Qing Cheng ZhuSanta Clara, CA

6446016, Sep 3, 2002

Dec 8, 1999

09/457836

Qing Zhu - Castro Valley CA

Intel Corporation - Santa Clara CA

G01R 2926

702 69, 702191, 702193, 324613

A method and apparatus for allocating decoupling capacitance in a power grid is provided. A power grid model of an RLC network is evaluated to identify the power nodes that have peak voltages exceeding a minimum voltage threshold and a maximum voltage threshold. For each noisy node that violates the thresholds, a decoupling capacitor is inserted. The power grid is once again re-evaluated to determine of any of the power nodes still violate the voltage thresholds. For those violating power nodes, the size of the decoupling capacitor is incremented. This process of incrementing the size of the decoupling capacitance and re-evaluating the power grid is repeated until all the power nodes are within a noise budget or the noise level for each power node is within the thresholds. The decoupling capacitance is then re-evaluated as it is iteratively decremented while maintaining the power noise within the thresholds. This method of inserting and sizing decoupling capacitance allows the power noise thresholds, to be satisfied while optimizing the size of the decoupling capacitance.

7317874, Jan 8, 2008

Jun 2, 2006

11/446276

Wen Li - Fremont CA, US
Qing Zhu - San Jose CA, US

Broadway Networks, Inc. - San Jose CA

H04J 14/00

398 72, 398 69, 398 67, 398 68, 398 70, 398 71, 398 95

An optical module includes a transmitter optical sub-assembly comprising a transmitter configured to emit a multi-longitudinal-mode (MLM) spectrum signal having an emission spectrum comprising a plurality of distinct narrow-spectrum peaks each corresponding to a longitudinal mode in the transmitter. The emission spectrum can be shifted in wavelength by a change in the transmitter temperature. The optical module also includes a heating and cooling device configured to control the temperature of the transmitter in response to a temperature-control signal and a receiver optical sub-assembly configured to output a pair of differential digital signals in response to an input optical signal.

7440701, Oct 21, 2008

Apr 3, 2006

11/396973

Wen Li - Fremont CA, US
Qing Zhu - San Jose CA, US

Broadway Networks, Ltd. - San Jose CA

H04B 10/00

398135, 398 67, 398 82

An optical communication system includes a first wavelength filter, a bidirectional amplifier, and a second wavelength filter. The first wavelength filter can receive a downstream broad-spectrum signal and output a downstream spectrum-sliced signal in response to the downstream broad-spectrum signal. The bidirectional amplifier can amplify the downstream spectrum-sliced signal. The second wavelength filter can receive the amplified downstream spectrum-sliced signal from the bidirectional amplifier and route the amplified downstream spectrum-sliced signal. The second wavelength filter can also output an upstream spectrum-sliced signal in response to an upstream broad-spectrum signal. The bidirectional amplifier can amplify the upstream spectrum-sliced signal to product an amplified upstream spectrum-sliced signal that is subsequently routed by the first wavelength filter.

7450848, Nov 11, 2008

Apr 28, 2006

11/413405

Wen Li - Fremont CA, US
Qing Zhu - San Jose CA, US

Broadway Networks, Ltd, - San Jose CA

H04J 14/00

398 68, 398 72, 398 85

An optical communication system including a plurality of transceiver ports each including a transmitter configured to produce a downstream MLM-spectrum signal and a receiver configured to receive an upstream spectrum-sliced signal. The spectrum of the downstream MLM-spectrum signal comprises a plurality of distinct narrow-spectrum peaks each corresponding to a longitudinal mode. The optical communication system also includes a wavelength filter that includes a plurality of branching ports each associated with a specific wavelength channel, wherein each of the branching ports is in connection with a transceiver port and is configured to receive the downstream MLM-spectrum signal from the transmitter and send an upstream spectrum-sliced signal to the receiver, and a common port configured to output a downstream spectrum-sliced signal in response to the downstream MLM-spectrum signal, wherein the spectrum of the downstream spectrum-sliced signal is located in a wavelength channel specifically associated with the branching port at which the downstream MLM-spectrum signal is received.

7469558, Dec 30, 2008

Jul 10, 2001

09/903081

Richard E. Demaray - Portola Valley CA, US
Kai-An Wang - Cupertino CA, US
Ravi B. Mullapudi - San Jose CA, US
Qing Zhu - San Jose CA, US
Hongmei Zhang - San Jose CA, US
Harold D. Ackler - Sunnyvale CA, US
John C. Egermeier - San Jose CA, US
Rajiv Pethe - San Jose CA, US

SpringWorks, LLC - Minnetonka MN

C03C 17/02
C03C 17/34

65386, 65429, 65391

An as-deposited waveguide structure is formed by a vapor deposition process without etching of core material. A planar optical device of a lighthouse design includes a ridge-structured lower cladding layer of a low refractive index material. The lower cladding layer has a planar portion and a ridge portion extending above the planar portion. A core layer of a core material having a higher refractive index than the low refractive index material of the lower cladding layer overlies the top of the ridge portion of the lower cladding. A slab layer of the core material overlies the planar portion of the lower cladding layer. The lighthouse waveguide also includes a top cladding layer of a material having a lower refractive index than the core material, overlying the core layer and the slab layer. A method of forming an as-deposited waveguide structure includes first forming a ridge structure in a layer of low refractive index material to provide a lower cladding layer. Next a layer of core material is deposited over the ridge structure by a vapor deposition process.

7493042, Feb 17, 2009

Jun 14, 2006

11/452498

Wen Li - Fremont CA, US
Qing Zhu - San Jose CA, US

Broadway Networks, Ltd. - San Jose CA

H04J 14/00

398 68, 398 72, 398 85

An optical communication system including a plurality of transceiver ports each including a transmitter configured to produce a downstream MLM-spectrum signal and a receiver configured to receive an upstream spectrum-sliced signal. The spectrum of the downstream MLM-spectrum signal comprises a plurality of distinct narrow-spectrum peaks each corresponding to a longitudinal mode. The optical communication system also includes a wavelength filter that includes a plurality of branching ports each associated with a specific wavelength channel, wherein each of the branching ports is in connection with a transceiver port and is configured to receive the downstream MLM-spectrum signal from the transmitter and send an upstream spectrum-sliced signal to the receiver, and a common port configured to output a downstream spectrum-sliced signal in response to the downstream MLM-spectrum signal, wherein the spectrum of the downstream spectrum-sliced signal is located in a wavelength channel specifically associated with the branching port at which the downstream MLM-spectrum signal is received.

2008008, Apr 17, 2008

Oct 17, 2006

11/550385

Wen Li - Fremont CA, US
Qing Zhu - San Jose CA, US

H04B 10/04

398197, 398196

A method for remotely tuning a transmitter in an optical communication system includes sending a control signal from a first location to a temperature controller at a second location and setting a first transmitter at the second location to a first temperature by the temperature controller in response to the control signal. The emission spectrum of the first transmitter can reach maximum power at or in the vicinity of a predetermined wavelength.

2008027, Nov 13, 2008

May 9, 2007

11/746512

Wen Huang - Cupertino CA, US
Fulin Pan - Fremont CA, US
Wen Li - Fremont CA, US
Qing Zhu - San Jose CA, US

H04B 10/00

398168

An Ethernet-based optical network system includes a first optical transmitter that can receive a first electric signal and to produce a first optical signal, a first optical receiver that can convert the first optical signal to a second electric signal. The first electric signal, the first optical signal, and the second electric signal have a first transmission baud rate. A down converter can receive a third electric signal having the first transmission baud rate and to produce a fourth electric signal having a second transmission baud rate. A second optical transmitter can receive the fourth electric signal and produce a second optical signal having the second transmission baud rate. A second optical receiver can convert the second optical signal to a fifth electric signal having the second transmission baud rate. An up converter can convert the fifth electric signal to a sixth electric signal having the first transmission baud rate.