A communication apparatus capable of data communication includes a controller that temporarily permits data communication of an application. Upon the application transitioning to the background, the controller maintains temporary permission for data communication of the application when the application transitioned to the background as a result of an interrupt not intended by a user, and prohibits data communication of the application when the application transitioned to the background as a result of an interrupt other than an interrupt not intended by the user.

The present invention is provided with the page responding unit 33, the login performing unit 31, the logout performing unit 35, the counting unit 37, and the logout managing unit 39. The page responding unit 33 submits a response of a Web page in response to an automatic request or a manual request from a user. The login performing unit 31 performs login by user authentication. The logout performing unit 35 performs logout of the user in a case in which the request from the user who logged in is not received within the login timeout period. The counting unit 37 counts the automatic request upon reception of the automatic request within the login timeout period. The logout managing unit 39 makes the logout performing unit 35 perform logout in a case in which the accumulated refreshing time exceeds the login timeout period.

A system for providing media services on behalf of a customer contact center includes: a processor; and a memory, wherein the memory has stored thereon instructions that, when executed by the processor, cause the processor to: transmit and receive signaling messages to and from a control server over an established data network connection; in response to the signaling messages, invoke a media device for transmitting media to an end-user device; detect loss of the data network connection; identify a configurable parameter for determining whether a failed message transmission should be retried; and in response to determining that the failed message transmission should be retried, re-transmitting the failed message to the control server.

Described are a login information transmission method, a code scanning method and apparatus, and a server. The login information transmission method includes: receiving user account number information and two-dimension code information sent from a client after the client logs in to an application and scans a two-dimension code; verifying the received user account number information and two-dimension code information; sending a confirmation request to the client, so as to request the client to confirm an application to be logged in to if verification passes; and sending login confirmation information to a corresponding application server, so as to instruct the application server to notify the client to log in to the application when confirmation pass information sent from the client is received.

In an example implementation of the disclosed technology, a method includes predicting, by a computing device, a destination server that is predicted to be the destination of a message from a sending device connected to the computing device. The method also includes determining whether a connection exists between the computing device and the destination server. The method also includes, responsive to determining that no connection exists, determining a connection and caching the connection at the computing device. The method also includes, responsive to receiving a message for dispatch to the destination server, dispatching the message to the destination server via the connection.

There is provided a system and method for automatically scaling a number of deployed application delivery controllers (ADCs) in a digital network. The method is conducted at a destination controller provided or accessed by a server computer. The destination controller receives telemetry data from a plurality of ADCs managed by the server computer. The destination controller also receives multiple data transfer requests originating from a plurality of user devices that are connected to the destination controller. A number of currently deployed ADCs for handling network traffic originating from the plurality of user devices may be detected by the destination controller or by the system. The telemetry data is intelligently processed, and the number of deployed ADCs is automatically scaled, based on the received telemetry data, or based on an output of an Artificial Intelligence (AI) module.

There is provided a system and method for automatically scaling a number of deployed application delivery controllers (ADCs) in a digital network. The method is conducted at a destination controller provided or accessed by a server computer. The destination controller receives telemetry data from a plurality of ADCs managed by the server computer. The destination controller also receives multiple data transfer requests originating from a plurality of user devices that are connected to the destination controller. A number of currently deployed ADCs for handling network traffic originating from the plurality of user devices may be detected by the destination controller or by the system. The telemetry data is intelligently processed, and the number of deployed ADCs is automatically scaled, based on the received telemetry data, or based on an output of an Artificial Intelligence (AI) module.

A Service Continuity Network Function (SCNF) may be used to provide service continuity support in IoT networks such as 3 GPP and oneM2M, whereby higher layer session and service information is associated with transport layer session information. By means of the SCNF, a higher layer service may be resumed when a new session or connection is created, without support for transport layer session continuity. The service continuity capabilities of the SCNF may be exposed to the service layer of the network by way of a resource data structure.

Disclosed is a novel system and method for maintaining computing functionality when a client device must be used in a low-power state. More particularly, when a client device is placed in a low-power state, sleep mode, or even shut-down, this method transfers aspects of the machine state onto a virtual machine in the cloud. This virtual machine may then function as a partial or full emulator of the user's client machine and thus can be: 1) accessed; and 2) communicated with by the machine's owner or others who use the machine. As long as the client device is shutdown, the cloud continues to temporarily function as the user's machine. Numerous embodiments are disclosed including a “hybrid decomposition feature” in which the data on the client machine is prioritized and then transfer to a server, typically a virtual emulator, component by component or piecemeal manner or manner.

An information processing system comprising a memory, and a processor coupled to the memory and configured to receive requests from a plurality of client apparatuses, store, in the memory, information about sessions established to communicate with the plurality of client apparatuses, store, in the memory, a request in response to which processing has not yet been started, the request being one of the requests received from the plurality of client apparatuses, detect a session during which a predetermined time-out time has elapsed in a state in which processing demanded by a request corresponding to the session is not being executed, the session being one of the sessions, information about the sessions being stored in the memory, and suppress, when a request received from a client apparatus corresponding to the detected session is stored in the memory, invalidation of the session due to an elapse of the time-out time.