Multi-channel listening capable receiver capable of operating on one of K data channels and method of operating such a receiver. A local oscillator (2) is provided for tuning the receiver (1) to one of the channels within a channel switching time Ts, as well as a processing unit (9) arranged to detect a presence of a preamble on the tuned channel. The processing unit (9) is further arranged to switch over the local oscillator (2) to a next one of the data channels if no presence of a preamble is detected within a single preamble symbol duration Tp. The channel switching time is a fraction of a single preamble symbol period Tp. The number of data channels K fulfills the condition K<floor (N1(K*)) to be able to receive all relevant data packets on the K channels, after being triggered by reception of the preamble.

A device using parity for verification of data transmitted from a first device through a data line to a second device includes a processor and a memory. The data line includes first to fourth pins for transmitting data and fifth to eighth pins for transmitting parity information. The processor receives values of first to eighth pins, calculates sum of the values of combinations of the first to fourth pins for data and applies modular operations on results of the four combinations. Equality or non-equality with the parity values of the fifth to eighth pins is determined, and the second device is permitted to receive the data when the results correspond, the modular operation being a (mod 2) operation. A method applied to such device is also disclosed.

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.

The present disclosure is directed to systems, apparatuses, and methods for performing continuous or periodic link training. Existing link training protocols generally perform link training only once during startup or initialization of a link and, as a result, are limited in their applications. After link training is performed and Open Systems Interconnect (OSI) data link layer and other high-layer data is transmitted across the link, no further link training is performed using these existing link training protocols. However, parameters of the link may change over time after link training is performed, such as temperature of the link and voltage levels of signals transmitted over the link by the transmitter of the transmitter-receiver pair.

A data transmission parity device for verifying data transmitted from a first device through a data line to a second device includes a processor and a memory. The data line includes an N number of signal pins for transmitting data and an (N+1)th signal pin for transmitting parity information. The processor is configured to receive and obtain a signal value of the N+1 signal pins, calculate a first sum of the signal value of the N+1 signal pins and apply a first modular operation on the first sum, determine whether a result of the first modular operation is equal to zero, and control the second device to reject the data when the result of the first modular operation is not equal to zero. The first modular operation and the second modular operation are both (mod 2) operations.

A method for data transmission includes receiving a data stream from a host device, the data stream as received from the host device including encoded data, separating the encoded data in the data stream into first data blocks and second data blocks, and generating a first forward error correction (FEC) block. The first FEC block includes a first parity section and a first data section, the first parity section includes a first parity bit corresponding to the first data blocks and a second parity bit corresponding to the second data blocks, and the first data section includes the first data blocks and the second data blocks. The method further includes transmitting the first FEC block.

Methods, systems, and devices are described herein for using codewords to detect or correct errors in data (e.g., data stored in a memory device). A host device may generate one or more codewords associated with data to be stored in the memory device. In some cases, the host device may generate one or more codewords for error detection and correction (e.g., corresponding to data transmitted by the host device to the memory device). In some cases, the host device may transmit the codewords and the associated data using an extended (e.g., adjustable) burst length such that the one or more codewords may be included in the burst along with the data. Additionally or alternatively, the host device may transmit one or more of the codewords over one or more channels different than the one or more channels used to transmit the data.

Systems and methods are provided to improve a communication channel dynamically and autonomously based on the status of the communication traffic on the communication channel between a first integrated circuit (IC) and a second IC. The communication traffic on the communication channel can be monitored, and latency, bandwidth, link quality, or power consumption associated with the communication channel for the monitored communication traffic can be determined dynamically. A modified protocol for the communication channel that can improve the communication channel as compared to an existing protocol can be determined based on the information related to the latency, bandwidth, link quality, or the power consumption. The existing protocol can be changed autonomously to the modified protocol as the communication traffic varies.

A method for data communication between a first node and a second node includes forming one or more redundancy messages from data messages at the first node using an error correcting code and transmitting first messages from the first node to the second node over a data path, the transmitted first messages including the data messages and the one or more redundancy messages. Second messages are received at the first node from the second node, which are indicative of: (i) a rate of arrival at the second node of the first messages, and (ii) successful and unsuccessful delivery of the first messages. A transmission rate limit and a window size are maintained according to the received second messages. Transmission of additional messages from the first node to the second node is limited according to the maintained transmission rate limit and window size.

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.