condition to decide whether the operating mode of the communication control device is or is not to be switched into an operating mode for transmitting frames to the bus and/or for receiving frames from the bus, and uses in its check at least one predetermined re-integration condition having a sequence of bits in which the value of the last bit differs from that of the preceding bits.

Systems and techniques for single-wire communications are described. A described technique includes detecting transitions on a single-wire bus that are produced by a host device, determining an estimated baud rate of the host device based on the transition, and communicating with the host device based on the estimated baud rate. Determining the estimated baud rate can include charging a capacitor based on a charging rate in response to a detection of a first transition of the transitions, sampling a capacitor voltage associated with the capacitor in response to a detection of a second transition of the transitions, and adjusting the charging rate based on a comparison between the capacitor voltage and a reference voltage.

A system and method is provided for simultaneous communications on Modbus and DNP 3.0 over Ethernet for an electronic power meter. The system incorporates one or more protocol wrappers to provide compatibility with both Modbus and DNP based applications. The system removes the appropriate wrappers and routes the incoming data packet to its destination. Additionally, the system also wraps outgoing response packets with the appropriate protocol wrapper based on the related data packet wrappers.

System, methods and apparatus are described that support multimode operation of a data communication interface. A method includes receiving a first code word transmitted while a physical interface of the device is configured to operate in a low-power mode of operation, reconfiguring the physical interface in response to the first code word such that it operates in a high-speed mode, transmitting data while the physical interface operates in the high-speed mode of operation, receiving a second code word transmitted while the physical interface operated in the high-speed mode of operation, and reconfiguring the physical interface in response to the second code word, such that it operates in the low-power mode of operation. The first code word, the second code word, and the data may be transmitted in signals bound by a common voltage range. In one example, the voltage range is less than 600 millivolts.

System, methods and apparatus are described that support multimode operation of a data communication interface. A method includes receiving a first code word transmitted while a physical interface of the device is configured to operate in a low-power mode of operation, reconfiguring the physical interface in response to the first code word such that it operates in a high-speed mode, transmitting data while the physical interface operates in the high-speed mode of operation, receiving a second code word transmitted while the physical interface operated in the high-speed mode of operation, and reconfiguring the physical interface in response to the second code word, such that it operates in the low-power mode of operation. The first code word, the second code word, and the data may be transmitted in signals bound by a common voltage range. In one example, the voltage range is less than 500 millivolts.