A module may include a transceiver and a wireless interface. The transceiver may be configured to communicatively couple to an in-band communications interface of an information handling system and communicatively couple to a cable thus enabling in-band communications via wire-line transmissions between the cable and the in-band communications interface. The wireless interface may be configured to communicatively couple to an out-of-band communications interface of the information handling system and communicatively couple to a client device configured to perform out-of-band management of the information handling system via wireless transmissions between the wireless interface and the out-of-band communications interface.

A module may include a transceiver and a wireless interface. The transceiver may be configured to communicatively couple to an in-band communications interface of an information handling system and communicatively couple to a cable thus enabling in-band communications via wire-line transmissions between the cable and the in-band communications interface. The wireless interface may be configured to communicatively couple to an out-of-band communications interface of the information handling system and communicatively couple to a client device configured to perform out-of-band management of the information handling system via wireless transmissions between the wireless interface and the out-of-band communications interface.

A spine switch for a network switch comprises a support board that supports at least one first switch. The spine switch further includes a first set of connectors at a first edge of the support board that detachably connect to one or more first leaf switches to communicatively couple and decouple the at least one first switch from the one or more first leaf switches.

A spine switch for a network switch comprises a support board that supports at least one first switch. The spine switch further includes a first set of connectors at a first edge of the support board that detachably connect to one or more first leaf switches to communicatively couple and decouple the at least one first switch from the one or more first leaf switches.

Embodiments are generally directed apparatuses, methods, techniques and so forth to select two or more processing units of the plurality of processing units to process a workload, and configure a circuit switch to link the two or more processing units to process the workload, the two or more processing units each linked to each other via paths of communication and the circuit switch.

Embodiments are generally directed apparatuses, methods, techniques and so forth to select two or more processing units of the plurality of processing units to process a workload, and configure a circuit switch to link the two or more processing units to process the workload, the two or more processing units each linked to each other via paths of communication and the circuit switch.

A system and method for managing memory resources. In some embodiments the system includes a first server, a second server, and a server-linking switch connected to the first server and to the second server. The first server may include a stored-program processing circuit, a cache-coherent switch, and a first memory module. In some embodiments, the first memory module is connected to the cache-coherent switch, the cache-coherent switch is connected to the server-linking switch, and the stored-program processing circuit is connected to the cache-coherent switch.

A system and method for managing memory resources. In some embodiments the system includes a first server, a second server, and a server-linking switch connected to the first server and to the second server. The first server may include a stored-program processing circuit, a cache-coherent switch, and a first memory module. In some embodiments, the first memory module is connected to the cache-coherent switch, the cache-coherent switch is connected to the server-linking switch, and the stored-program processing circuit is connected to the cache-coherent switch.

A system may receive, by a switching component of the system, network traffic to be provided to an I/O component of the network device. The system may route, by the switching component, the network traffic to the I/O component based on whether the I/O component is connected to the switching component via the first connections and/or via second connections. The first connections may be connections via a chassis of the system. The second connections may be connections via a connector component that is removable from the switching component. The network traffic may be routed via the first connections and the second connections when the I/O component is connected via the first connections and the second connections. The network traffic may be routed via the first connections and not via the second connections when the I/O component is connected via the first connections and not via the second connections.

This application provides a data communications system and method. The system includes a first chassis and a second chassis. The first chassis includes a first high-performance switching module and a first low-performance switching module. The second chassis includes a second high-performance switching module and a second low-performance switching module. The first high-performance switching module is connected to the second low-performance switching module. The first low-performance switching module is connected to the second high-performance switching module. The first high-performance switching module is configured to connect to a third low-performance switching module in a third chassis that is to be added to the communications system. The second high-performance switching module is configured to connect to a fourth low-performance switching module in the third chassis that is to be added to the communications system. During capacity expansion, there is no need to change cables between deployed chassis.