Michael John Cumbo, 66Albany, NY

6625378, Sep 23, 2003

Oct 5, 2001

09/972023

Nada A. OBrien - Santa Rosa CA
J. Gordon H. Mathew - Santa Rosa CA
Michael J. Cumbo - Santa Rosa CA
Bryant P. Hichwa - Santa Rosa CA
Robert W. Adair - Santa Rosa CA

JDS Uniphase Corporation - San Jose CA

G02B 632

385140, 385 24, 385 32, 385 34, 359283

A variable optical attenuator device is provided for modulating an optical signal. The attenuator device includes a variable attenuation assembly with an electrochromic structure interposed between a first electrode and a second electrode. The electrochromic structure is configured to reversibly change its optical characteristics from a bleached off state to a colored active state under the influence of an electrical potential applied to the first and second electrodes to thereby modulate the optical signal. The optical attenuator device includes at least one lens attached to the variable attenuation assembly. The lens cooperates with the variable attenuation assembly to direct the optical signal towards the electrochromic structure. Waveguides such as optical fibers define ports at the outer endface of the lens for the optical signal.

7444049, Oct 28, 2008

Dec 22, 2006

11/615883

Kyungbum Kim - Cotati CA, US
Laurent Vaissié - Oviedo FL, US
Robert G. Waarts - Los Altos CA, US
Andrew Stadler - San Francisco CA, US
Michael J. Cumbo - Santa Rosa CA, US

Raydiance, Inc. - Orlando FL

G02B 6/34
G02B 5/18

385 37, 359566

A chirped pulse amplification (CPA) system and method is described wherein the pulse is stretched using multiple passes through a Bragg grating or compressed using multiple passes through a Bragg grating. A switch may be used to control the number of passes through the Bragg grating, thus, tuning the compressed or the stretched pulse width. The pulse may be directed through an amplifier between the multiple passes through the Bragg grating to apply amplification to the stretched pulse multiple times. The Bragg grating may include a fiber Bragg grating, a volume Bragg grating, or a Bragg waveguide.

2005016, Aug 4, 2005

Jan 27, 2005

11/044326

Michael Cumbo - Santa Rosa CA, US

H01S003/06

372066000, 372067000

A waveguide laser is formed by starting with a glass disc doped with a rare earth element to define a lasant material. The disc is etched or machined to define an elongated waveguide channel having a spiral configuration. The open area between the walls of the waveguide channel is filled with a cladding material. An end reflector is formed on the radial inner end of the spiral waveguide. First cladding layers are formed on both sides of the spiral waveguide. A second cladding layer is deposited on at least one of the first cladding layers. A heat sink is connected to the second cladding layer. A plurality of optical pump sources are positioned about the side walls of the structure to excite the lasant material and generate a laser beam. In one preferred embodiment, the side walls of the structure are provided with a convex configuration to enhance pump coupling.

6261641, Jul 17, 2001

Nov 4, 1999

9/433441

Jerry Zieba - Santa Rosa CA
Curtis Ross Hruska - Santa Rosa CA
Steven P. Sapers - Santa Rosa CA
Michael J. Cumbo - Santa Rosa CA
Nada O. O'Brien - Santa Rosa CA

Optical Coating Laboratory, Inc. - Santa Rosa CA

B05D 506

4273897

Polymeric coating materials used to protect electrochromic devices from environmental and mechanical damage arc provided. The protective polymeric coating materials are physically, chemically and optically compatible with the electrochromic cell layers of electrochromic devices. The polymeric coating materials are polymers having generic polymer back-bones selected from the group of polyimides, polybenzimidazoles, polybenzothiazoles, polybenzoxazoles, poly(phenylene ethers), polyquinolines, polycarbonates, and polysulfones.

5724175, Mar 3, 1998

Jan 2, 1997

8/735431

Bryant P. Hichwa - Sonoma CA
Richard A. Bradley - Sonoma CA
Steven P. Sapers - Sonoma CA
Michael J. Cumbo - Santa Rosa CA
J. Gordon H. Mathew - Sonoma CA

Optical Coating Laboratory, Inc. - Santa Rosa CA

G02F 115

359265

The present invention is directed to method for manufacturing electrochromic devices using laser ablation techniques. More specifically, the present invention uses laser ablation to provide a simple, noncontact method of patterning electrochromic devices to a controlled depth, to form an electrochromically active area. Furthermore, laser patterning is conducive to the formation of multiple electrochromic devices on a single substrate.

5995271, Nov 30, 1999

Oct 7, 1997

8/946604

Jerry Zieba - Santa Rosa CA
Curtis Ross Hruska - Santa Rosa CA
Steven P. Sapers - Santa Rosa CA
Michael J. Cumbo - Santa Rosa CA
Nada A. O'Brien - Santa Rosa CA

Optical Coating Laboratory, Inc. - Santa Rosa CA

G02F 115

359265

The present invention is directed to a polymeric coating material used to protect electrochromic devices from environmental and mechanical damage. The protective polymeric coating material in the present invention are physically, chemically and optically compatible with the electrochromic cell layers. The polymeric coating materials in the present invention are polymers having generic polymer back-bones selected from the group consisting of polyimides, polybenzimidazoles, polybenzothiazoles, polybenzoxazoles, poly(phenylene ethers), polyquinolines, polycarbonates and polysulfones.

6204953, Mar 20, 2001

Nov 4, 1999

9/434037

Jerry Zieba - Santa Rosa CA
Curtis Ross Hruska - Santa Rosa CA
Steven P. Sapers - Santa Rosa CA
Michael J. Cumbo - Santa Rosa CA
Nada A. O'Brien - Santa Rosa CA

Optical Coating Laboratory, Inc. - Santa Rosa CA

G02F 115
G02F 1153

359265

Polymeric coating materials used to protect electrochromic devices from environmental and mechanical damage are provided. The protective polymeric coating materials are physically, chemically and optically compatible with the electrochromic cell layers of electrochromic devices. The polymeric coating materials are polymers having generic polymer back-bones selected from the group of polyimides, polybenzimidazoles, polybenzothiazoles, polybenzoxazoles, poly(phenylene ethers), polyquinolines, polycarbonates, and polysulfones.

5959762, Sep 28, 1999

Nov 5, 1997

8/965000

Steven P. Bandettini - Forestville CA
Lindsey Brown - Healdsburg CA
Bryant P. Hichwa - Santa Rosa CA
Michael J. Cumbo - Santa Rosa CA
J. Gordon H. Mathew - Santa Rosa CA
Nada A. O'Brien - Santa Rosa CA

Optical Coating Laboratory, Inc. - Santa Rosa CA

G02F 115
H04N 572

359265

A flexible panel is provided that is easily and conformingly applied to a curved display screen of a VDU to afford, in a lightweight manner, variably adjustable contrast enhancement of the VDU while simultaneously providing a decrease in the amount of ambient light reflected from the curved display screen. The flexible panel is a glass microsheet layered, on one side thereof, with an antireflection coating and, on the other side, with an electrochromic device. The electrochrmic device allows for variable adjustment of the contrast of the VDU as a function of the voltage applied across the electrochromic device. The flexible glass microsheet dually possesses the advantages of conventional rigid glass panels, such as excellent optical performance, high durability, capability of being coated with various optical coatings under extreme temperature, pressure and chemical conditions and the additional benfeit of physical flexibility. This flexibility allows for easy application to variously sized and shaped curved VDU display screens. The electrochromic device is a six-layered structure deposited, in order from the layer adjacent the panel: a 1 quarter wavelength (QW) alumina layer; a first indium-tin-oxide (ITO) layer; a tungsten trioxide (WO. sub.