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Peter B Catrysse

from Redwood City, CA
Age ~53
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Also known as:
Peter Bert Catrysse
Phone and address:
1770 Woodside Rd, Redwood City, CA 94061
Connected to:
Jonathan H Cats, 39Andrea N Catsicas, 47Ephraim H Catsiff, 100Stamatia S Catsikopoulos, 45John R Catsis, 91William T Catsonis, 73Gary C Catsoulis, 76Becky A Catt, 51Brenda K Catt, 57Jan Catt, 77

Peter Catrysse Phones & Addresses

  • 1770 Woodside Rd, Redwood City, CA 94061
  • Woodside, CA
  • Palo Alto, CA
  • San Jose, CA

Work

Company: Stanford university Dec 2012 Position: Senior research engineer

Education

Degree: Doctorates, Doctor of Philosophy School / High School: Stanford University 2003 Specialities: Electrical Engineering

Skills

Matlab • Simulations • Cmos • Image Sensors • Optics • Physics • Nanotechnology • Image Processing • Nanophotonics • Plasmonics • Nanoscale Apertures • Metallic Waveguide Arrays • Metamaterials • Sensors • Pixel Optics • Signal Processing • Numerical Electromagnetics

Industries

Research

Resumes

Resumes

Peter Catrysse Photo 1

Senior Research Engineer

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Location:
Palo Alto, CA
Industry:
Research
Work:
Stanford University
Senior Research Engineer
Stanford University Nov 2007 - Nov 2012
Engineering Research Associate
Stanford University Jul 2003 - Oct 2007
Postdoctoral Scholar
Brobeck, Phleger & Harrison Jun 2001 - Sep 2001
Cmos Image Sensor Expert
Opelin 1997 - 1998
Hardware Engineer
Education:
Stanford University 2003
Doctorates, Doctor of Philosophy, Electrical Engineering Stanford University Apr 1996
Master of Science, Masters, Electrical Engineering Vrije Universiteit Brussel 1989 - 1994
Skills:
Matlab
Simulations
Cmos
Image Sensors
Optics
Physics
Nanotechnology
Image Processing
Nanophotonics
Plasmonics
Nanoscale Apertures
Metallic Waveguide Arrays
Metamaterials
Sensors
Pixel Optics
Signal Processing
Numerical Electromagnetics

Publications

Us Patents

Integrated Color Pixel (Icp)

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US Patent:
7248297, Jul 24, 2007
Filed:
Nov 30, 2001
Appl. No.:
09/999592
Inventors:
Peter B. Catrysse - Palo Alto CA, US
Brian A. Wandell - Menlo Park CA, US
Assignee:
The Board of Trustees of the Leland Stanford Junior University - Palo Alto CA
International Classification:
H04N 5/335
H01L 31/062
US Classification:
348273, 348272, 257294
Abstract:
An integrated color pixel (ICP) with at least one integrated metal filter is presented. Rather than utilizing a separate color filter, the wavelength responsivity of the ICP is specified and integrated at pixel level into the ICP itself using metal materials already available for standard integrated circuit design and fabrication process. The ICP of the present invention is thus distinguished from a conventional color pixel constructed in a two-stage process that combines an image sensor with a color filter array or other optical material.

Effect Of The Plasmonic Dispersion Relation On The Transmission Properties Of Subwavelength Holes

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US Patent:
7417219, Aug 26, 2008
Filed:
Sep 20, 2006
Appl. No.:
11/533719
Inventors:
Peter B. Catrysse - Palo Alto CA, US
Hocheol Shin - Stanford CA, US
Shanhui Fan - Stanford CA, US
Assignee:
The Board of Trustees of the Leland Stanford Junior University - Palo Alto CA
International Classification:
H01J 3/14
H01J 5/16
H01J 40/14
US Classification:
250234, 385129, 385131, 359360, 359585, 359589
Abstract:
Using a realistic plasmonic model, an optically thick electrically conductive film with subwavelength hole or holes therein is shown to always support propagating modes near the surface plasmon frequency, where cross-sectional dimensions of the hole or holes are less than about λ/2n, λ being the wavelength of the light and nthe refractive index of the dielectric material in the hole or holes. This is the case even when material losses are taken into account. Based on the dispersion analysis, in both a single hole or hole array designs, propagating modes play a dominant role in the transport properties of incident light. These structures exhibit a new region of operation, while featuring a high packing density and diffraction-less behavior. These structures can be used in near-field scanning optical microscopy, in collection and emission modes, for writing data to an optical storage device, as wavelength-selective optical filters, for multispectral imaging of a sample, as photolithography masks for transferring an image to a photoresist-coated substrate, as light emitters, light collectors and light modulators.

Integrated Waveguide And Method For Designing Integrated Waveguide

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US Patent:
7616855, Nov 10, 2009
Filed:
Nov 15, 2004
Appl. No.:
10/989118
Inventors:
Peter B Catrysse - Palo Alto CA, US
John S. Wenstrand - Menlo Park CA, US
International Classification:
G02B 6/44
US Classification:
385113, 385114, 385146
Abstract:
An integrated waveguide including a dielectric structure configured to receive a first electromagnetic field distribution via a first major surface and having a second major surface, wherein the first electromagnetic field distribution produces a second electromagnetic field distribution within the dielectric structure. The waveguide further includes at least one metallic element disposed in the dielectric structure between the first major surface and the second major surface, the at least one metallic element structured and positioned to effect the second electromagnetic field distribution to increase an amount of the second electromagnetic field distribution that is incident upon a selected region of the second major surface.

System And Method For Estimating Physical Properties Of Objects And Illuminants In A Scene Using Modulated Light Emission

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US Patent:
20020171842, Nov 21, 2002
Filed:
Jun 4, 2001
Appl. No.:
09/874881
Inventors:
Jeffrey Dicarlo - Sunnyvale CA, US
Peter Catrysse - Palo Alto CA, US
Feng Xiao - Stanford CA, US
Brian Wandell - Menlo Park CA, US
International Classification:
G01N021/55
US Classification:
356/445000
Abstract:
Color balancing algorithms for digital image processing require an accurate estimate of the physical properties of the ambient scene illuminant, particularly its spectral power distribution. An active imaging method and apparatus estimate these properties by emitting modulated light with a known spectral power distribution into a region of a scene. Backscattered light is detected and demodulated to separate output representing active emitter light from output representing ambient illuminant light. Using the emitter-related detector output and the known emitter spectral power distribution, the surface spectral reflectance function of the illuminated scene region can be computed. Subsequently, the spectral power distribution of the ambient scene illuminant can be computed from the surface reflectance function and the illuminant-related output of the detector. The estimated spectral power distribution can be used in standard color balancing algorithms for digital or film images.

Infrared-Transparent, Polymer Fiber-Based Woven Textiles For Human Body Cooling

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US Patent:
20190211476, Jul 11, 2019
Filed:
Sep 25, 2017
Appl. No.:
16/333874
Inventors:
- Stanford CA, US
Peter B. CATRYSSE - Stanford CA, US
Jun CHEN - Stanford CA, US
Shanhui FAN - Stanford CA, US
Po-Chun HSU - Stanford CA, US
Yucan PENG - Stanford CA, US
Alex Yu SONG - Stanford CA, US
International Classification:
D01F 6/04
A41D 31/04
D01F 6/46
D03D 15/00
D01F 1/10
D01F 6/06
D03D 1/00
Abstract:
A fiber includes an elongated member and refractive index contrast domains dispersed within the elongated member. The elongated member includes at least one polymer having a transmittance of infrared radiation at a wavelength of 9.5μπι of at least about 40%.

Infrared-Transparent Porous Polymer Textile For Human Body Cooling And Heating

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US Patent:
20190008217, Jan 10, 2019
Filed:
Feb 17, 2017
Appl. No.:
16/066247
Inventors:
- Stanford CA, US
Shanhui Fan - Stanford CA, US
Po-Chun Hsu - Stanford CA, US
Alex Yu Song - Stanford CA, US
Peter B. Catrysse - Stanford CA, US
Yucan Peng - Stanford CA, US
Assignee:
The Board of Trustees of the Leland Stanford Junior University - Stanford CA
International Classification:
A41D 13/002
A41D 31/00
D06M 17/00
D01F 6/04
D01F 6/62
Abstract:
A method of regulating a temperature of a human body includes: (1) providing an article of clothing including a textile, wherein the textile includes at least one porous layer including a polyolefin; and (2) placing the article of clothing adjacent to the human body. The porous layer has pores having an average pore size in a range of 50 nm and 1000 nm.
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Peter B Catrysse from Redwood City, CA, age ~53 Get Report