A method (200) of bias cancellation for a radio channel sequence includes: receiving (201) a radio signal, the radio signal comprising a radio channel sequence coded by a first signature, the first signature belonging to a set of orthogonal signatures; decoding (202) the radio channel sequence based on the first signature to generate a decoded radio channel sequence; decoding (203) the radio channel sequence based on a second signature, wherein the second signature is orthogonal to the signatures of the set of orthogonal signatures, to generate a bias of the radio channel sequence; and canceling (204) the bias of the radio channel sequence from the decoded radio channel sequence.

Embodiments of the present disclosure disclose a method and an apparatus for bearing a flexible Ethernet service on an optical transport network (OTN). The method includes extracting a flexible Ethernet service from a flexible Ethernet service layer; performing data division on the flexible Ethernet service to obtain at least two data queues, where each data queue carries a queue identifier; mapping each data queue into an OTN container, where the OTN container includes an optical channel data unit-k (ODUk) container or an optical channel data unit flexible container; and sending the OTN containers to an OTN. By using the embodiments of the present disclosure, bandwidth utilization can be improved, and network construction costs of an OTN can be reduced.

In one example, a network controller manages a network having many network devices. Network devices can receive the timing flow port role assignments from the network controller based on the controller's global view of the network topology. The controller can also calculate timing offsets to be applied to the network devices, based on timestamp information obtained by the network devices via exchanging time synchronization protocol messages, and the controller can update time clocks on all of the network devices within a single window of time, based on a timing offsets calculated in single iteration of calculations.

The present technology relates to a signal processing device, a method thereof, and a program capable of inhibiting deterioration in reception sensitivity. According to the present technology, in a case where a frequency band is vacant on the basis of a result of carrier sense, a data frame is transmitted as a wireless signal in the frequency band, and further, a synchronous frame formed of predetermined information different from that of the data frame is transmitted as a wireless signal in the frequency band in a case where the data frame is transmitted predetermined number of times within first time. Also, in the present technology, in a case where the synchronous frame is detected, the data frame is detected from a reception signal of predetermined time before the synchronous frame. The present technology is applicable to, for example, a signal processing device, an information processing device, a signal transmission device, a signal reception device, a signal transmission/reception device, a communication device, an electronic device, a computer, a program, a storage medium, a system and the like.

Network discovery and synchronization for new radio (NR) shared spectrum (NR-SS) is discussed for a wireless network having a super frame configuration on a shared spectrum shared between a plurality of network operators. A base station may obtain a discovery preamble from a plurality of network entities within the wireless network, wherein each of the plurality of network entities belongs to one or more of the plurality of network operators and shares the super frame configuration. The base station detects the timing of the super frame configuration using the discovery preamble and may then synchronize the base station to the super frame configuration according to the detected timing.

An information processing device of a cooperative system that further includes a portable device includes: a display that displays an image; a position detector that detects a position on a display surface of the display with which an object has made contact; and a hardware processor that detects the portable device in response to the position detector detecting a position with which an object has made contact, establishes a communication path with the portable device, switches an independent mode not cooperating with the portable device to a cooperation mode cooperating with the portable device when a communication path with the portable device is established and the portable device is detected by the hardware processor, and displays a related image that is related to the portable device on the display in response to the hardware processor no longer detecting the portable device in the cooperation mode.

Disclosed is a switching network synchronization method, which is applied to a first switching device. The method comprises: receiving a first suspected target ID; the first suspected target ID being an ID corresponding to a suspected target switching device determined by an access device connected to the first switching device according to a first identity number ID; receiving via the access device a second suspected target ID sent by a second switching device; the second suspected target ID being an ID corresponding to a suspected target switching device determined by the second switching device; determining a first target ID according to the first suspected target ID and the second suspected target ID; and the first target ID being an ID corresponding to a target switching device. Also disclosed is a first switching device, an access device and a storage medium.

A network such as an in-vehicle powerline communication (PLC) network may allow PLC nodes to communicate over existing powerlines. Provided in the present disclosure are exemplary techniques for synchronizing network nodes (e.g., PLC nodes) with a network clock for the network so that data generated at each node may share a common time reference. For example, a synchronization (sync) signal may be generated by a master node and broadcast to other PLC nodes over a PLC channel, which may also carry data frames to and from other PLC nodes. The network clock may be autonomously generated by the master node or may be tied to an external clock.

A network device includes one or more ports coupled to a network, a path determination module, and a clock synchronization module. The one or more ports receive a plurality of time synchronization packets from a master clock device. The path determination module identifies, based on respective path information included in each of at least some of the plurality of time synchronization packets, particular communication paths among two or more communication paths between the master clock device and the network device, via which the respective time synchronization packets traveled from the master clock device to the network device. The clock module determines a system time clock based on respective time information included in the at least some of the plurality of time synchronization packets and the identifications of the particular communication paths via which the respective time synchronization packets traveled from the master clock device to the network device.

A multimedia presentation system for presenting multimedia data comprising a demultiplexing unit and at least one processing unit. The demultiplexing unit demultiplexes a plurality of streams of data. At least one presentation processing unit provides the plurality of stream of data for presentation according to predetermined timing and detecting an end of any one of the plurality of streams of data.