A distributed networking system and protocol is provided to a networking system with a modular design. The distributed networking system may include a networking system, modules, control module, user interface module, input/output module, network module, data transmission network, hybrid modules and composite modules. A method to interface with accessories of a system with a modular design using the distributed networking system and protocol is also provided.

Providing a template for orchestration of a cloud provided service in a datacenter. This template can include virtual processing services, virtual networking services, storage services, and service level requirements that a user or administrator can select for the cloud provided service. Based on the template the cloud provided service can be provisioned according to the requirements of the service level agreement.

Disclosed are systems, methods, and devices for managing a plurality of remote devices of disparate types. There is maintained an electronic device definition repository comprising: a plurality of semantic model definitions for corresponding devices of the plurality of remote devices. An action request for an action to be performed by one or more selected devices of the plurality of remote devices is received. For each one or more selected devices, the action request is processed including: converting a generic device action and a generic device property to a device-specific action and a device-specific property using the semantic model definition for the selected device; establishing one or more messages for communicating the device-specific action request to a given selected device using the data protocol definition for the selected device; translating the one or more messages of the sequence of messages to an application protocol suitable for communication with the selected device.

Embodiments of a device and method are disclosed. In an embodiment, a method of communications involves generating a packet for communications in a wired communications network, where the packet includes a header and a payload, and where the header includes packet type information that indicates a network connection within the wired communications network in which the packet is used, and transmitting the packet through the network connection.

A technology is provided for invoking a random linear network coding (RLNC) communications protocol between a client and server in a network. In one example, a synchronize message requesting a network connection to a server can contain an indication that a client supports the RLNC communications protocol to encode and decode data packets using random linear network coding. The server can analyze the synchronize message for the indication that the client supports the RLNC communications protocol and send an acknowledge message to the client indicating that the server supports the RLNC communications protocol. Thereafter, the server can listen on a communications channel for a connection request sent by the client to communicate with the server using the RLNC communications protocol.

New data processing and transmission method is disclosed. A node executing at least one of protocol layer software downloads software from protocol software server. Each node in network has a node type associated with it and node type is defined by the protocol software layer that node executes. Protocol layer selector selects the protocol layer software running in a node. Communication starts when protocol completion is achieved, and protocol completion is achieved when combination of nodes executes all protocol layers of communication standard.

A vehicle controller, a system including the same, and a method thereof are provided. The vehicle controller includes a communication device that receives a diagnostic message for diagnosing of a vehicle from an external diagnostic device and a processor that identifies the diagnostic message and controls the communication device to transmit data generated in the vehicle under a transport protocol (TP) selected between a first TP configuring data to a predetermined size and a second TP configuring data to a variable size, the second TP being distinguished from the first TP.

According to a method for encapsulating or decapsulating a general data stream, one or more data sections are obtained by encapsulating data of a transport object based on a format of the general data stream. The data section includes a data section head and a data section payload. The data section head includes a basic section head and an extension section head or includes the basic section head only. The basic section head includes a transport object identity, a data section length, a data section payload encapsulation mode and an extension section head flag. The encapsulation mode uses a variable-length packet encapsulation mode, a fixed-length packet encapsulation mode or a stream encapsulation mode. The flag indicates whether there is the extension section head and the extension section head includes at least one extended parameter. The one or more data sections are concatenated to obtain and transmit the general data stream.

A packet sending method includes generating, by a network device, a first packet, and sending the first packet. The first packet includes a first packet header, a second packet header, and protected data. The first packet header includes an indication field. The indication field indicates that the first packet includes the second packet header. The second packet header includes a type field. The type field indicates a first protection protocol. The protected data is protected by using the first protection protocol.

Presented herein are techniques that provide for a way to associate a policy, or signal the policy for a user equipment (UE), directly from the UE traffic, inband or, in other words, within the data plane. The policies are effectively embedded in the address of the UE traffic. When the Neutral Host Network (NHN) receives the UE traffic, the policy can be determined directly from the address associated with the UE traffic. This provides for a unique way of integrating a service chain identifier in the Internet Protocol address of the UE to identify the services/policies to be applied to UE traffic in a stateless manner.