A communication control device for a user station for a serial bus system. The communication control device controls a communication of the user station with at least one other user station of the bus system, and generates a transmission signal for transmission onto a bus of the bus system and/or to receive a signal from the bus. The communication control device generates the transmission signal according to a frame in which bits having a predetermined temporal length are provided. The communication control device is designed to shorten, in comparison to some other bit of the bit sequence, at least one bit in the frame that is situated in a bit sequence of at least two bits having the same logical value, and the communication control device is designed to not shorten bits that are not situated in a bit sequence of at least two bits having the same logical value.

A communication system includes a master device and a plurality of slave devices. Each slave device stores a synchronization period and a correction amount of a difference between a time of the master device and a time of the slave device. The master device acquires the correction amount from the slave device, calculates a correspondence relationship between a synchronization period and the correction amount based on the correction amount, calculates a target synchronization period in the slave device based on the correspondence relationship, classifies each slave device into a plurality of groups based on the target synchronization period in each slave device, and sets a maximum target synchronization period among the target synchronization periods of at least one slave device classified into each group to a new synchronization period in which the master device performs the time synchronization along with the at least one slave device.

In aspects, a Local Interconnect Network (LIN) communication circuit including a first LIN master associated with a first LIN bus and a second LIN master associated with a second LIN bus is disclosed. A data link is connected between the first and second LIN masters. A first mirroring client is established at the first LIN master for receiving message bits corresponding to a LIN message in a first slot on the first LIN bus and for transmitting the message bits bitwise over the data link. A second mirroring client is established at the second LIN master for receiving the message bits and transmitting them over the second LIN bus. The first and second LIN masters include synchronised schedule tables such that the message bits on the second LIN bus are transmitted in a corresponding slot to the first.

A data bus subscriber connected to a local bus, particularly a ring bus. The data bus subscriber has a status signal input for receiving a first status signal value from a downstream data bus subscriber or a terminator, a status signal output for providing a second status signal value to an upstream data bus subscriber or to a local bus master, wherein the data bus subscriber is adapted to provide the second status signal value based on a logical link of a communication readiness of the data bus subscriber and the first status signal value. The invention further relates to a corresponding method and a local bus.

A system for automatically addressing serially connected slave devices includes a master device and multiple slave devices each including a serial communication transceiver, an address input port, an address output port, and a controller. The system also includes a serial communication wiring bus connected between the serial communication transceivers of the master and slave devices, and at least one digital address line connected between the address input ports and the address output ports. Each controller is configured to receive a PWM or PFM signal from a previous one of the multiple slave devices, determine an address for the slave device including the controller according to the received PWM or PFM signal, and transmit a PWM or PFM signal indicative of the determined address to a subsequent one of the multiple slave devices.

A system for controlling equipment at a wellsite includes a surface PLC, a first subsea PLC, a second subsea PLC, a first CAN module, a second CAN module, and a CAN network. The surface PLC is configured to receive a parameter that is measured by a sensor and to transmit a first signal to the first subsea PLC, the second subsea PLC, or both in response to the parameter. The first subsea PLC or the second subsea PLC, or both are configured to transmit a second signal to the first CAN module, the second CAN module, or both in response to the first signal. The first CAN module, the second CAN module, or both are configured to transmit a third signal to the CAN network in response to the second signal. The CAN network is configured to control the equipment in response to the third signal.

A method is described for identifying communication-ready data bus subscribers connected to a local bus. The method comprises receiving, at a local bus master, at least one data packet transmitted via the local bus, wherein the at least one data packet received at the local bus master comprises an address of a communication-ready data bus subscriber among a plurality of communication-ready data bus subscribers in the local bus, wherein the communication-ready data bus subscriber is in a sequence of communication-ready data bus subscribers, and mapping of the received address by the local bus master to a relative position of the communication-ready data bus subscriber in the sequence of communication-ready data bus subscribers in the local bus. In addition, a local bus master of the local bus is described.

Provided are a topology switching method based on isochronous channel, an apparatus, a system and a storage medium. The method is applied to a first central slave device. There are a plurality of first isochronous channels between the first central slave device and a master device, and there is a first communication channel between the first central slave device and a peripheral slave device. The method includes: sending, by first central slave device, first isochronization information to peripheral slave device through the first communication channel, where the first isochronization information includes a channel parameter of first isochronous channel, so that peripheral slave device starts data transmission with master device according to the channel parameter of first isochronous channel; and stopping, by first central slave device, data transmission with master device through the first isochronous channel, before peripheral slave device starts data transmission with master device.

A master is provided which is connected to at least one slave via an interface, wherein the at least one master is designed, in a transmission mode to transfer a valid combination of output data and associated error detection data via the interface, and wherein the at least one master is furthermore designed, in a non-transmission mode, to output an invalid combination of output data and associated error detection data in case of an erroneous output request.

A method, a bus system, and a transportation means control a utilization of the bus system. The method includes determining a first piece of information representing a current and/or a future utilization of the bus system, and determining a second piece of information representing respective data transmission time periods for a plurality of bus subscribers which transmit data by means of the bus system, as a function of the first piece of information. The method also includes transmitting the second piece of information to the plurality of bus subscribers, and adjusting respective data transmission time periods for the plurality of bus subscribers by the respective bus subscribers, as a function of the second piece of information, and transmitting data by the plurality of bus subscribers within the respective adjusted data transmission time periods by means of the bus system.