Techniques for improving data transmission in teleoperation systems including a method for dynamic packet routing. The method includes identifying an optimal channel of a plurality of channels based on a network connectivity status of a system and historical connectivity data related to a current location of the system, wherein the system includes a plurality of network authorization devices, wherein each network authorization device is configured to enable communications via an associated channel; and routing packets to the optimal channel using a network authorization device of the plurality of network authorization devices that is associated with the optimal channel.

Embodiments provide an SDN, an SDN configuration method, an SDN-based data transmission method, and a network controller. A data packet combination function and a data packet split function are separately configured on nodes in the SDN. Therefore, when data packets of a first service are received, multiple small data packets of the first service may be combined into one large data packet. In comparison with transmission of the multiple small data packets, transmission efficiency of the SDN can be improved by transmitting the combined data packet.

A communication device performs data transfer from a first device holding a data group to a second device that stores received data as a record of transfer. The communication device includes a storage that stores transmitted data as a record of transfer, and a processor configured to acquire, from the first device, data matching a predetermined condition among the data group, stores first data that is not retained in the storage, among the acquired data, in the storage, transmit the first data to the second device, and transmit, to the second device, when transfer of the first data from the first device to the second device is started in response to an acquisition request for the first data, identification information of the first data having a smaller size than the first data.

Non-limiting examples of the present disclosure describe detection of gross motion of a region of content. Gross motion of a region of content may be detected. A determination may be made as to a current quality level of the region. Based on detection of the gross motion, residual values may be generated for a progressive update of the region. The residual values are generated using the current quality level of the region as a base to determine a quantization update for a progressive update of the region at a higher quality level as compared with the current quality level of the region. Frame data for the progressive update of the region may be encoded. The frame data may comprise the residual values and motion vectors for progressive update of the region. The frame data may be transmitted for decoding. Other examples are also described.

A method for highly efficient and parallel data transfer and display with event alerting includes employing an aggregation server to receive and filter multiple Internet data feeds, including an event list, streaming each Internet data feed to an input device as a streamed data segment, displaying each data segment in an interactive stacked ticker display on the remote computing device, determining a location of the input device, displaying an event alert in the interactive stacked ticker display if the input device location comes within a threshold distance of an event location, and enabling a user to purchase tickets to the event corresponding to the event alert.

Dynamic history multistream long range compression (DHC) techniques are described for efficiently compressing multiple, prioritized data streams received over a channel. A history buffer is associated with each received stream and a DHC compressor dynamically allocates fixed sized history sections to and from each history buffer. In implementations, the DHC compressor makes stream history size adjustments prior to compressing a block of data and sends information identifying the change in history size to a DHC decompressor. The DHC decompressor sends signaling information to the DHC compressor that is used to ensure that the DHC decompressor can operate with a fixed amount of total history memory.

A radio unit configured to connect to a baseband processing unit includes a transformation unit configured to obtain uplink time domain signal data and transform the uplink time domain signal data into uplink frequency domain signal data; and a compression unit configured to compress the uplink frequency domain signal data by using a compression algorithm.

A method and an apparatus for forwarding a multimedia message are provided. The method for forwarding a multimedia message includes that a gateway receives a compressed multimedia message from a terminal, the gateway parses the received multimedia message to acquire a compression type parameter which is adopted for the compression at the terminal and is carried in the received multimedia message, the gateway decompresses the received multimedia message according to the compression type parameter to obtain a decompressed multimedia message, and the decompressed multimedia message is sent to an MMS center. According to the technical solution of the present disclosure, the gateway decompresses the received multimedia message and then sends the decompressed multimedia message to the MMS center in a conventional way, and the multimedia message downloaded from the MMS center is sent to the terminal in a compression form, so that the waste of network resources can be avoided effectively and the speed of uploading and downloading the multimedia message is increased.

A method, apparatus and non-transitory computer medium are provided for obtaining a required frame size for a first compressed data frame to be generated by compressing at least a first data frame of a media file, the first compressed data frame for use by a user equipment in a communications network. The method comprises, responsive to receiving a request for the media file from the user equipment, retrieving at least metadata of the media file. The required frame size for the first compressed data frame is determined based on a size of the at least a first data frame as indicated by the metadata, a compression parameter indicative of a requested compression factor for the at least a first data frame and a biasing factor that acts to reduce the effect of the requested compression factor.

Dynamic and selective compression for content caching is provided for improving content delivery over a digital network. The dynamic and selective compression increased server cache size for higher cache-hit ratios that offset delays associated with compressing and decompressing content. The dynamic compression involves switching between an available set of compression tools in order to compress different files with the compression tool that is optimal for that file. The selective compression involves selectively compressing the content or files with the optimal compression tool when at least a threshold amount of space savings is obtained in an acceptable amount of time. Thus, the caching server caches compressed copies of a first set of files compressed with a first compression tool, compressed copies of a second set of files compressed with a different second compression tool, and an uncompressed third set of files.