A packet forwarding network may include spine and leaf switches that forward network traffic between end hosts that are coupled to the packet forwarding network. A controller may control the switches in the forwarding network to implement desired forwarding paths. The packet forwarding network may additionally include access switches that are directly connected to edge switches to form access switch groups. The access switches may also be controlled by the controller. End hosts may be coupled to access switches as well as leaf switches to extend the reach of the packet forwarding network. Additionally, the access switches may include access-leaf switches and access-edge switches to improve network routing capabilities and network flexibility.

The in-vehicle communication device includes a CAN communication unit, an Ethernet communication unit, a controller that controls communication by the CAN communication unit and the Ethernet communication unit, a first voltage output unit that outputs a first voltage, and a second voltage output unit that outputs a second voltage lower than the first voltage. The second voltage output is applied to the Ethernet communication unit. The first voltage output by the first voltage output unit and the second voltage output by the second voltage output unit are applied to the CAN communication unit. An opening/closing unit is provided between the second voltage output unit and the Ethernet communication unit. When a predetermined operation in the vehicle has been detected, the controller puts the opening/closing unit into an open state and cuts off the supply of power from the second voltage output unit to the Ethernet communication unit.

A monitoring device is one of a plurality of monitoring devices to be attached to mobility. The monitoring device is configured to monitor an abnormal state of a first object to be monitored. The monitoring device includes a receiver and a controller. The receiver is configured to receive a result of detection of an abnormality detected by another monitoring device that monitors an abnormal state of a second object to be monitored that is different from the first object to be monitored. The controller is configured to change a process to be performed by the monitoring device, according to the result of detection of the abnormality detected by the other monitoring device.

An in-vehicle communication system includes first and second switch devices that perform a relay process of relaying data in an in-vehicle network, the first switch device includes a switch unit and a processing unit that performs the relay process via the switch unit, the switch unit transmits target data to the second switch device instead of outputting the target data to the processing unit when an abnormality in the processing unit is detected, the target data being data which is received from a device other than the second switch device and is to undergo the relay process performed by the processing unit, and the second switch device performs a proxy process of relaying the target data received from the switch unit instead of the processing unit.

A switch device is a switch device that relays data in an in-vehicle network and including a plurality of first communication ports which are connectable to a plurality of functional units in a vehicle, and includes a plurality of first communication circuits disposed corresponding to the first communication ports and capable of communicating with the functional units via the corresponding first communication ports, one or more second communication circuits different from the plurality of first communication circuits, a switching unit capable of switching a connection destination of each of the first communication ports between the corresponding first communication circuit and the second communication circuit, and a control unit that controls the switching unit such that a connection destination of a target port which is the first communication port serving as a target is switched to the second communication circuit when a predetermined condition is satisfied.

A method for transmitting real-time messages in a computer network (100), in particular real-time computer network, wherein said network comprises two or more computing nodes (21, 22, 23, 24, 25, 26) and one or more star couplers (1, 2, 3, 4), wherein said nodes are interconnected via at least one star coupler, wherein each node is connected to at least one star coupler via at least one of the communication links (50), and wherein the nodes exchange messages (M1, M2) with one another and with the at least one star coupler, and wherein star couplers, which are synchronized to a global time base (C), transmit a first non-empty set (SSET) of real-time messages according to a synchronized communication paradigm, and/or wherein computing nodes, which are synchronized to the global time base, transmit said first non-empty set of real-time messages according to the synchronized communication paradigm, wherein a star coupler, which is not synchronized to a global time base, and/or a computing node, which is not synchronized to a global time base, transmits a second non-empty subset (CSET) of said first non-empty subset of real-time messages according to an unsynchronized communication paradigm and stops the transmission of said second non-empty subset of real-time messages according to the synchronized communication paradigm.

A server system may include a plurality of internal hubs communicatively coupled to a plurality of server nodes. The plurality of internal hubs may communicate with an external hub to transmit broadcast traffic to reach a designated server node. A hub controller, a routing device coupled to the plurality of internal hubs, may select an internal hub from among a plurality of internal hubs based on a link status and a set of hub selection rules. Based on a status of active link and a relative priority of internal hubs, an internal hub is selected as a transmission channel to receive broadcast traffic from the external hub and direct the broadcast traffic to a corresponding server node.

Heterogeneous capabilities in an overlay fabric may be provided. First, it may be determined that a first link and a second link support a feature. Then the first link and the second link may be traversed with traffic between a host in a first Endpoint Group (EPG) connected to a first leaf switch and a second host in a second EPG connected to a second leaf switch when a topology preference for the feature is indicated for the traffic.

Certain embodiments described herein are generally directed to configuring a generic channel for exchanging information between a hypervisor and a virtual machine run by the hypervisor that resides on a host machine. In some embodiments, the generic channel represents a network or communication path enabled by a logical switch that connects a HyperBus running on the hypervisor and a node agent running on the virtual machine. In some embodiments, network traffic handled by the generic channel is isolated from incoming and outgoing network traffic between the virtual machine and one or more other virtual machines or hosts.

An operation method of a first communication node comprises: receiving a first frame from a second communication node; obtaining a destination address of the first frame; and transmitting a second frame including an indicator for indicating an occurrence of an error in the first frame to a communication node corresponding to a source address of the first frame, when a port corresponding to the destination address does not exist in a routing table.