A client device (e.g., user equipment or “UE”) may be configured to engage in a media communication session, such as a WebRTC session, with another client device. The client devices may separate a quality of service (QoS) specification from a QoS flow definition, to allow for separate interactive connectivity establishment (ICE) negotiation. The QoS specification may cover all segments of a connection for the media communication session. For example, QoS may be requested for a case where a server (e.g., a Traversal Using Relay Network Address Translation (TURN) server) is hosted by a mobile network operator (MNO). The QoS specification and the QoS flow description may be linked.

The present invention relates to systems and methods suitable for verifying and compensating nodes for streaming multimedia. In particular, the present invention relates to systems and methods that utilize a blockchain to verify and compensate devices for computational resources contributions when streaming multimedia over a decentralized network.

Establishing a communication channel via a relay server with reduced setup time. Upon request by an initiating communication device a relay allocation server may allocate a single relay server for use in a communication session between the initiating communication device and one or more recipient communication devices. The relay server may be selected to perform favorably for the initiating communication device. Messaging for establishment of the communication session may be performed using persistent messaging connections, to avoid connection establishment cost. Messaging may also be performed using address tokens to avoid the cost of discovering global IP addresses. Following establishment of the communication session, the relay server may discover the IP address of one or more recipient communication devices, and may initiate reallocation of those devices to another relay server.

Establishing a communication channel via a relay server with reduced setup time. Upon request by an initiating communication device a relay allocation server may allocate a single relay server for use in a communication session between the initiating communication device and one or more recipient communication devices. The relay server may be selected to perform favorably for the initiating communication device. Messaging for establishment of the communication session may be performed using persistent messaging connections, to avoid connection establishment cost. Messaging may also be performed using address tokens to avoid the cost of discovering global IP addresses. Following establishment of the communication session, the relay server may discover the IP address of one or more recipient communication devices, and may initiate reallocation of those devices to another relay server.

In a communication system, a first mediation apparatus includes a first control device. The first control device stores in a memory a correlation database correlating a mediation apparatus ID of the second mediation apparatus with a first device ID of a device. The first controller requests a management server to register the first device ID, and receives a first command from the management server. The first controller transmits a second command to the second mediation apparatus through the firewall by using a series of procedures. The second command includes second instruction information based on the second command. The first controller transmits a first response to the management server. The second mediation apparatus includes a second control device to initiate the series of procedures and transmits a third command based on the second command to the device, and transmits a second response as to the first mediation apparatus through the firewall.

In a communication system, a first mediation apparatus includes a first control device. The first control device stores in a memory a correlation database correlating a mediation apparatus ID of the second mediation apparatus with a first device ID of a device. The first controller requests a management server to register the first device ID, and receives a first command from the management server. The first controller transmits a second command to the second mediation apparatus through the firewall by using a series of procedures. The second command includes second instruction information based on the second command. The first controller transmits a first response to the management server. The second mediation apparatus includes a second control device to initiate the series of procedures and transmits a third command based on the second command to the device, and transmits a second response as to the first mediation apparatus through the firewall.

A method and a call routing system (CRS) are provided for routing an incoming call made to one of multiple numbers of a user to a call receiving client application (CRCA) deployed on one or more user devices when the called number is not reachable. The CRS, in communication with the CRCA deployed on one or more user devices, sets up a user account using one or more of the user's multiple numbers. The CRS detects availability of the CRCA on one or more user devices over a data network to accept an incoming call. The CRS receives the incoming call made to one of the numbers, when the called number is not reachable. The CRS routes the incoming call to the CRCA on one or more user devices over the data network on detecting the availability of the CRCA on one or more user devices over the data network.

Various systems and methods for dynamically registering a communication device with a network are disclosed. As one example, a system is disclosed that includes a home feature server, a central feature server, and a floating feature server. The floating feature server is communicably coupled to at least the home and central feature servers, and the home feature server is communicably coupled to at least the central feature server. The home feature server is associated with a communication device. The floating feature server is communicably coupled to a computer readable medium that includes instructions executable by the floating feature server to: receive an access request from the communication device; issue a services request to the home feature server; and service the access request. In some cases, the computer readable medium further includes instructions executable to determine that the first services access request failed, and to issue a second services access request to the central feature server. Various other embodiments and/or features are also disclosed.

Systems and methods for routing data in a network are described. A client device may send a request for video data that has been captured by a camera of a security system. A gateway of the security system may receive the request and determine if the client device is able to support encryption. The gateway may select a protocol with which to transmit the video data to the client device according to a priority attribute of the protocol and the capability of the client device to support encryption. The video data may be sent to the client device via the selected protocol.

Embodiments disclosed herein provide systems and methods for controlling bandwidth across a network address translation (NAT) system. In a particular embodiment a method provides, identifying a first endpoint and a second endpoint to a communication session. The first endpoint is located within a domain of the NAT system and the second endpoint is located outside to the domain. The method further provides determining a bandwidth limitation for the communication session and exchanging communications between the first and second endpoints in accordance with the bandwidth limitation.