| Patent application number | Description | Published |
|---|
| 20100014427 | ARBITRATION SCHEME FOR AN OPTICAL BUS - A method of arbitrating data transmissions to prevent data collisions in an optical data interconnect system including a transmitting node, a plurality of receiving nodes, and one or more remaining nodes connected through an optical data channel. The method involves transmitting a transmission request signal from the transmitting node over an arbitration channel corresponding to the transmitting node, monitoring, at the transmitting node, a plurality of arbitration channels corresponding to each of the plurality of receiving nodes and the one or more remaining nodes at the transmitting node for a predetermined period of time, determining a start time for a data transmission from the transmitting node based on the monitored signals to prevent a data collision, and initiating a data transmission of a data signal from the transmitting node over the optical data channel at the determined start time. | 01-21-2010 |
| 20100014852 | CSMA/CD OPTICAL INTERCONNECT SCHEME - A method of detecting transmission collisions in an optical data interconnect system including a transmitting node, a plurality of receiving nodes, and one or more remaining nodes connected through an optical data channel. The method includes initiating a data transmission of a data signal from the transmitting node over the optical data channel, transmitting a first collision detect signal from the transmitting node throughout a duration of the data transmission where the first collision detect signal is transmitted over an optical detection channel corresponding to the transmitting node, monitoring at the transmitting node of the optical data interconnect system for a predetermined period of time, where the optical data interconnect system further includes a plurality of optical collision detection channels corresponding to each of the plurality of receiving nodes and the one or more remaining nodes, and identifying a transmission collision when a second collision signal is received through one of the plurality of optical collision detection channels at the transmitting node during the predetermined period of time. | 01-21-2010 |
| 20100213606 | DIELECTRIC ENHANCEMENTS TO CHIP-TO-CHIP CAPACITIVE PROXIMITY COMMUNICATION - A method for improving signal levels between capacitively-coupled chips in proximity communication (PxC) includes depositing a high permittivity dielectric material layer over a signal pad of a first chip, and placing a second chip in close proximity to the first chip such that faces of the signal pads align to enable for capacitive signal coupling. The high permittivity dielectric material layer that fills at least a portion of a gap between the first chip and the second chip, and improves capacitive coupling between signal pads of the first chip and the second chip by providing for an increased permittivity in the gap between the first chip and the second chip. The increased permittivity ensures that electric fields are substantially confined to a space between the signal pad of the first chip and the signal pad of the second chip. | 08-26-2010 |
| 20100215309 | ELECTRICAL CONTACTS ON TOP OF WAVEGUIDE STRUCTURES FOR EFFICIENT OPTICAL MODULATION IN SILICON PHOTONIC DEVICES - A phase modulation waveguide structure includes one of a semiconductor and a semiconductor-on-insulator substrate, a doped semiconductor layer formed over the one of a semiconductor and a semiconductor-on-insulator substrate, the doped semiconductor portion including a waveguide rib protruding from a surface thereof not in contact with the one of a semiconductor and a semiconductor-on-insulator substrate, and an electrical contact on top of the waveguide rib. The electrical contact is formed of a material with an optical refractive index close to that of a surrounding oxide layer that surrounds the waveguide rib and the electrical contact and lower than the optical refractive index of the doped semiconductor layer. During propagation of an optical mode within the waveguide structure, the electrical contact isolates the optical mode between the doped semiconductor layer and a metal electrode contact on top of the electrical contact. | 08-26-2010 |
| 20110103397 | TWO-PHASE ARBITRATION MECHANISM FOR A SHARED OPTICAL LINKS - A method for arbitration in an arbitration domain. The method includes: receiving, by each node of a plurality of nodes in the arbitration domain, an arbitration request from each sending node of the plurality of nodes in the arbitration domain, where the plurality of nodes in the arbitration domain each use a shared data channel to send data to a set of receiving nodes; assigning, by each node in the arbitration domain, consecutive time slots to each sending node based on a plurality of priorities assigned to the plurality of nodes in the arbitration domain; for each time slot: sending, from the arbitration domain, a switch request to a receiving node designated by the sending node, where the receiving node is in the set of receiving nodes; and sending, by the sending node, data to the receiving node via the shared data channel during the time slot. | 05-05-2011 |
| 20110179208 | TIME DIVISION MULTIPLEXING BASED ARBITRATION FOR SHARED OPTICAL LINKS - A method for arbitration including selecting, for an arbitration interval corresponding to a timeslot, a sending node from a plurality of sending nodes in an arbitration domain, where the plurality of sending nodes include a plurality of source counters; broadcasting, by the sending node and in response to selecting the sending node, a transmitter arbitration request for the timeslot during the arbitration interval; receiving, by the plurality of sending nodes, the transmitter arbitration request; incrementing the plurality of source counters in response to receiving the transmitter arbitration request; and sending, during the timeslot, a data item from the sending node to a receiving node via an optical data channel. | 07-21-2011 |
| 20110200332 | SHARED-SOURCE-ROW OPTICAL DATA CHANNEL ORGANIZATION FOR A SWITCHED ARBITRATED ON-CHIP OPTICAL NETWORK - A system including first and second sending nodes, a horizontal optical data link (ODL) having optical signals propagating in opposite directions in first and second waveguide segments, a vertical ODL having optical signals propagating in the same direction throughout third and fourth waveguide segments, a first optical output switch operatively connecting the first sending node and the first waveguide segment and configured to switch first data item onto the first waveguide segment during a first timeslot, a second optical output switch operatively connecting the second sending node and the second waveguide segment and configured to switch second data item onto the second waveguide segment during a second timeslot, and an optical coupler pair operatively connecting the first and second waveguide segments to the third and fourth waveguide segments, respectively, and redirecting the first and the second data items from the horizontal to the vertical ODL. | 08-18-2011 |
| 20110200335 | DATA CHANNEL ORGANIZATION FOR A SWITCHED ARBITRATED ON-CHIP OPTICAL NETWORK - A system for optical data communication, including: a first sending node including a first data item for transmission to a first receiving node during a first timeslot; a second sending node including a second data item for transmission during a second timeslot; a first optical data link (ODL) and a second ODL; a first output switch configured to switch the first data item from the first sending node onto the first ODL during the first timeslot; a second output switch configured to switch the second data item from the second sending node onto the first ODL during the second timeslot; an optical coupler connecting the first and second ODL; and a first input switch operatively connecting the first receiving node with the second ODL and configured to switch the first data item from the second ODL to the first receiving node during the first timeslot. | 08-18-2011 |
