The technologies disclosed herein provide improvements to the Low Extra Delay Background Transport (LEDBAT) protocol. Some aspects of the present disclosure introduce an adaptive congestion window gain for background connections. In some configurations, a gain value for influencing the transmission rate of a background connection is dynamically adjusted based on data indicating a round trip time (RTT). The RTT includes a sum of a time in which the data is communicated to a remote device and a time in which acknowledgement is data returned from the remote device. In some configurations, the gain is decreased when the RTT is below a threshold and the gain is increased when the RTT is above the threshold. Among other features, the present disclosure also provides techniques involving a modified slow-start, multiplicative decrease and periodic slowdowns. The features disclosed herein mitigate some existing issues, such as latency drift, inter-LEDBAT fairness, and unnecessary slowdowns.

A transmitting circuit includes: a multiplexer configured to output a third digital signal obtained by alternately synthesizing a first digital signal of a predetermined cycle length and a predetermined data rate with a second digital signal of the predetermined cycle length and the predetermined data rate; a first selector configured to output the first digital signal in a first state and output the third digital signal in a second state that is different from the first state; a second selector configured to output the second digital signal in the first state and output the third digital signal in the second state; a first driver circuit configured to output a signal corresponding to a signal output from the first selector; and a second driver circuit configured to output a signal corresponding to a signal output from the second selector.

A method includes: determining a target code block in a code block stream that is in a first rate mode and includes a plurality of code blocks, where the target code block includes a code block of a start type in the first rate mode; modifying information carried in a code block type field of the target code block to target information, where the target information includes information carried in a code block type field of a code block of a start type in a second rate mode; or the target information includes information carried in a code block type field of a code block of a terminate type in a second rate mode; and transmitting a code block stream in the second rate mode to a transport network, where the code block stream in the second rate mode includes a modified target code block.

In one embodiment, a plurality of data rates available for communication is identified at a first device in a network. Slots of a channel hopping schedule are also identified and the data rates are assigned to the slots of the channel hopping schedule to generate a data rate hopping schedule. The generated data rate hopping schedule is further provided to a second device in the network.

A circuit is provided to facilitate temporal redundancy for inter-chip communication. When an inter-chip communication channel fails, data bits associated with the faulty channel are steered to a non-faulty channel and transmitted via the non-faulty channel together with data bits associated with the non-faulty channel at an increased data rate.

The present disclosure relates to a communication method and system for converging a 5.sup.th-Generation (5G) communication system for supporting higher data rates beyond a 4.sup.th-Generation (4G) system with a technology for Internet of Things (IoT). The present disclosure may be applied to intelligent services based on the 5G communication technology and the IoT-related technology, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services.

An electronic device and method for processing a packet in an Internet Protocol (IP)-based network are provided. The method performed in an electronic device includes determining a network condition from a received signal, setting one of reference values set for corresponding network conditions as a transmission rate for the determined network condition, and transmitting the packet at the transmission rate.

Disclosed herein is a broadcasting system using a wireless communication system, including a subscriber to receive a broadcast signal and transmits an ACK signal or NACK signal depending on whether or not the broadcast signal is normally decoded; and a broadcast transmitter to transmit the broadcast signal and set a maximum throughput based on the ACK signal or NACK signal transmitted from the subscriber to transmit the broadcast signal. According to embodiments of the present invention, broadcast services can be provided with the maximum efficiency, and therefore power consumption may be reduced, radio resources may be prevented from being wasted. When broadcast services according to the present invention are used, desired advantages may be expected in terms of overall efficiency of a network.

Described are a method and apparatus for controlling the power consumption of a terminal, and a storage medium. The method includes: recording the number of times a connection between a terminal and an auxiliary cell group fails, and where the number of times is greater than a preset threshold value, controlling, on the basis of a power consumption adjustment policy, the terminal to disable a dual-connection mode, wherein the terminal can support the dual-connection mode, and in the dual-connection mode, the terminal communicates with both a first base station and a second base station, the second base station being an auxiliary base station, and the auxiliary cell group being a group of serving cells associated with the auxiliary base station.

Embodiments of the invention include a communication interface and protocol for allowing communication between devices, circuits, integrated circuits and similar electronic components having different communication capacities or clock domains. The interface supports communication between any components having any difference in capacity and over any distance. The interface utilizes request and acknowledge phases and signals and an initiator-target relationship between components that allow each side to throttle the communication rate to an accepted level for each component or achieve a desired bit error rate.