Patent application number | Description | Published |
20100058099 | HETEROGENEOUS TRANSCEIVER ARCHITECTURE FOR WIDE RANGE PROGRAMMABILITY OF PROGRAMMABLE LOGIC DEVICES - High-speed serial data transceiver circuitry on a programmable logic device (“PLD”) includes some channels that are able to operate at data rates up to a first, relatively low maximum data rate, and other channels that are able to operate at data rates up to a second, relatively high maximum data rate. The relatively low-speed channels are served by relatively low-speed phase locked loop (“PLL”) circuitry, and have other circuit components that are typically needed for handling data that is transmitted at relatively low data rates. The relatively high-speed channels are served by relatively high-speed PLLs, and have other circuit components that are typically needed for handling data that is transmitted at relatively high data rates. | 03-04-2010 |
20100215086 | Multi-protocol channel-aggregated configurable transceiver in an integrated circuit - Embodiments in the disclosure include a multi-protocol transceiver including a configurable arrangement of receive and/or transmit circuitry. An exemplary transceiver can be selectively configured to effectively transmit and/or receive data communications corresponding to a select one of a plurality of high-speed communication protocols. Another more particular embodiment disclosed includes a configurable data path through link-wide Physical Coding Sub-layer (“PCS”) circuitry including link-wide clock compensation, encoding/decoding, and scrambling/descrambling circuitry and lane striping/de-striping circuitry; the configurable data path further includes lane-wide circuitry including clock compensation, encoding/decoding, receive block sync, and Physical Medium Access sub-layer (“PMA”) circuitry, and further includes bit muxing/de-muxing circuitry coupled to Physical Medium Dependent (“PMD”) sub-layer circuitry. | 08-26-2010 |
20100277201 | EMBEDDED DIGITAL IP STRIP CHIP - An integrated circuit (IC) is provided. The IC includes a first region having an array of programmable logic cells. The IC also includes a second region incorporated into the IC and in communication with the first region. The second region includes standard logic cells and base cells. In one embodiment, the standard logic cells are assembled or interconnected to accommodate known protocols. The base cells include configurable logic to adapt to modifications to emerging communication protocols, which are supported by the base cells. The second region can be embedded in the first region in one embodiment. In another embodiment, the second region is defined around a perimeter of the first region. The configurable logic may be composed of hybrid logic elements that have metal mask programmable interconnections so that as emerging communication protocols evolve and are modified, the IC can be modified to accommodate to the changes in the protocol. In another embodiment, a generic device can be customized by replacing the original function with a completely new function targeting a specific application space, e.g., replacing the original function such as a PCI Express, used for computing based applications, with 40 G/100 G Ethernet and Interlaken, used in wireline applications. A method of designing an integrated circuit is also provided. | 11-04-2010 |
20110090101 | DIGITAL PHASE LOCKED LOOP CIRCUITRY AND METHODS - Phase locked loop circuitry operates digitally, to at least a large extent, to select from a plurality of phase-distributed candidate clock signals the signal that is closest in phase to transitions in another signal such as a clock data recovery (“CDR”) signal. The circuitry is constructed and operated to avoid glitches in the output clock signal that might otherwise result from changes in selection of the candidate clock signal. Frequency division of the candidate clock signals may be used to help the circuitry support serial communication at bit rates below frequencies that an analog portion of the phase locked loop circuitry can economically provide. Over-transmission or over-sampling may be used on the transmit side for similar reasons. | 04-21-2011 |
20110211621 | HETEROGENEOUS TRANSCEIVER ARCHITECTURE FOR WIDE RANGE PROGRAMMABILITY OF PROGRAMMABLE LOGIC DEVICES - High-speed serial data transceiver circuitry on a programmable logic device (“PLD”) includes some channels that are able to operate at data rates up to a first, relatively low maximum data rate, and other channels that are able to operate at data rates up to a second, relatively high maximum data rate. The relatively low-speed channels are served by relatively low-speed phase locked loop (“PLL”) circuitry, and have other circuit components that are typically needed for handling data that is transmitted at relatively low data rates. The relatively high-speed channels are served by relatively high-speed PLLs, and have other circuit components that are typically needed for handling data that is transmitted at relatively high data rates. | 09-01-2011 |
20120307878 | MULTI-PROTOCOL MULTIPLE-DATA-RATE AUTO-SPEED NEGOTIATION ARCHITECTURE FOR A DEVICE - An interface for use in a local device includes a transmitter portion programmably configurable to at least three data rates, a receiver portion programmably configurable to those at least three data rates, and an automatic speed negotiation module operatively connected to the transmitter portion and the receiver portion to configure the transmitter portion and the receiver portion for communication with a remote device at a single data rate that is a best available one of those at least three data rates. The date rate can be adjusted by adjusting transmitter data path width and receiver data path width, adjusting a frequency of said transmitter data path and said receiver data path, and oversampling. Byte serialization or deserialization can be enabled or disabled to alter the width of the data, depending on the data rate, for transfer to/from the remainder of the local device. | 12-06-2012 |
20130265179 | DIGITAL PHASE LOCKED LOOP CIRCUITRY AND METHODS - Phase locked loop circuitry operates digitally, to at least a large extent, to select from a plurality of phase-distributed candidate clock signals the signal that is closest in phase to transitions in another signal such as a clock data recovery (“CDR”) signal. The circuitry is constructed and operated to avoid glitches in the output clock signal that might otherwise result from changes in selection of the candidate clock signal. Frequency division of the candidate clock signals may be used to help the circuitry support serial communication at bit rates below frequencies that an analog portion of the phase locked loop circuitry can economically provide. Over-transmission or over-sampling may be used on the transmit side for similar reasons. | 10-10-2013 |