Described is a differential data bus system which maintains error free communication despite faults in one of the data bus lines.

Described is a differential data bus system which maintains error free communication despite faults in one of the data bus lines.

A receiver circuit includes a feedback loop including a device. The receiver circuit also includes a register and a sequencer. The sequencer is configured to, responsive to an error signal being below a threshold value, cause the register to store a value indicative of the state of the feedback loop. The sequencer is also configured to cause the feedback loop to transition to a lower power state, and, responsive to a detected wake-up event, cause the previously stored value indicative of the state of the feedback loop to be loaded from the register into the device and enable the feedback loop.

A control module for use within a control network, the control module comprising: interface circuitry for enabling communication with an external device; communication means configured to communicate with the external device over the control network by communication with the interface circuitry; coupling means configured to mechanically couple the control module to an adjacent control module and provide a data connection between the communication means and the adjacent module; and an electrical isolation in the data connection between the communication means and the coupling means.

A control module for use within a control network, the control module comprising: interface circuitry for enabling communication with an external device; communication means configured to communicate with the external device over the control network by communication with the interface circuitry; coupling means configured to mechanically couple the control module to an adjacent control module and provide a data connection between the communication means and the adjacent module; and an electrical isolation in the data connection between the communication means and the coupling means.

Various embodiments for implementing a switched direct attached shared storage architecture as disclosed herein include: providing a plurality of compute nodes, each compute node having integrated compute capabilities, data storage, and a network interface controller (Host NIC), the plurality of compute nodes being in data communication with each other via a local area network, the plurality of compute nodes each including distributed storage processing software resident thereon; providing a plurality of physical data storage devices in data communication with a storage controller; and enabling data communications in a data store switch fabric between the plurality of compute nodes and the plurality of physical data storage devices via the Host NIC and the storage controller, the data store switch fabric encapsulating data requests from the plurality of compute nodes into data frames for transport to corresponding physical data storage devices.

In one embodiment, a communication device operates according to a particular frequency hopping sequence in a communication network, and receives a first packet with an indication that the first packet is part of a particular packet train, the packet train comprising a plurality of packets to be transmitted in succession. Accordingly, the communication device prevents transmission until receiving a final packet of the packet train, and stores received packets of the particular packet train while preventing the transmission.

In one embodiment, a communication device operates according to a particular frequency hopping sequence in a communication network, and receives a first packet with an indication that the first packet is part of a particular packet train, the packet train comprising a plurality of packets to be transmitted in succession. Accordingly, the communication device prevents transmission until receiving a final packet of the packet train, and stores received packets of the particular packet train while preventing the transmission.

A mobile communications network includes one or more network elements providing a wireless access interface for communications devices. The wireless access interface provides plural communications resource elements across a host frequency bandwidth, and includes, within the host frequency bandwidth, first communications resource elements within a first frequency bandwidth for allocation preferably to reduced capability devices to receive signals representing the data transmitted by the transmitter unit within the first bandwidth forming a first virtual carrier, the reduced capability devices each having a receiver bandwidth which is greater than or equal to the first frequency bandwidth but less than the host frequency bandwidth. Communications devices of different capabilities can be allocated communications resources within different frequency ranges according to their capability, which can relieve congestion on a center frequency of communications resources in which communications devices with a minimum bandwidth capability must receive communications resources for receiving down link signals.

A system for controlling a CVVD by adjusting an actuator for controlling the CVVD is provided. The system includes an electronic control unit (ECU) configured to output a command phase angle and a selection signal for controlling the actuator based on a vehicle state and a mode of operation, and an actuator controller configured to operate based on the command phase angle and the selection signal and output an electric current to adjust the actuator. The actuator controller is configured to output an electric current corresponding to the command phase angle originating from the ECU or adjust the command phase angle and then output an electric current corresponding to the corrected command phase angle based on a type of selection signal.