Aspects of the present disclosure describe transmitting data in wireless communications. A set of packets for transmission in a defined sequence can be received where the set of packets includes two or more packets. It can be detected that a packet, of the set of packets, is a prioritized packet type. The packet can be prioritized for transmission ahead of its order in the defined sequence based on the detection of the prioritized packet type. The packet can be transmitted ahead of its order in the defined sequence to an access point.

A device may obtain first information related to a digital service that may identify a digital path. The digital path may include digital nodes and optical links, of an optical network, to provide the digital service. The device may determine second information based on the first information. The second information may describe a relationship between one or more digital services and one or more digital paths. The device may provide a graphical representation, via a user interface, of the one or more digital paths. The device may provide the second information in relation to the graphical representation. The device may detect a user interaction with the graphical representation. The user interaction may relate to one or more of the digital services and/or one or more of the digital paths. The device may cause the digital nodes and/or the optical links to be configured.

A technique includes receiving, by a user device from abase station in a wireless network, a downlink control information associated with a priority downlink data transmission from the base station that preempts an ongoing data transmission; determining, by the user device based on the downlink control information, a set of resources allocated for a priority uplink transmission, wherein the set of resources allocated for the priority uplink transmission were previously indicated by the base station as allocated for other use; and sending, by the user device, an uplink transmission via the set of resources allocated for priority uplink transmission.

A transfer device for coupling a priority signal and a standard signal includes a reception unit configured to receive a plurality of signals transmitted from a device connected to a path different from a forwarding path, a separation unit configured to separate the signals into the priority signal and the standard signal, an identifier reference unit configured to reference an identifier added to the standard signal, an identifier sort unit configured to sort the standard signal by the identifier, a signal coupling unit configured to couple the plurality of standard signals, a multiplexing unit configured to multiplex the priority signal and the standard signal, a priority control unit configured to determine a transfer order of the signals, a transmission unit configured to transmit the signals to a device connected to the forwarding path, an interrupt transfer processing unit configured to perform interrupt processing in a case where the priority signal arrives during transfer of the standard signal, a signal division unit configured to divide the standard signal, an identifier addition unit configured to add the identifier to the standard signal divided, and a transmission suspending unit configured to suspend transfer of the standard signal until transfer of the priority signal is completed.

Disclosed herein is technology to reduce latency of frames through a network device supporting various priorities. In an implementation, a method comprises configuring one or more priorities with a preemptive right over other one or more of said plurality of priorities; receiving frames in a sequence, each of the frames having a frame priority comprising of one of said plurality of priorities; queuing the received frames in a predetermined order based on a frame arrival time and the frame priority; transmitting a current frame based on a current frame priority and current frame arrival time; stopping transmission of the current frame when a later frame in the sequence is received that has a later frame priority with preemptive right over the current frame priority; transmitting an invalid frame check sequence; transmitting the later frame; and restarting the transmission of the current frame after transmitting the later frame.

The invention relates to transmission of communication signal frames by a communicating entity in a packet-switched network, the communicating entity comprising an egress port for transmitting communication signal frames. The frames comprise a first type of frames, intended to be transmitted in a plurality of bursts for which a traffic shaping is defined as an express traffic, and a second type of frames, for which no traffic shaping is defined, as a sporadic traffic. The communicating entity is configured for storing a plurality of first queues of frames of the first type, associated respectively to the aforesaid plurality of bursts, and at least one second queue for frames of the second type. The bursts are stored in respective first queues with a signaling frame preceding each burst, and this signaling frame comprises a timestamp of generation of said burst. Then, for selecting a first burst to transmit among the bursts stored in said first queues, the communicating entity is configured for: —Reading the timestamp of each signaling frame located at a head of each first queues, —Determining among all the signaling frames the one having the most ancient timestamp, and —Select the burst having the thus determined signaling frame as the first burst to transmit.

In an information processing apparatus configured to utilize a first speech recognition function provided by an external speech recognizer via a communication network to execute a speech recognition processing, a processor is configured to detect trigger information, which shows that a user wishes to start the speech recognition processing, predict a future communication state, and inform the user of a state of the speech recognition processing based on the predicted future communication state when the trigger information is detected.

Processes and systems to allow for pre-emption of transmissions scheduled on configured grant resources, and subsequent autonomous retransmission using a subsequent occurrence of the configured grant resources.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment may determine that processing or transmission associated with a scheduling request is preempted, and perform one or more scheduling request preemption actions, associated with the scheduling request, based at least in part on determining that the processing or transmission is preempted. Numerous other aspects are provided.

A communication method in a communication device includes storing a first type of data and a second type of data belonging to a same access category defined by IEEE802.11 series, contending for access according to an enhanced distributed channel access, EDCA, using first EDCA parameters, to a communication channel in order to transmit the first type of data to another communication device; and contending for access according to the EDCA, using second EDCA parameters different from the first EDCA parameters, to the communication channel in order to transmit the second type of data to the other communication device.