Patent application number | Description | Published |
20080232527 | SYNCHRONOUS NETWORK DEVICE - A physical layer device comprises a first port that embeds a first clock into data transmitted over a first physical medium; a second port that embeds a second clock into data transmitted over a second physical medium; a first selection module that outputs the first clock to the first port based on one of a locally generated clock and a recovered clock; and a second selection module that outputs the second clock to the second port based on one of the locally generated clock and the recovered clock. A method comprises embedding a first clock into data transmitted over a first physical medium; embedding a second clock into data transmitted over a second physical medium; generating the first clock based on one of a locally generated clock and a recovered clock; and generating the second clock based on one of the locally generated clock and the recovered clock. | 09-25-2008 |
20090080459 | Long-reach ethernet for 1000BASE-T and 10GBASE-T - A physical-layer device (PHY) having corresponding methods comprises: a data rate module to select a data rate divisor N, where N is at least one of a positive integer, or a real number greater than, or equal to, 1; and a PHY core comprising a PHY transmit module to transmit first signals a data rate of M/N Gbps, and a PHY receive module to receive second signals at the data rate of MIN Gbps; wherein the first and second signals conform to at least one of 1000BASE-T, wherein M=1, and 10GBASE-T, wherein M=10. | 03-26-2009 |
20090147695 | SUB-SYMBOL RATE CABLE TESTER - Aspects of the present disclosure provide for a cable tester that tests a cable to determine the cable length. The cable tester can include a clock generator that generates a clock that has clock period that is a multiple of the data symbol period and a signal generator that injects the training signal, which can be synchronous with the clock, into the cable. The cable tester can also include a receiver that samples the returned signal from the cable and adaptively filters the returned signal based on the training signal and a controller that determines the cable length from the adaptive filter tap coefficients. | 06-11-2009 |
20090252054 | Reduced Power Transmission - Reduced power transmission is described. In embodiments, networked devices communicate via a network connection. A characteristic of the network connection between the networked devices can be determined, and an output amplitude of a signal that is indicative of the communications between the network devices can be adjusted based on the characteristic of the network connection. Power consumption that is utilized for the communications between the network devices is reduced based on the adjustment of the output amplitude of the signal. | 10-08-2009 |
20090282277 | LOW-POWER IDLE MODE FOR NETWORK TRANSCEIVER - Low-power idle mode for network transceivers. In one aspect, a method for reducing power consumption of a transceiver connected to a communication network includes entering a low-power idle mode, and in this mode, repeatedly turning off a transmitter of the transceiver and turning on the transmitter according to a pattern, where the pattern has been customized based on characteristics of the receiver. Turning off the transmitter conserves power consumed by the transceiver. | 11-12-2009 |
20110299641 | Synchronous Network Device - A physical layer device including a plurality of ports and a clock synchronization module. Each port of the plurality of ports is programmable to receive a grandmaster clock. The clock synchronization module is configured to i) receive the grandmaster clock from a first port of the plurality of ports (wherein the first port has been programmed to receive the grandmaster clock), and ii) clean up the grandmaster clock, wherein cleaning up the grandmaster clock includes one or more of removing jitter from the grandmaster clock, controlling a voltage swing or the grandmaster clock, or establishing fixed edge rates of the grandmaster clock. Other ones of the plurality of ports, not including the first port, are programmed to receive the cleaned up grandmaster clock for use when transmitting data. | 12-08-2011 |
20120076057 | Duplex Mismatch Detection - An apparatus including a port to transmit first frames and receive second frames over a communication channel, the port including a collision detect circuit and a duplex mismatch circuit. The collision detect circuit detects collisions on the communication channel between the first frames and the second frames. The duplex mismatch circuit declares a duplex mismatch when the communication channel was established without attempting auto-negotiation, the port is in a half-duplex mode, and the collision detect circuit detects a very late collision involving one of the first frames. The very late collision occurs after a predetermined amount of data has been transmitted in the one of the first frames. The duplex mismatch indicates that a full-duplex mode is used with respect to the second frames. | 03-29-2012 |
20120314716 | LONG-REACH ETHERNET FOR 1000BASE-T AND 10GBASE-T - A physical-layer device includes a cable measurement module, a data rate module and a physical-layer device core. The cable measurement module measures characteristics of a cable. The data rate module (i) selects a data rate divisor N based on the characteristics of the cable, and (ii) reduces a rate of a first clock based on the data rate divisor N, where N is greater than 1. The physical-layer device core includes: a transmit module that transmits first signals over the cable at a data rate of M/N Gbps based on the rate of the first clock, where M is an integer; and a receive module that receives second signals over the cable at the data rate of M/N Gbps based on the rate of the first clock. The first and second signals conform to 1000BASE-T when M=1. The first and signals conform to 10GBASE-T when M=10. | 12-13-2012 |
20130301657 | Synchronous Network Device - A networking device includes a plurality of network ports and a clock synchronizer. Each network port is configured to receive a respective signal over a respective physical medium. A selected network port is configured to recover a clock signal from the respective signal received by the selected network port. Each of the network ports is configured to be selectable as the selected network port. The clock synchronizer is configured to generate a transmit clock signal in response to the clock signal recovered by the selected network port. The selected network port is configured to transmit data over the respective physical medium according to a local clock signal generated by a clock signal generator local to the networking device. Each network port other than the selected network port is configured to transmit data over the respective physical medium according to the transmit clock signal generated by the clock synchronizer. | 11-14-2013 |