Deadlocks in a multi-protocol heterogeneous packet-based transport system are avoided while maintaining real-time aspects. When receiving a plurality of packets from a root complex where contents of each packet from the plurality of packets organized in accordance with a first protocol, a sequence number is added to each packet and a packet type is identified. Every packet in the first plurality of packets is encapsulated into at least one packet organized in accordance with a second protocol to form a second plurality of packets organized in accordance with the second protocol. All the packets from the second plurality of packets are sent via a plurality of connections so that each connection from the plurality of connections only transports packets from the second plurality of packets that encapsulate packets from the first plurality that have a same packet type.

When an access point device is aware of an internet access failure, the access point device can attempt to re-route the baseband content through a different access point for the purpose of using its hard-wired internet connection. An administrative function can allow the access point device to tunnel through the internet service provider (ISP) of another access point device if permission is granted to do so. The permission can be granted beforehand or it can be granted to on the fly. Consequently, if the packets cannot route via the normal, hard-wired path, a message to a secondary transceiver of the access point device can instruct the access point device to find an alternate path via the ISP of the other access point device.

An industrial controller with a modular backplane includes multiple modules, where each module includes a base and a chassis. Electrical connectors located on each side of the base engage the base of an adjacent module such that the bases are electrically connected. The backplane is defined by and extends through each of the bases connected to each other. A chassis is inserted into each base. Each chassis includes an embedded switch and a local circuit. The embedded switch is in communication with the base, and the local circuit performs the operation of the corresponding module. The embedded switch receives data transmitted along the backplane between bases. The embedded switch reads the data intended for the module and passes the data to the local circuit for further processing. Similarly, the embedded switch receives data from the local circuit and inserts the data on the backplane for transmission to the appropriate module.

Through the identification of different packet-types, packets can be handled based on an assigned packet handling identifier. This identifier can, for example, enable forwarding of latency-sensitive packets without delay and allow error-sensitive packets to be stored for possible retransmission. In another embodiment, and optionally in conjunction with retransmission protocols including a packet handling identifier, a memory used for retransmission of packets can be shared with other transceiver functionality such as, coding, decoding, interleaving, deinterleaving, error correction, and the like.

Apparatus, systems and methods for receiving one or more input signals and providing output signals in various video, audio, data and mixed formats are described. One or more input processors receive the input signals. Each of the input processors provides one or more packetized signals corresponding to one or more of the input signals received at the input processor. Each output processor can receive one or more packetized signals and generate one or more output signals. The output signals correspond to one or more of the input signals, additional locally generated signals or data relating to the signals or any combination of such signals. Use of a packet router according to the invention allows input signals encoded as one set of packetized signals to be recombined to provide additional packetized signals incorporating the same or different combinations of the packetized signals.

In general, in one aspect, the disclosure describes a Universal Plug and Play (UPnP) Remote Access Server (RAS) to provide a communication channel between UPnP Remote Access Clients (RACs) connected thereto. The UPnP RAS maintains local discovery information for UPnP devices connected to a local network and remote discovery information for remote UPnP devices communicating therewith. The UPnP RAS provides the remote UPnP devices communicating therewith with the local discovery information and the remote discovery information. The remote discovery information is utilized by a first remote UPnP device to discover a second UPnP device and vice versa. After discovery, a first remote UPnP device can communicate with a second UPnP device and vice versa.

Some embodiments of the invention provide a a method of processing packets associated with a logical switching element implemented by multiple physical switching elements executing on multiple host computers on which multiple machines execute. At a first physical switching element of a first host computer, the method receives a packet from a first machine associated with the logical switching element. For the packet, the method identifies a logical ingress port of the logical switch that is associated with the packet. For the packet, the method also uses the logical ingress port to identify a logical egress port of the logical switch that is associated with the packet. For the packet, the method also uses the logical egress port to identify a physical egress port of the first host computer to use to send the packet along to a second machine associated with the logical egress port. From the identified physical egress port, the method forwards the packet with an encapsulating header that stores the logical egress port.

Technology for characterizing internet application performance is described. An example method may involve, analyzing client requests from a plurality of internet service providers, the client requests comprising requests to access media items and being associated with internet service provider identities; identifying a set of the client requests that are associated with a first internet service provider; determining for at least one client request of the set: a request time, a payload data quantity, and an elapsed time; calculating a transfer rate comprising an application level throughput for the at least one client request, the transfer rate being based on the payload data quantity and the elapsed time; and calculating a performance measurement of the first and second internet service providers, the performance measurements being based on the transfer rate and on a portion of the set of client requests that have a transfer rate meeting a transfer threshold.

Embodiments of the present invention provide a system for dynamically monitoring and filtering data packets associated with accessing one or more entity resources. The system is configured for identifying a data packet in a network comprising at least one data unit, determining that the data packet is attempting to access an entity resource, determining if the at least one data unit of the data packet comprises a signature bit, and allowing or denying the at least one data unit in the data packet to access the entity resource based on determining if the at least one unit comprises the signature bit.

Techniques for operationalizing workloads at edge network nodes, while maintaining centralized intent and policy controls. The techniques may include storing, in a cloud-computing network, a workload image that includes a function capability. The techniques may also include receiving, at the cloud-computing network, a networking policy associated with an enterprise network. Based at least in part on the networking policy, a determination may be made at the cloud-computing network that the function capability is to be operationalized on an edge device of the enterprise network. The techniques may also include sending the workload image to the edge device to be installed on the edge device to operationalize the function capability. In some examples, the function capability may be a security function capability (e.g., proxy, firewall, etc.), a routing function capability (e.g., network address translation, load balancing, etc.), or any other function capability.