Patent application number | Description | Published |
20100103955 | POWER MANAGEMENT OF A NETWORK DEVICE - In one embodiment, a method includes receiving a synchronization command to synchronize time information among each component of a set of components in a communication path. The method includes generating a power state message. The method includes transmitting the power state message, by the first component, to the remaining components in the communication path. The power state message is configured to reduce the power consumption of the remaining components of the set of components from a first power amount to a second power amount for a time period and the time period is associated with the synchronized time information. | 04-29-2010 |
20100128738 | INTERIM PHY SOLUTION FOR LPI COMPATIBILITY WITH LEGACY DEVICES - In one embodiment, a modified local PHY is adapted to couple a legacy host device to link partner implementing Energy Efficient Ethernet. The modified local PHY includes a buffer and if the legacy host transmits data when the modified local PHY is in a Low Power Idle (LPI) state then the data is stored in the buffer and transmission is paused until the modified local PHY transitions from the LPI state to an active state. | 05-27-2010 |
20100191794 | METHOD AND SYSTEM FOR PHY LOOP DETECTION - A method, system and apparatus are provided for detecting a loop-back in a physical layer on an Ethernet link. In the physical layer, a device sends a base page on the Ethernet link. The base page has at least one next page capability bit set. Subsequently, the device receives a received base page. Thereafter, for detecting the loop-back, the next page capability bit is set in the received base page is determined. | 07-29-2010 |
20100262848 | POWER CONSUMPTION MANAGEMENT IN A NETWORK DEVICE - A method includes buffering an initial amount of data of a data set transmitted from a MAC. When an amount of time for data associated with the data set to fill a PHY buffer approaches an amount of time for the far-end PHY to transition from the second far-end PHY power state to the first far-end PHY power state, buffering a remaining amount of data of the data set transmitted from the MAC and transmitting the data to a far-end PHY after the far-end PHY transitions between a second and first far-end PHY power state. When the amount of time for data associated with the data set to fill the buffer exceeds the amount of time for the far-end PHY to transition from the second to the first far-end PHY power state, transmitting a data delay indicator to the MAC to preempt the MAC from transmitting the remaining amount of data. | 10-14-2010 |
20120269070 | POWER CONSUMPTION MANAGEMENT IN A NETWORK DEVICE - A method includes buffering an initial amount of data of a data set transmitted from a MAC. When an amount of time for data associated with the data set to fill a PHY buffer approaches an amount of time for a far-end PHY to transition from a second far-end PHY power mode to a first far-end PHY power state, a remaining amount of data of the data set transmitted from the MAC is buffered and the data is transmitted to the far-end PHY after it transitions to the first far-end PHY power state. When the amount of time for data associated with the data set to fill the buffer exceeds the amount of time for the far-end PHY to transition to the first far-end PHY power state, a data delay indicator is transmitted to the MAC to preempt the MAC from transmitting the remaining amount of data. | 10-25-2012 |
20120320915 | SYSTEMS AND METHODS TO CONTROL FLOW AND TO DEFINE AND INTERLEAVE MULTIPLE CHANNELS - A transmitter transmits a data frame as an uninterrupted stream of codeblocks of predefined size on a first data path between a MAC and PHY. It inserts a first idle block of predefined size within the data frame if there is insufficient data. A receiver receives a second idle block on a second data path, the second idle block including a request to slow down the transmission on the first data path. The receiver causes the transmitter to insert a third idle block in response to receiving the second idle block. The transmitter may further send a stream identifier including an identifier for a data stream and a bandwidth factor. The transmitter may send one codeblock chosen from data blocks for the data stream and idle blocks, and then send the bandwidth factor number of codeblocks chosen from data blocks for other data streams and idle blocks. | 12-20-2012 |
20140241181 | METHODS AND DEVICES FOR PERFORMING DYNAMIC DROOP COMPENSATION - Provided herein are systems, methods and devices for performing droop compensation. In particular, systems, methods and devices for performing droop compensation by modifying transmit and/or receive characteristics of a magnetic device based on changing conditions are described. For example, a plurality of operating parameters or characteristics can be measured, a droop compensation capability of a link partner can be determined and transmit and/or receive characteristics of the magnetic device can be modified based on the measured operating parameters or characteristics and the determined droop compensation capability. | 08-28-2014 |
20140269689 | SYSTEMS AND METHODS TO EXPLICITLY REALIGN PACKETS - Methods and systems to explicitly realign packets are described. The system includes a first communications device that receives a first stream of bytes comprising a first packet and generates realignment information for the first packet based on an alignment restriction. The first communications device further transmits a second stream of bytes over the data path comprising the first packet and the realignment information. The transmitting of the first byte of the first packet over the data path being in accordance with the alignment restriction that is associated with an interface. The realignment information identifies a difference between a time that the first byte of the first packet would have been transmitted by the first communications device without the alignment restriction and a time of transmission of the first byte of the first packet by the first communications device in accordance with the alignment restriction. | 09-18-2014 |
20150124610 | NETWORK TRAFFIC PREEMPTION USING INTERMITTENT ENCAPSULATION - An example method for intermittent encapsulation of preemptable network traffic at a network node can include receiving a frame at the network node and determining if the frame is a preemptable frame. A preemptable frame is a frame that can be preempted, suspended, interrupted, etc. after transmission begins in order to transmit a preemptive frame. If the frame is a preemptable frame, the method can include determining if the preemptable frame satisfies a selective encapsulation rule. If the preemptable frame does not satisfy the selective encapsulation rule, the method can include transmitting the preemptable frame from the network node without encapsulation. Alternatively, if the preemptable frame satisfies the selective encapsulation rule, the method can include encapsulating and transmitting the preemptable frame from the network node. The preemptable frame can be encapsulated with a preemption header and/or a preemption trailer. | 05-07-2015 |
20150130269 | DETECTION, CLASSIFICATION AND MUTUAL RECOGNITION OF 4 PAIR POWER OVER ETHERNET - A method for verifying interconnection of a PSE and PD with 4-pair PoE capabilities includes performing a first classification event on first and second pairs, respectively, and detecting a first predetermined class current on first and second sets of twisted pairs, respectively. The method includes performing a second classification event on first and second pairs, respectively, and detecting first and second predetermined class currents on first and second pairs, respectively. After expiration of a first variable delay period related to a first pseudo-random variable of the PSE, the method includes performing a third classification event on the first pair and detecting a first derived class current on the first pair. After expiration of a second variable delay period related to a second pseudo-random variable of the PD, the method includes performing the third classification event on the second pair and detecting a second derived class current on the second pair. | 05-14-2015 |