A communication device with receded ports includes one or more port connectors in a first position, one or more port connectors in a setback position that is receded back from the first position, and one or more port connectors in one or more additional setback positions. The communication device with receded ports includes, a circuit board, and one or more circuits mounted on the circuit board. Circuit traces electrically connect the port connectors in the first position, the setback position, and the one or more subsequent setback positions to a circuit mounted on a circuit board. The port connectors in the first position, setback position, and one or more subsequent setback positions may be situated in a triangular pattern, stair-stepped pattern, curved pattern, or some other pattern.

A system includes a first device that communicates a first configuration signal, an IP address and port identifier to a second device. The second device includes a router having a quality of service module therein. The second device deep packet inspects communication signals destined for the first device based on the IP address and port identifier. The quality of service module applies a quality of service policy to the communication signals based on deep packet inspecting to form modified communication signals. The first device performs a function in response to the modified communication signals.

The present disclosure generally discloses a network infrastructure virtualization mechanism configured to support virtualization of the network infrastructure (NI) of a communication network to provide thereby a virtualized infrastructure (VI) for the communication network. The network infrastructure virtualization mechanism may be configured to support virtualization of infrastructure resources (IRs) of the network infrastructure to provide virtualized infrastructure resources (VIRs) of the network infrastructure. The IRs of the communication network may include network resources (NRs) which may be virtualized to provide virtualized network resources (VNRs) and service resources (SRs) which may be virtualized to provide virtualized service resources (VSRs). The network infrastructure virtualization mechanism may be configured to support multi-owner virtualization such that multiple owners may share portions of the network infrastructure of the communication network and multi-tenant virtualization such that multiple tenants, at one or more hierarchical layers, may share portions of the network infrastructure of the communication network.

A network interface module can include a housing including a first cavity configured to receive a first network plug having a first dimension. The housing also includes a second cavity within the first cavity, and configured to receive a second network plug having a second dimension that is less than the first dimension. The network interface module can also include a network detection circuit operatively connected to a first terminal within the housing.

A method and system for configuring communications over a physical communication link connected between a physical port of a network switch and a physical port of a physical network interface on an end station. The communication link between the physical port of the network switch and the physical port of the physical network interface is logically partitioned into a number of channels of communication. For each channel, a channel profile is generated that defines properties of that channel. The physical network interface is instructed to self-configure such that the physical network interface is able to communicate with the network switch over each channel in accordance with the channel profile defined for that channel.

In an OpenFlow network, a “proactive type” is attained and hardware (HW) performance problem is solved. Specifically, in the OpenFlow network, each of a plurality of switches executes, on a reception packet that meets a rule of an entry registered in its own flow table, an operation based on an action defined in the entry. A controller registers an entry, in which an identifier unique to a path calculated based on a physical topology of a network composed of the plurality of switches is set as a rule and an output from a predetermined output port as an action, in each of the plurality of switches before communication is started among the plurality of switches.

Methods and systems are disclosed for providing a signaling protocol to enable a bi-directional point-to-point Ethernet Virtual Circuits (EVC) to be configured between any two network elements, as part of a network infrastructure. The bi-directional EVC is established by configuration of a source network element and a destination network element, and defines a bi-directional data path across the network infrastructure therebetween. The EVC may include one or more network elements over which the data path may traverse. The methods and systems disclosed may be applied to linear, ring and mesh network topologies.

A management device allocates a first identifier that identifies, from among tenants included in a multi-tenant system, a tenant that uses virtual machines running on the multi-tenant system. The management device performs the following process, for each terminating device, from among tenants in the multi-tenant system, on virtual machines that are running on a second network in which terminating devices are installed. Specifically, the management device allocates a second identifier that identifies a tenant that uses virtual machines running on the multi-tenant system. Furthermore, the management device creates, for each terminating device, conversion information in which the first identifier that is allocated to each of the virtual machines is associated with the second identifier. Then, the management device sets each terminating device such that a packet is encapsulated in accordance with the created conversion information.

Systems disclosed herein may allocate buffer space using methods, which prevent other resource allocation methods from apportioning the other resources in a way that inhibits system needs from being met. As such, buffer space may be dynamically allocated without impeding other resource allocation by basing the buffer space allocation at least on the traffic priority class that each allocated buffer will handle. Alternatively, buffer space may be dynamically allocated without impeding other resource allocation by basing the buffer space allocation at least on the bandwidth needs of each respective buffer being allocated. Alternatively still, buffer space may be dynamically allocated without impeding other resource allocation by basing the buffer space allocation at least on a function of the traffic priority class that each allocated buffer will handle and the bandwidth needs of each respective buffer being allocated.

Some embodiments provide a method for implementing a logical router in a network. The method receives a definition of a logical router for implementation on a set of network elements. The method defines several routing components for the logical router. Each of the defined routing components includes a separate set of routes and separate set of logical interfaces. The method implements the several routing components in the network. In some embodiments, the several routing components include one distributed routing component and several centralized routing components.