A building controller is configured to control one or more building system components of a building control system. In one example, the building controller includes a housing and one or more wiring terminals that are accessible from outside of the housing. A controller is housed by the housing and is operatively coupled to the one or more wiring terminals. The controller is configured to output one or more control commands on one or more of the wiring terminals. A managed network switch is housed by the housing and includes a plurality of network switch ports that are each accessible from outside of the housing and are each configured to be releasably secured to one or more network cables. The building controller is configured to receive user input for configuring one or more managed characteristics of the managed network switch.

A building controller is configured to control one or more building system components of a building control system. In one example, the building controller includes a housing and one or more wiring terminals that are accessible from outside of the housing. A controller is housed by the housing and is operatively coupled to the one or more wiring terminals. The controller is configured to output one or more control commands on one or more of the wiring terminals. A managed network switch is housed by the housing and includes a plurality of network switch ports that are each accessible from outside of the housing and are each configured to be releasably secured to one or more network cables. The building controller is configured to receive user input for configuring one or more managed characteristics of the managed network switch.

This disclosure describes methods, devices, and systems related to coordinating channel switch times and specifying device operation (for example, transmitting device operation) to ensure data reception by one or more devices (for example, receiving devices). A device may receive a data path setup request frame from a second device. The device may cause to send a data path setup response frame. The device may cause to establish a communication with the second device on a first channel. The device may cause to establish a communication with the second device on a second channel at a first time. The device may cause to wait, by the device, at least for a duration specified by a channel switch time (CST) parameter. The device may cause to send device data to the second device over the first channel or the second channel based at least in part on the CST parameter.

The present subject matter relates to methods, systems, devices, circuitry and equipment providing for communication service to be transported between first and second networks, and which monitors the communication service and/or injects test signals, and which can provide redundancy. At least one demarcation point or line is established between the first network and the second network, and/or between the first network, the second network and/or a third network. The Circuitry comprises a plurality of input amplifiers, output amplifiers, and multiplexer switches between a plurality of Port connectors. An SFP module or a WSFP module is inserted in the Ports.

In one embodiment, Ethernet Virtual Private Network (EVPN) is implemented using Internet Protocol Version 6 (IPv6) Segment Routing (SRv6) underlay network and SRv6-enhanced Border Gateway Protocol (BGP) signaling. A particular route associated with a particular Internet Protocol Version 6 (IPv6) Segment Routing (SRv6) Segment Identifier (SID) is advertised in a particular route advertisement message of a routing protocol (e.g., BGP). The SID includes encoding representing a particular Ethernet Virtual Private Network (EVPN) Layer 2 (L2) flooding Segment Routing end function of the particular router and a particular Ethernet Segment Identifier (ESI), with the particular SID including a routable prefix to the particular router. The particular router receives a particular packet including the particular SID; and in response, the particular router performs the particular EVPN end function on the particular packet.

In one embodiment, Ethernet Virtual Private Network (EVPN) is implemented using Internet Protocol Version 6 (IPv6) Segment Routing (SRv6) underlay network and SRv6-enhanced Border Gateway Protocol (BGP) signaling. A particular route associated with a particular Internet Protocol Version 6 (IPv6) Segment Routing (SRv6) Segment Identifier (SID) is advertised in a particular route advertisement message of a routing protocol (e.g., BGP). The SID includes encoding representing a particular Ethernet Virtual Private Network (EVPN) Layer 2 (L2) flooding Segment Routing end function of the particular router and a particular Ethernet Segment Identifier (ESI), with the particular SID including a routable prefix to the particular router. The particular router receives a particular packet including the particular SID; and in response, the particular router performs the particular EVPN end function on the particular packet.

The avionic system of an aircraft includes a set of avionic computers and a switch associated with each avionic computer. For each avionic computer of the set of avionic computers, the avionic system includes a communication link between the switch associated with this avionic computer and each of the switches associated with the other avionic computers. Each switch is configured such that it routes the data frames received on its input ports to its output ports in a manner predefined only on the basis of the input ports on which these data frames are received. The various switches are configured such that, when an avionic computer sends a data frame, this data frame is transmitted to all of the other avionic computers.

The avionic system of an aircraft includes a set of avionic computers and a switch associated with each avionic computer. For each avionic computer of the set of avionic computers, the avionic system includes a communication link between the switch associated with this avionic computer and each of the switches associated with the other avionic computers. Each switch is configured such that it routes the data frames received on its input ports to its output ports in a manner predefined only on the basis of the input ports on which these data frames are received. The various switches are configured such that, when an avionic computer sends a data frame, this data frame is transmitted to all of the other avionic computers.

Described herein are systems, methods, and software to enhance the implementation of communication rules in a computing network. In one example, a method of operating a communication settings system maintains communication rules for a plurality of networks, wherein the communication rules define forwarding actions for ingress and egress packets to and from applications in the plurality of computing networks. The service further identifies a configuration request from a computing network with applications executing in the computing network, identifies a subset of the communication rules based on the plurality of applications, and provides the subset of the communication rules to the computing network.

Described herein are systems, methods, and software to enhance the implementation of communication rules in a computing network. In one example, a method of operating a communication settings system maintains communication rules for a plurality of networks, wherein the communication rules define forwarding actions for ingress and egress packets to and from applications in the plurality of computing networks. The service further identifies a configuration request from a computing network with applications executing in the computing network, identifies a subset of the communication rules based on the plurality of applications, and provides the subset of the communication rules to the computing network.