Abstract: Apparatus and methods for implementing high-speed Ethernet links using a hybrid PHY (Physical layer) selectively configurable to employ a non-interleaved RS-FEC (Reed Solomon Forward Error Correction) sublayer or an interleaved RS-FEC sublayer. An adaptive link training protocol is used during link training to determine whether to employ the non-interleaved or interleaved RS-FEC during link DATA mode. Training frames are exchanged between link partners including control and status fields used to respectfully request a non-interleaved or interleaved FEC mode and confirm the requested FEC mode is to be used during link DATA mode. The hybrid PHY includes interleaved RS-FEC and non-interleaved RS-FEC sublayers for transmitter and receiver operations. During link training, a determination is made to whether a local receiver is likely to see decision feedback equalizer (DFE) burst errors. If so, the interleaved FEC mode is selected; otherwise the non-interleaved FEC mode is selected or is the default FEC mode.

Abstract: Apparatus and methods for implementing high-speed Ethernet links using a hybrid PHY (Physical layer) selectively configurable to employ a non-interleaved RS-FEC (Reed Solomon Forward Error Correction) sublayer or an interleaved RS-FEC sublayer. An adaptive link training protocol is used during link training to determine whether to employ the non-interleaved or interleaved RS-FEC during link DATA mode. Training frames are exchanged between link partners including control and status fields used to respectfully request a non-interleaved or interleaved FEC mode and confirm the requested FEC mode is to be used during link DATA mode. The hybrid PHY includes interleaved RS-FEC and non-interleaved RS-FEC sublayers for transmitter and receiver operations. During link training, a determination is made to whether a local receiver is likely to see decision feedback equalizer (DFE) burst errors. If so, the interleaved FEC mode is selected; otherwise the non-interleaved FEC mode is selected or is the default FEC mode.

Abstract: Technologies for cooperative link equalization include a network device with a network interface controller (NIC). The NIC is to monitor variation in a property of a link channel that connects the network device with a target network device. The NIC detects, based on the channel variation, an event that triggers a condition to change an equalization setting of the link channel. In response to the detection, the NIC communicates, via an in-band equalization control channel, changes to the equalization setting of the link channel to the target network device.

Abstract: Apparatus and methods for implementing high-speed Ethernet links using a hybrid PHY (Physical layer) selectively configurable to employ a non-interleaved RS-FEC (Reed Solomon Forward Error Correction) sublayer or an interleaved RS-FEC sublayer. An adaptive link training protocol is used during link training to determine whether to employ the non-interleaved or interleaved RS-FEC during link DATA mode. Training frames are exchanged between link partners including control and status fields used to respectfully request a non-interleaved or interleaved FEC mode and confirm the requested FEC mode is to be used during link DATA mode. The hybrid PHY includes interleaved RS-FEC and non-interleaved RS-FEC sublayers for transmitter and receiver operations. During link training, a determination is made to whether a local receiver is likely to see decision feedback equalizer (DFE) burst errors. If so, the interleaved FEC mode is selected; otherwise the non-interleaved FEC mode is selected or is the default FEC mode.

Abstract: Technologies for cooperative link equalization include a network device with a network interface controller (NIC). The NIC is to monitor variation in a property of a link channel that connects the network device with a target network device. The NIC detects, based on the channel variation, an event that triggers a condition to change an equalization setting of the link channel. In response to the detection, the NIC communicates, via an in-band equalization control channel, changes to the equalization setting of the link channel to the target network device.

Abstract: One embodiment provides a method for resolving a forward error correction (FEC) protocol. The method includes requesting, by a network node element during an auto-negotiation period between the node element and a link partner, to resolve at least one FEC mode during a link training period; wherein the auto-negotiation period and the link training period are defined by an Ethernet communications protocol and the auto-negotiation period occurs before the link training period; determining, by the network node element, at least one channel quality parameter of at least one channel of a communication link between the network node element and the link partner; and determining, by the network node element during the link training period, whether to enable at least one FEC mode for use by the network node element based on, at least in part, the at least one channel quality parameter.

Abstract: One embodiment provides a PHY having a Media Access Control (MAC) and a Forward Error Correction (FEC) decoder, capable of error detection and error correction for FEC encoded packets based on FEC parity data included in the FEC encoded packets. The FEC decoder is capable of being enabled into different configurations of different operations to perform on FEC parity data included in the FEC encoded packets. The different configurations having different respective associated latencies.

Abstract: One embodiment provides a PHY having a Media Access Control (MAC) and a Forward Error Correction (FEC) decoder, capable of error detection and error correction for FEC encoded packets based on FEC parity data included in the FEC encoded packets. The FEC decoder is capable of being enabled into different configurations of different operations to perform on FEC parity data included in the FEC encoded packets. The different configurations having different respective associated latencies.

Abstract: One embodiment provides a method for time protocol latency correction based on forward error correction (FEC) status. The method includes determining, by a network node element, if a forward error correction (FEC) decoding mode is enabled or disabled for a packet received from a link partner in communication with the network node element. The method also includes determining, by the network node element, a first time correction factor if an FEC decoding mode is enabled, the first time correction factor includes a time delay associated with the enabled FEC decoding mode and the first time correction factor is applied to a time stamp associated with the packet. The method also includes determining, by the network node element, a second time correction factor if an FEC decoding mode is disabled, the second time correction factor is applied to the time stamp associated with the packet.

Abstract: One embodiment provides a method for resolving a forward error correction (FEC) protocol. The method includes requesting, by a network node element during an auto-negotiation period between the node element and a link partner, to resolve at least one FEC mode during a link training period; wherein the auto-negotiation period and the link training period are defined by an Ethernet communications protocol and the auto-negotiation period occurs before the link training period; determining, by the network node element, at least one channel quality parameter of at least one channel of a communication link between the network node element and the link partner; and determining, by the network node element during the link training period, whether to enable at least one FEC mode for use by the network node element based on, at least in part, the at least one channel quality parameter.

Abstract: One embodiment provides a method for time protocol latency correction based on forward error correction (FEC) status. The method includes determining, by a network node element, if a forward error correction (FEC) decoding mode is enabled or disabled for a packet received from a link partner in communication with the network node element. The method also includes determining, by the network node element, a first time correction factor if an FEC decoding mode is enabled, the first time correction factor includes a time delay associated with the enabled FEC decoding mode and the first time correction factor is applied to a time stamp associated with the packet. The method also includes determining, by the network node element, a second time correction factor if an FEC decoding mode is disabled, the second time correction factor is applied to the time stamp associated with the packet.

Abstract: According to some embodiments, a first measurement of a network device signaling characteristic is performed. The network device includes a first communication port and a second communication port, the second port being associated with a detachable attachment. The first measurement is performed when the attachment is not attached to the second port. A second measurement of the signaling characteristic is then performed when the attachment is attached to the second port. At least one corrective value to be used by the network device is then determined based on the first and second measurement.