A system for negotiating Ethernet link settings between interconnected nodes in a network having an Ethernet protocol stack that includes a PCS sub-layer with an auto-negotiation function. The system comprises connecting an intermediate device coupled between two network nodes via optical or copper interfaces, with the link settings between each node and the connected intermediate device being the same, thereby bypassing the auto-negotiation of the PCS sub-layer in the intermediate device. The intermediate device may transparently send negotiation messages from each node to the other during the link negotiation phase without interacting with those messages. Instead of the intermediate device, a single form pluggable (SFP) device may be connected between the two network nodes via optical or copper interfaces on the network side and via an SFP slot on the device side.

A network device includes a hardware component. The network device includes a first device receiver operably connected to the hardware component via a first hardware component connection and adapted to receive a device. The network device further includes a second device receiver operably connected to the hardware component via a second hardware component connection. The first device receiver of the network device is adapted to reversibly reallocate the first hardware component connection to the second device receiver.

Examples include a method of identifying single twisted pair cable Ethernet auto-negotiation requests or double twisted pair cables Ethernet auto-negotiation requests using detection of message time interval patterns. The method includes receiving, by a first Ethernet device, a plurality of messages transmitted by a second Ethernet device over a single twisted pair cable connecting the first Ethernet device and the second Ethernet device; storing one or more time intervals between starting times of successive pairs of the plurality of messages; determining if a pattern is found in the time intervals; when the pattern is found, setting a single twisted pair cable communications mode between the first Ethernet device and the second Ethernet device; and performing priority resolution between the first Ethernet device and the second Ethernet device.

A network element includes at least one communication port and a processor. The communication port is configured to communicate with a peer communication port of a peer network element. The processor is configured to support a full-boot mode and a fast-boot mode, to establish, by negotiation with the peer network element, whether the fast-boot mode is supported both for the communication port and for the peer communication port, and, in response to finding that the fast-boot mode is supported both for the communication port and for the peer communication port, to coordinate with the peer network element a boot of the communication port and of the peer communication port, both using the fast-boot mode.

A data routing method used to implement data routing in a communications system in which a plurality of networks that use different data bearer protocols are integrated is produced. The method includes: a routing apparatus receives data by using an input port, and determines a data bearer protocol attribute of the input port; the routing apparatus determines an attribute of the data based on the data bearer protocol attribute of the input port; the routing apparatus determines based on the attribute of the data, a data bearer protocol attribute of an output port used to output the data; and determines based on the data bearer protocol attribute of the output port, the output port used to output the data, and outputting the data by using the determined output port.

A method for detecting an open circuit on a cable for 1GBASE-T and/or 10GBASE-T Ethernet communications includes transmitting one or more autonegotiation signals during an attempt to identify an open cable. The autonegotiation signals are sent from an autonegotiation-capable Ethernet transceiver connected to a cable with a twisted pair. The method includes receiving one or more waveforms from the cable, analyzing the received one or more waveforms, and transmitting an open cable alert in response to determining that the received one or more waveforms are indicative of a reflected autonegotiation signal.

Examples described herein relate to a network interface comprising physical medium dependent (PMD) circuitry, the PMD circuitry to during link training of at least one lane consistent with IEEE 802.3, exit to TIME_OUT state during TRAIN_LOCAL state based on consideration of expiration of a wait timer, loss of local_tf_lock state, and loss of remote_tf_lock state. In some examples, during link training for at least one lane consistent with IEEE 802.3, the PMD circuitry is to exit to TIME_OUT state during TRAIN_REMOTE state based on consideration of expiration of a wait timer, loss of local_tf_lock state, and loss of remote_tf_lock state. In some examples, link training consistent with IEEE 802.3 comprises performance of the PMD control function in Section 162.8.11 of IEEE 802.3ck.

In a communication network operating according to a communication protocol that defines a link establishment procedure having i) a negotiating procedure and ii) a training procedure, a first communication device performs the link establishment procedure with a second communication device. During the negotiating procedure, the first communication device negotiates one or more new parameter values for the link establishment procedure that are different than one or more mandated parameter values specified by the communication protocol. During the link establishment procedure, the first communication device uses the one or more new parameter values instead of using the one or more mandated parameter values specified by the communication protocol.

A method and an apparatus for achieving network intercommunication based on neighbor negotiation are disclosed. The method may include: switching a link mode from a first mode to a second mode; sending, to a to-be-connected device, a switching request for switching from the second mode to the first mode; and switching the second mode back to the first mode in response to receiving a response sent by the to-be-connected device, the response being used to indicate that the to-be-connected device is to be switched to the first mode.

Technologies for autonegotiation of communications operational modes over copper cable include a network port logic having a communication link coupled to a remote link partner. The network port logic may start an autonegotiation protocol upon reset, when the link is broken, or upon manual renegotiation. The network port logic transmits an autonegotiation page to the remote link partner that indicates single-lane communications ability over copper cable. The network port logic receives an autonegotiation page from the link partner indicating single-lane communications ability over copper cable. If the network port logic and link partner have a common single-lane communication ability, the link may be activated. The autonegotiation pages may be base pages or next pages. The single-lane communication ability may be indicated by one or more bits of the autonegotiation pages. The link may be established at 1 gigabit or 10 gigabits per second. Other embodiments are described and claimed.