A method includes determining, by one or more processing entities associated with at least one of: one or more low voltage drive circuits (LVDCs) and one or more other LVDCs, an initial data conveyance scheme and an initial communication scheme for each communication of a plurality of communications on one or more lines of a bus. The method further includes determining a desired number of channels for each communication of the plurality of communications based on the initial data conveyance scheme and the initial communication scheme, a desired total number of channels for the plurality of communications based on the desired number of channels, determining whether the desired total number of channels for the plurality of communications exceeds a total number of available channels. If not, allocating the desired number of channels to each communication of the plurality of communications in accordance with the channel allocation mapping.

A device for coupling a fieldbus to a local bus for connection to at least one data bus subscriber, the device comprising a first unit that is connectable to the fieldbus and is adapted for sending and receiving data via the fieldbus; a second unit that is connectable to the local bus and is adapted for sending and receiving data via the local bus in at least one data packet; a data management unit that is connected to the first unit and the second unit, wherein the data management unit is adapted for transferring first symbols from data received via said first unit to said second unit in a sequence-dependent manner; and wherein the second unit is adapted to send at least one data packet including the first symbols on the local bus. In addition, a corresponding method for transferring data is described.

A wind turbine having a Controller Area Network communication system is provided. Electrical and/or electronic components of the wind turbine are coupled to CAN nodes. The communication system has a plurality of CAN nodes. At least one CAN distributor unit is coupled via a first communication segment to one of the plurality of CAN nodes and via a second communication segment to at least one further CAN distributing unit. The CAN distributor units are designed to carry out a data communication via the first communication segment on the basis of a first CAN protocol which represents a standard CAN protocol, and to carry out a data communication via a second communication segment on the basis of a second CAN protocol which is different from the standard CAN protocol.

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 flexible test arrangement for performing measurements on a test object. A plurality of safety components, each having a safety module which can be set to active or inactive, and having a ready status which can be set to active or inactive, is provided in a circular test arrangement. Each of the safety components carries out a number of function tests cyclically. As one of the function tests, a cyclical, error-free reception of a data packet is tested. One of the safety components is selected as a bus master which cyclically transmits a bus verification signal in a data packet to the safety component which is adjacent in the direction of transmission, wherein the bus verification signal is relayed by each of the safety components in a data packet, and, when said bus verification signal is received in a data packet, the bus master determines that the circular test arrangement is closed.

A multi-protocol bus circuit is provided. The multi-protocol bus circuit includes multiple master circuits each configured to communicate a respective master bus command(s) via a respective one of multiple master buses based on a respective one of multiple master bus protocols, and a slave circuit(s) configured to communicate a slave bus command(s) via a slave bus based on a slave bus protocol that is different from any of the master bus protocols. To enable bidirectional bus communications between the master circuits and the slave circuit(s), the multi-protocol bus circuit further includes a multi-protocol bridge circuit configured to perform a bidirectional conversion between the slave bus protocol and each of the master bus protocols. As a result, it is possible to support bidirectional bus communications based on heterogeneous bus protocols with minimal impact on cost and/or footprint.

A master slave communication system capable of reducing a manufacturing cost is provided. The mater slave communication system includes a master node and a plurality of slave nodes having the same initial address. A communication between the master node and one slave node among the plurality of slave nodes is established by using the initial address set as an address of the one slave node. The address of the one slave node is changed into another address which has been transmitted from the master node to the one slave node through the established communication and is different from the initial address.

A relay device and a multi-split control system that achieve reliable communication between an outdoor air conditioning unit and multiple indoor units under the condition that the length of a communication bus is limited. The system expands the communication distance by a cascade path formed by a plurality of relay devices. The cascade path transmits control signals sent by a master control device/a specific slave control device (i.e. a slave control device communicating with the master control device or certain relay device) to corresponding slave control devices one by one, and the corresponding slave control devices transmit the signals to the master control device/specific slave control device according to a response signal fed back by the control signal, where the relay devices may respectively communicate with a source node device and a destination node device on the basis of the master-slave type communication mode.

A method implemented by an electronic device for sending data on low latency communication includes remote writing a sequence number of a message to be sent next to a receiver, determining whether there is an open position in a receive buffer of the receiver using a local tracking mechanism, writing data of the message to an area of an address space of a sending application that is mapped onto the receive buffer as a result of determining there is the open position in the receive buffer, incrementing a local sequence counter, and updating position information in the local tracking mechanism.

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.