A transmission apparatus includes a transmission signal generator which, in operation, generates a transmission signal having an aggregate physical layer protocol data unit (PPDU) that includes a legacy preamble, a legacy header, a non-legacy preamble, a plurality of non-legacy headers and a plurality of data fields; and a transmitter which, in operation, transmits the generated transmission signal, wherein the legacy preamble, the legacy header and the plurality of non-legacy headers are transmitted using a standard bandwidth, the non-legacy preamble and the plurality of data fields are transmitted using a variable bandwidth that is larger than the standard bandwidth and wherein a plurality of sets of each of the plurality of non-legacy headers and each of the plurality of data fields are transmitted sequentially in a time domain.

[Object] To provide a mechanism capable of improving the efficiency of wireless communication even in a case in which the sequence numbers of received data units are non-sequential.

[Solution] A wireless communication device including: a processing unit that generates a protocol data unit (PDU) that has sequence information with which a sequence number of a data unit that is determined as being to be resent is specified; and a communication unit that transmits the PDU generated by the processing unit. A wireless communication device including: a communication unit that receives a protocol data unit (PDU) that has sequence information with which a sequence number of a data unit that is determined as being to be resent is specified; and an acquisition unit that acquires the sequence information from the PDU received by the communication unit.

An information processing method performed by an information processing system including a storage device to process a plurality of data frames flowing in an in-vehicle network including at least one electronic control unit includes a receiving step of sequentially receiving a plurality of data frames flowing in the in-vehicle network, a frame collection step of recording, in a reception log held in the storage device, reception interval information indicating reception intervals between the plurality of data frames as frame information, a feature acquisition step of acquiring, from the reception interval information, a feature relating to distribution of the reception intervals between the plurality of data frames, and an unauthorized data presence determination step of determining the presence/absence of an unauthorized data frame among the plurality of data frames.

Disclosed are various embodiments for optimizing broadcast messaging for a node. The node receives data for a message from the network. While the data for the message is being received and upon completion of an initial portion of the message, the node determines identification information for the message specified in the initial portion. When (i) the identification information specifies that the message is a broadcast message and (ii) an identifier in the message matches a stored identifier of a previously received broadcast message, the node terminates receiving the data for the remainder of the message. Alternatively, when (i) the identification information specifies that the message is a broadcast message and (ii) the identifier in the message does not match any stored identifier of a previously received broadcast message, the node continues receiving data for the subsequent portion of the message and stores the identifier for the broadcast message.

The present invention relates to providing control information within a search space for blind decoding in a multi-carrier communication system. In particular, the control information is carried within a sub-frame of the communication system, the sub-frame including a plurality of control channel elements. The control channel elements may be aggregated into candidates for blind decoding. The number of control channel elements in a candidate is called aggregation level. In accordance with the present invention, the candidates of lower aggregation levels are localized, meaning that the control channel elements of one candidate are located adjacently to each other in the frequency domain. Some candidates of the higher aggregation level(s) are distributed in the frequency.

Presented herein are downstream recovery (error correction) techniques for an aggregated/consolidated media stream. In one example, a consolidated media stream that includes source media packets from one or more sources is sent to one or more downstream receiving devices. Based on the source media packets, one or more self-describing recovery packets for downstream error correction of the source media packets are generated. The self-describing recovery packets include a mapping to the source media packets used to generate the self-describing recovery packets, thereby avoiding the addition of error correction information in the consolidated media stream. The one or more self-describing recovery packets are sent to each of the downstream receiving devices as a separate stream.

In a wireless media network a source device provides entertainment content to a sink device over a radio frequency (RF) wireless channel. The source device can go into a receive only quiet enrolment mode until activated by a sink device transmitting enrolment trigger packets or having a signal strength above a certain threshold, thereby improving coexistence with other wireless devices. The source device changes from the quiet enrolment mode to an active enrolment mode when activated by the sink device.

Disclosed are various embodiments for optimizing broadcast messaging for a node. The node receives data for a message from the network. While the data for the message is being received and upon completion of an initial portion of the message, the node determines identification information for the message specified in the initial portion. When (i) the identification information specifies that the message is a broadcast message and (ii) an identifier in the message matches a stored identifier of a previously received broadcast message, the node terminates receiving the data for the remainder of the message. Alternatively, when (i) the identification information specifies that the message is a broadcast message and (ii) the identifier in the message does not match any stored identifier of a previously received broadcast message, the node continues receiving data for the subsequent portion of the message and stores the identifier for the broadcast message.

A transmission device includes, a receiver that receives availability information of each of a plurality of first transmission paths, and a transmitter that divides data into a plurality of transmission blocks, groups the plurality of transmission blocks into a plurality of slices, each of the plurality of slices include a distinct subset of the plurality of transmission blocks, when the availability information indicates that each of the plurality of first transmission paths has an error occurrence below a threshold value, transmits a different one of the plurality of slices to each of the plurality of first transmission paths.

A data sending method is provided. Media access control MAC payloads corresponding to a plurality of receiving devices are encapsulated in one MAC packet data unit (PDU), where the MAC PDU includes a header, the MAC payloads and identification information of each receiving device in the plurality of receiving devices; and the header includes a plurality of subheaders, the plurality of subheaders is subheaders respectively corresponding to a MAC payload corresponding to each receiving device, the MAC payload corresponding to each receiving device includes a MAC control element (CE) and/or a MAC service data unit (SDU), and the identification information is used for identifying each receiving device. The MAC PDU is sent. In the foregoing solutions, transmission of a MAC PDU during multi-user cooperated communication is implemented.