The method and system of the present invention provides an improved technique for processing email during an unplanned outage. Email messages are redirected from the primary server to a secondary server during an unplanned outage such as, for example, a natural disaster. A notification message is sent to users alerting them that their email messages are available on the secondary server by, for example, Internet access. After the termination of the unplanned outage, email messages received during the unplanned outage are synchronized into the users standard email application.

The present disclosure provides an effective solution to employ hyperscale photonics connectivity using existing server connections. The solution described in the present disclosure eliminates top-of-rack switches and facilitates a manner for servers to connect directly to middle-of-row switches. An apparatus consistent with the present disclosure includes a primary transceiver device. The primary server-end transceiver device comprising a photonics transceiver and a first electrical transmitter. The apparatus further includes a first secondary server-end transceiver device, the first secondary server-end transceiver device comprising a second electrical transmitter. In addition, a first electrical cable electrically couples the primary server-end transceiver to the first secondary server-end transceiver device. The present disclosure enables the use of an input fiber connection and a photonics transceiver to effect two sets of electrical connections on different servers.

Communication between one system and another system using one communication mechanism has failed. The one communication mechanism includes an operating system service to transfer a message between the one system and the other system. Based on determining that the communication between the one system and the other system has failed, automatically switching from the one communication mechanism to another communication mechanism to communicate the message between the one system and the other system. The other communication mechanism is different from the operating system service and uses a coupling facility list structure.

Devices systems and methods are disclosed providing a highly fault tolerant Command, Control, and Data Handling (CC&DH) system immune to byzantine faults. The system includes a plurality of High Integrity Computing Elements each capable of delivering data immune to byzantine faults, an arbitrary communication interface, and a number of peripheral devices providing input and output to the system. The system is capable of providing high integrity data immune to byzantine faults throughout the system. Using one greater High Integrity Computing Elements than the number of faults required allows for implementation of a wide range of redundant systems including dual, triple, quad, and beyond redundancy using voting computers. The system is implemented using any number of standard computing elements, which is greater than two, a communication abstraction, data exchange, mission algorithm, and data comparison producing data immune to byzantine errors to the remaining peripherals in the system.

The method and system of the present invention provides an improved technique for processing email during an unplanned outage. Email messages are redirected from the primary server to a secondary server during an unplanned outage such as, for example, a natural disaster. A notification message is sent to users alerting them that their email messages are available on the secondary server by, for example, Internet access. After the termination of the unplanned outage, email messages received during the unplanned outage are synchronized into the users standard email application.

In one embodiment, an audio device includes a plurality of ports. The audio device receives, from a first network via a first port included in the plurality of ports, at least one of a first audio signal and a first control signal. The audio device transmits the at least one of the first audio signal and the first control signal to an audio output device. In case of a fault associated with the first port, the audio device transmits at least one of a second audio signal and a second control signal to the audio output device, where the at least one of the second audio signal and the second control signal is received from a second network via a second port included in the plurality of ports.

In some embodiments, a storage system with internal communication for data resiliency, is provided. The storage system includes a plurality of blades, each having a processor of a storage node arranged for communication with other blades through a midplane. Each of the plurality of blades has one or more storage units each having a storage controller and storage memory. The system includes a switch fabric coupling the plurality of blades through the midplane, and each storage unit having a first end of a point-to-point communication pathway connecting to the midplane, the point-to-point communication pathway passing through an associated blade having the storage unit and bypassing the processor of the storage node of the associated blade.

Technical solutions are described for providing a redundant processor. An example processing unit includes a source processor coupled with a system communication bus via a first communication line; a backup processor coupled with the system communication bus via a second communication line; and an inter-microprocessor communication channel for communication between the source processor and the backup processor. The backup processor monitors for a failure of the source processor by monitoring the first communication line for communication messages being transmitted by the source processor. The backup processor determines a failure of the source processor in response to an absence of the communication messages on the first communication line for a predetermined duration. The backup processor, in response to a failure of the source processor, takes over control of communication of the processing unit by sending a status update on the inter-microprocessor communication channel.

A serial communication system for communicating data over a Controller Area Network (CAN) bus comprises a security slave device located between a first system node and a Controller Area Network (CAN) bus. The system is characterised in that: said security slave device further comprises a tagging means for inserting data indicative of said first node into a Controller Area Network (CAN) frame received from said first node; said system further comprises a security master device, located between said Controller Area Network (CAN) bus and a second system node; said security master device further comprises a means of extracting said data indicative of first said node from a received data frame; and said system further comprises a means of checking the validity of received Controller Area Network (CAN) frame associated to said extracted data indicative of said first node.

Remote control system is disclosed. The present techniques relate to a system and a method for improving connection between two devices, e.g. to enable one device to control the other. The method comprises receiving, at a remote computing device, a request from a secondary user device to diagnose a fault with the primary user device. The request is received on a first communication channel. The method further comprises a step of connecting, in response to the request, the remote computing device with the secondary user device. This is performed by using a secure communication channel which is different to the first communication channel. The method further comprises a step of sending a command message for the primary user device from the remote computing device to the secondary user device via the secure communication channel. Any response to the command message is then received from the secondary user device via the secure communication channel. The response is used at least in part to diagnose the fault.