Michael J Rowan

US Patent:

6407843, Jun 18, 2002

Filed:

Nov 28, 2000

Appl. No.:

09/728376

Inventors:

Michael W. Rowan - Los Gatos CA
Peter Chang - San Jose CA
James F. Coward - San Francisco CA
Roger R. Taur - Honolulu HI
Stuart Wilson - Menlo Park CA
Ting K. Yee - Foster City CA

Assignee:

Kestrel Solutions, Inc. - Mountain View CA

International Classification:

H04B 1000

US Classification:

359189

Abstract:

A system transmits digital data over an optical fiber at high aggregate data rates and high bandwidth efficiencies. The system includes a modulation stage, a frequency division multiplexer, and an optical modulator. The modulation stage QAM-modulates a plurality of incoming digital data channels. The frequency division multiplexer combines the QAM-modulated signals by frequency division multiplexing them into an RF signal. The optical modulator uses the RF signal to modulate an optical carrier for transmission over an optical fiber.

US Patent:

6452945, Sep 17, 2002

Filed:

Jan 13, 1999

Appl. No.:

09/229594

Inventors:

David B. Upham - Sunnyvale CA
Augustus Elmer - San Jose CA
Laurence J. Newell - Saratoga CA
David A. Pechner - San Jose CA
Abraham Kou - San Jose CA
Michael W. Rowan - Los Gatos CA
James F. Coward - La Honda CA
Norman L. Swenson - Fremont CA
Minnie Ho - Palo Alto CA

Assignee:

Kestrel Solutions, Inc. - Mountain View CA

International Classification:

H04J 308

US Classification:

370480, 370535

Abstract:

A frequency division multiplexing (FDM) node used in optical communications networks provides add-drop multiplexing (ADM) functionality between optical high-speed channels, and low-speed tributaries. The FDM node includes a high-speed system and an ADM crosspoint. The high-speed system converts between an optical high-speed channel and its constituent electrical, low-speed channels through the use of frequency division multiplexing. The ADM crosspoint couples any incoming low-speed channels and any incoming tributaries to any outgoing low-speed channels and tributaries, thus implementing the ADM functionality for the FDM node.

US Patent:

6529303, Mar 4, 2003

Filed:

Sep 24, 1999

Appl. No.:

09/405367

Inventors:

Michael W. Rowan - Los Gatos CA
David B. Upham - Sunnyvale CA
Augustus Elmer - San Jose CA
Laurence J. Newell - Saratoga CA
David A. Pechner - San Jose CA
Abraham Kou - San Jose CA
James F. Coward - La Honda CA
Norman L. Swenson - Mountain View CA
Minnie Ho - Palo Alto CA
Peter H. Chang - San Jose CA
Ting K. Yee - Foster City CA
Stuart E. Wilson - Menlo Park CA

Assignee:

Kestrel Solutions, Inc. - Mountain View CA

International Classification:

H04J 1402

US Classification:

359128, 359127, 359189, 370480

Abstract:

A frequency division multiplexing (FDM) node used in optical communications networks provides add-drop multiplexing (ADM) functionality between optical high-speed channels and electrical low-speed channels. The FDM node includes a high-speed system and an ADM crosspoint. The high-speed system converts between an optical high-speed channel and its constituent electrical low-speed channels through the use of frequency division multiplexing and preferably also QAM modulation. The ADM crosspoint couples incoming low-speed channels to outgoing low-speed channels, thus implementing the ADM functionality for the FDM node.

US Patent:

7146103, Dec 5, 2006

Filed:

Jul 30, 2001

Appl. No.:

09/918886

Inventors:

Ting K Yee - Foster City CA, US
Peter H Chang - San Jose CA, US
Shin-Sheng Tarng - San Jose CA, US
Gregory M Cutler - Cupertino CA, US
Slava Yazhgur - Daly City CA, US
Ji Li - Cupertino CA, US
Laurence J Newell - Saratoga CA, US
James F Coward - Los Gatos CA, US
Michael W Rowan - Los Gatos CA, US
Norman L Swenson - Fremont CA, US
Matthew C Bashaw - Palo Alto CA, US

Assignee:

Forster Energy LLC - Las Vegas NV

International Classification:

H04J 14/02
H04J 1/00
H04J 1/04
H04J 1/08
H04B 10/04
H04B 10/05
H04B 10/08
H04B 10/145
H04B 10/148

US Classification:

398 68, 398 76, 398 82, 398 91, 398 95, 398152, 398163, 398184, 398196, 398205

Abstract:

A transmitter subsystem generates an optical signal which contains multiple subbands of information. The subbands have different polarization. For example, in one approach, two or more optical transmitters generate optical signals which have different polarization. An optical combiner optically combines the optical signals into a composite optical signal for transmission across an optical fiber. In another aspect, each optical transmitter generates an optical signal containing both a lower optical sideband and an upper optical sideband (i. e. , a double sideband optical signal). An optical filter selects the upper optical sideband of one optical signal and the lower optical sideband of another optical signal to produce a composite optical signal.

US Patent:

7447436, Nov 4, 2008

Filed:

Aug 31, 2006

Appl. No.:

11/514381

Inventors:

Ting K. Yee - Foster City CA, US
Peter H. Chang - San Jose CA, US
Chin-Sheng Tarng - San Jose CA, US
Gregory M. Cutler - Cupertino CA, US
Slava Yazhgur - Daly City CA, US
Ji Li - Cupertino CA, US
Laurence J. Newell - Saratoga CA, US
James F. Coward - Los Gatos CA, US
Michael W. Rowan - Los Gatos CA, US
Norman L. Swenson - Fremont CA, US
Matthew C. Bradshaw - Palo Alto CA, US

Assignee:

Forster Energy LLC - Las Vegas NV

International Classification:

H04B 10/08
H04B 10/04
H04B 10/06
H04B 10/145
H04B 10/148
H04J 14/02
H04J 1/00
H04J 1/04
H04J 1/08

US Classification:

398 95, 398 68, 398 82, 398 91, 398152, 398163, 398184, 398196, 398205

Abstract:

A transmitter subsystem generates an optical signal which contains multiple subbands of information. The subbands have different polarizations. For example, in one approach, two or more optical transmitters generate optical signals which have different polarizations. An optical combiner optically combines the optical signals into a composite optical signal for transmission across an optical fiber. In another aspect, each optical transmitter generates an optical signal containing both a lower optical sideband and an upper optical sideband (i. e. , a double sideband optical signal). An optical filter selects the upper optical sideband of one optical signal and the lower optical sideband of another optical signal to produce a composite optical signal.

US Patent:

7694135, Apr 6, 2010

Filed:

Jul 18, 2005

Appl. No.:

11/184049

Inventors:

Michael J. Rowan - Wakefield RI, US
Christopher T. M. Bailey - Atlanta GA, US
Kefeng Chen - Duluth GA, US
Neal Creighton - Waltham MA, US

Assignee:

Geotrust, Inc. - Mountain View CA

International Classification:

H04L 29/00

US Classification:

713166, 713162, 713167, 713173

Abstract:

A service is provided to allow a user, such as an API or web service, Internet input, or software or hardware client to perform a search on any one or multiple Uniform Resource Identifier (URI) and/or other protocol addresses accessible via a public or private network to establish a report in a summary and/or detailed format on the trustworthiness of the address.

US Patent:

20030210909, Nov 13, 2003

Filed:

Mar 4, 2003

Appl. No.:

10/382094

Inventors:

Michael Rowan - Los Gatos CA, US
David Upham - Sunnyvale CA, US
Augustus Elmer - San Jose CA, US
Laurence Newell - Saratoga CA, US
David Pechner - San Jose CA, US
Abraham Kou - San Jose CA, US
James Coward - La Honda CA, US
Norman Swenson - Mountain View CA, US
Minnie Ho - Palo Alto CA, US
Peter Chang - San Jose CA, US
Ting Yee - Foster City CA, US
Stuart Wilson - Menlo Park CA, US

International Classification:

H04J014/00

US Classification:

398/043000, 398/140000

Abstract:

A frequency division multiplexing (FDM) node used in optical communications networks provides add-drop multiplexing (ADM) functionality between optical high-speed channels and electrical low-speed channels. The FDM node includes a high-speed system and an ADM crosspoint. The high-speed system converts between an optical high-speed channel and its constituent electrical low-speed channels through the use of frequency division multiplexing and preferably also QAM modulation. The ADM crosspoint couples incoming low-speed channels to outgoing low-speed channels, thus implementing the ADM functionality for the FDM node.