In various embodiments, a system comprising a network interface, a processor, and a non-transient memory medium operatively coupled to the processor is disclosed. The memory medium is configured to store a plurality of instructions configured to program the processor to receive a digital bit stream, transform the digital bit stream to an encoded digital bit stream. The encoded digital bit stream comprises at least one of a gateway channel, a composite channel, or a data channel, and any combination thereof, and provides the encoded digital bit stream to the network interface for transmission. A non-transitory computer-readable memory medium and a computer-implemented method also are disclosed.

Methods and apparatuses relating to data decompression are described. In one embodiment, a hardware processor includes a core to execute a thread and offload a decompression thread for an encoded, compressed data stream comprising a literal code, a length code, and a distance code, and a hardware decompression accelerator to execute the decompression thread to selectively provide the encoded, compressed data stream to a first circuit to serially decode the literal code to a literal symbol, serially decode the length code to a length symbol, and serially decode the distance code to a distance symbol, and selectively provide the encoded, compressed data stream to a second circuit to look up the literal symbol for the literal code from a table, look up the length symbol for the length code from the table, and look up the distance symbol for the distance code from the table.

A state transition method and apparatus based on ROHC, and a computer storage medium are disclosed. The method comprises: when a state machine of a compressor is in an IR state, transiting a state of the state machine to an FO state when a decompressor can only successfully parse a static field of a service stream packet header; and transiting a state of the state machine to an SO state when the decompressor can successfully parse the static field and a dynamic field; when the state machine is in the FO state, transiting a state of the state machine of the compressor to the SO state when the decompressor can successfully parse the dynamic field; and when the state machine is in the SO state, transiting a state of the state machine to the FO state when the decompressor fails to parse the dynamic field within a preset time threshold.

Provided are a data compression method and apparatus, and a storage medium. The method is used for a data sending end; the data sensing end can carry a plurality of services on a radio bearer; each service corresponds to a compression buffer. The method comprises: determining a first compression buffer corresponding to a service to which first data block to be sent belongs (S101); compressing the first data block using a dictionary corresponding to the first compression buffer to obtain compressed second data block (S102); encapsulating the second data block in a set message, and adding, to the set message, a compression identifier used for indicating the first compression buffer (S103); and sending, to a data receiving end, the set message carrying the compression identifier (S104). According to the present invention, data compression efficiency is improved, and efficient transmission of a plurality of services is achieved.

Embodiments of the present disclosure relate to methods, devices and computer readable storage media of communication. A network device transmits, to a terminal device, channel state information reference signals associated with first number of ports at the network device; receives, from the terminal device, compressed channel state information generated based on capability of the terminal device; and recoveries, from the compressed channel state information, channel state information associated with second number of ports at the network device, the second number of ports being not less than the first number of ports. The terminal device receives, from the network device, the channel state information reference signals associated with the first number of ports at the network device; determines channel state information based on the channel state information reference signals; compresses the channel state information based on capability of the terminal device; and transmits the compressed channel state information to the network device for recovery of the channel state information associated with the second number of ports. As such, CSI can be acquired more accurately with reduced complexity and overhead.

Disclosed are systems and methods that provide a communication framework that enables computerized functionality for a climate system's improved operation. The disclosed framework enables a location's climate system to be controlled via a centralized hub, which can be accessed remotely using a mobile application or web interface. The enabled communication network and functionality enables dynamic monitoring and control of the devices/components of a location's climate system, which can be effectuated from anywhere (e.g., at the location or away from the location), providing functionality for increased flexibility and convenience. The disclosed communication framework provides a reliable and secure wireless communication platform for climate system components, enabling improved energy efficiency, comfort and control for residential and commercial locations (e.g., buildings).

The size of a source application is reduced by compressing a plurality of invoked files, such as SO files, in the source application with a compression algorithm that has a higher compression rate compared to a default compression rate. A decompression file that corresponds with the compression algorithm is inserted into a plurality of invoking files in the source application so that the source application itself can decompress the invoked files that were compressed with the compression algorithm.

In various embodiments, a system comprising a network interface, a processor, and a non-transient memory medium operatively coupled to the processor is disclosed. The memory medium is configured to store a plurality of instructions configured to program the processor to receive a digital bit stream, transform the digital bit stream to an encoded digital bit stream. The encoded digital bit stream comprises at least one of a gateway channel, a composite channel, or a data channel, and any combination thereof, and provides the encoded digital bit stream to the network interface for transmission. A non-transitory computer-readable memory medium and a computer-implemented method also are disclosed.

A non-transitory computer-readable recording medium stores an encoding program that causes a computer to execute a process. The process includes first encoding a first character string in input data to a first code, when the first character string being registered in a first dictionary, the first code being associated with the first character string in the first dictionary; second encoding a second character string in input data to a second code and registering the second character string to a dynamic dictionary, when the second character string being not registered in the first dictionary, the second code being associated with the second character string and preliminary information in the dynamic dictionary; and generating encoded data including the encoded input data and the dynamic dictionary.

An amount of memory needed to hold prime data elements during reconstitution may be determined by examining the creation and usage of prime data elements and their spatial and temporal characteristics during data distillation.