A system includes a server, a plurality of end devices, and at least one gathering gateway serving as a relay between the server and the end devices. The server creates at least one group and allocates end devices to each group created; defines, for each group, instances of a group reception window separated by a period so as to occur at deterministic instants; receives uplink frames coming from end devices; for such end device allocated to a group, acknowledges the uplink frames received in a downlink frame transmitted in multicast mode, in such group reception window defined for said group, said downlink frame including a group acknowledgement for all the uplink frames sent by end devices of the group during the period preceding said instance of the group reception window; and, for such end device that is not allocated to a group, acknowledges the uplink frames received in unicast mode.

A communication device (20 and 40) includes a redundant data generation unit (212a and 412a), a signal generation unit (212b, 412b, 212c, and 412c), and a transmission unit (212d and 412d). The redundant data generation unit (212a and 412a) performs error correction coding processing on combined data obtained by combining first data and second data to generate redundant data used for error correction. The signal generation unit (212b, 412b, 212c, and 412c) generates a transmission signal based on the second data and the redundant data. The transmission unit (212d and 412d) transmits the transmission signal to another communication device (20 and 40).

A particular overall architecture for transmission over a bonded channel system consisting of two interconnected MoCA (Multimedia over Coax Alliance) 2.0 SoCs (Systems on a Chip) and a method and apparatus for the case of a “bonded” channel network. With a bonded channel network, the data is divided into two segments, the first of which is transported over a primary channel and the second of which is transported over a secondary channel.

Provided is a high-speed communication system with the high reliability and the low latency under New Radio (NR). A base station device includes a plurality of distributed units (DUs, 802) that transmit and receive radio signals, and a central unit (CU, 801) that controls the plurality of DUs (802). The CU (801) duplicates a downlink packet addressed to a communication terminal device (804), and forwards the duplicated downlink packet to each of at least two DUs (802) among the plurality of DUs (802). Each of the at least two of the DUs (802) transmits, to the communication terminal device (804) by the radio signal, the downlink packet obtained from the CU (801). Upon redundant receipt of the downlink packets, the communication terminal device (804) removes a redundant downlink packet in accordance with a predefined downlink packet removal criterion.

A method includes: sending, by a first device, a first bit stream to a second device, where the first bit stream is sent over N logical lanes of a physical layer of the first device; sending, by the first device, a first trigger marker group to the second device, where the first trigger marker group is used to indicate that the sending of the first bit stream ends; and sending, by the first device, a second bit stream to the second device in response to the sending of the first trigger marker group, where the second bit stream is sent over P logical lanes of the physical layer of the first device, and both N and P are positive integers.

One example may include transmitting data between a client device and a server over a first channel, determining an error rate on at least one of the first channel and a second channel not mirrored with the first channel, when the error rate crosses a first error rate threshold then mirroring the first channel and the second channel, and when the error rate is between the first error rate threshold and a second error rate threshold that is different than the first error rate threshold, determining whether to continue mirroring or discontinue the mirroring of the first channel and the second channel.

Embodiments herein disclose conditioning traffic through multiple data paths of a Software-Defined Wide Area Network (SD-WAN). Some embodiments include monitoring a first and a second path through an SD-WAN to reach a destination node, comparing the link utilization for the first and the second path to generate an allocation ratio of the first and the second path, allocating a sequence of data packets to the first and the second path using the allocation ratio to generate a first path data sequence and a second path data sequence, generating a forward error correction (FEC) packet for first path sequence, sending the first path data sequence to the destination node on the first path, sending the second path data sequence to the destination node on the second path, and sending the FEC packet on at least one of the first and the second path.

Disclosed is a transmitter which includes an encoder and a transmission interface circuit. The encoder receives data bits and generates conversion bits, a number of is the conversion bits being more than a number of the data bits, based on the number of the data bits. The encoder detects a risk pattern of the conversion bits to generate detection data and converts the risk pattern into a replacement pattern based on the detection data to generate code bits, a number of is the code bits being equal to the number of the conversion bits.

Methods and apparatus for transmitting data is disclosed. Data to be transmitted is segmented into data packets. The segmented data packets are duplicated into multiple groups of data packets, which are then transmitted from a device at a transmitting end to a device at a receiving end using multiple transmission protocols in parallel. Each of a set of duplicated data packets is thus transmitted by one of the multiple transmission protocols. The data packet among each of set of duplicated data packets that is first received by the device at the receiving end is retained and other received data packets of the set of duplicated data packets are discarded. The disclosed methods and apparatus thus combine benefits of different transmission protocols. For example, the disclosed methods and apparatus help achieve both transmission integrity and timing.

A system and method provide a communications link having a plurality of lanes, and an in-band, real-time physical layer protocol that keeps all lanes on-line, while failing lanes are removed, for continuous service during fail over operations. Lane status is monitored real-time at the physical layer receiver, where link error rate, per lane error performance, and other channel metrics are known. If a lane failure is established, a single round trip request/acknowledge protocol exchange with the remote port completes the fail over. If a failing lane meets an acceptable performance level, it remains on-line during the round trip exchange, resulting in uninterrupted link service. Lanes may be brought in or out of service to meet reliability, availability, and power consumption goals.