Resumes
Resumes
Ilya Agurok Phones & Addresses
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Arlington Heights, IL
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18864 Vista Del Canon #G, Newhall, CA 91321
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Long Beach, CA
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1150 Capitol Dr, San Pedro, CA 90732
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16892 Cod Cir, Huntington Beach, CA 92647
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Los Angeles, CA
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Torrance, CA
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1150 W Capitol Dr UNIT 149, San Pedro, CA 90732
Work
Position:
Service Occupations
Education
Degree:
High school graduate or higher
Publications
Us Patents
Real-Time Opto-Electronic Image Processor
View pageUS Patent:
6353673, Mar 5, 2002
Filed:
Apr 27, 2000
Appl. No.:
09/560412
Inventors:
Paul I. Shnitser - Irvine CA
Sergey Sandomirsky - Irvine CA
Ilya Agurok - Long Beach CA
Aramais Avakian - Pasadena CA
Sergey Sandomirsky - Irvine CA
Ilya Agurok - Long Beach CA
Aramais Avakian - Pasadena CA
Assignee:
Physical Optics Corporation - Torrance CA
International Classification:
G06T 900
US Classification:
382103, 382191, 382261, 382274
Abstract:
A system and method for real time optical processing of images by simultaneous combining the variable set of images in selected spectral intervals. Spectral images at a plurality of spectral intervals are collected if needed. According to criteria established in a particular application, coefficients for an optimal combination of selected spectral intervals are calculated. Positive and negative images are continuously captured through the optical filter whose transmission spectrum adjusted to positive and negative coefficients of the optimal combination. Negative images are subtracted from positive images and a sequence of resulting optimized images is displayed in real time.
Beam Combiner
View pageUS Patent:
6369925, Apr 9, 2002
Filed:
Jun 9, 2000
Appl. No.:
09/591335
Inventors:
Ilya Agurok - Long Beach CA
Lonnie Lindsey - Westminster CA
Lonnie Lindsey - Westminster CA
Assignee:
Physical Optics Corporation - Torrance CA
International Classification:
H04B 1000
US Classification:
359172, 359124, 359618, 359641
Abstract:
A nonimaging beam combiner and collimator. The nonimaging beam combiner and collimator can include at least two light sources that emit light of the same wavelength through a focus point and a nonimaging element that receives the light of the same wavelength after the focus point and collimates the light at the same wavelength through the atmosphere. The at least two light sources can include fiber light sources, optical fibers, gradient index lenses, fiber lasers or laser diodes. The collimator can include an input surface, a paraboloid surface located adjacent to the input surface, a conical surface located adjacent to the paraboloid surface, and an ellipsoid surface located adjacent to the conical surface and located on an opposite side of the collimator from the input surface. The paraboloid surface can include a total internal reflection surface.
Flush Luminaire With Optical Element For Angular Intensity Redistribution
View pageUS Patent:
6565239, May 20, 2003
Filed:
Feb 27, 2001
Appl. No.:
09/794797
Inventors:
Alexander Rizkin - Redondo Beach CA
Ilya Agurok - Huntington Beach CA
Robert H. Tudhope - Rancho Palos Verdes CA
Ilya Agurok - Huntington Beach CA
Robert H. Tudhope - Rancho Palos Verdes CA
Assignee:
Farlight, L.L.C. - Wilmington CA
International Classification:
B60Q 106
US Classification:
362373, 362153, 3621531, 362330, 362339, 362332, 362340
Abstract:
A luminaire flush with a horizontal surface and comprising a housing, an optical window, a light source, and an optical element. The housing has an internal cavity disposed beneath the horizontal surface and defines an opening disposed adjacent the horizontal surface. The optical window, substantially flat and transparent, has a surface that overlays the housing opening. The light source, disposed within the housing cavity, provides a spatial light distribution pattern which defines an optical axis that is disposed substantially perpendicular relative to the optical window surface. The optical element, also disposed within the housing cavity, redistributes light rays emitted by the light source along preselected angles relative to the horizontal surface.
Highly Efficient Luminaire Having Optical Transformer Providing Precalculated Angular Intensity Distribution And Method Therefore
View pageUS Patent:
6543911, Apr 8, 2003
Filed:
May 8, 2000
Appl. No.:
09/566521
Inventors:
Alexander Rizkin - Redondo Beach CA
Robert H. Tudhope - Rancho Palos Verdes CA
Ilya Agurok - Long Beach CA
David Ruiz - Redondo Beach CA
Robert H. Tudhope - Rancho Palos Verdes CA
Ilya Agurok - Long Beach CA
David Ruiz - Redondo Beach CA
Assignee:
FarLight LLC - Wilmington CA
International Classification:
F21V 700
US Classification:
362307, 362240, 362245, 362347, 362309
Abstract:
A highly efficient luminaire. The luminaire includes a light source that emits light. The emitted light is redirected by a light transformer having a curved circular reflective interior surface, the reflective interior surface reflecting the light in a predetermined pattern. A substantial amount of light being may be reflected close to an axis coincident with a radial line defining a radius of the circular reflective interior surface. Additionally, a substantial amount of light may be reflected in a pattern with low divergency or parallel with an axis of the light transformer. The light is transmitted to the exterior of the luminaire by an optical window.
Multi-Reflector Led Light Source With Cylindrical Heat Sink
View pageUS Patent:
7905634, Mar 15, 2011
Filed:
Jun 15, 2009
Appl. No.:
12/456392
Inventors:
Ilya Agurok - Torrance CA, US
Waqidi Falicoff - Stevenson Ranch CA, US
William A. Parkyn - Lomita CA, US
Oliver Dross - Köln, DE
Waqidi Falicoff - Stevenson Ranch CA, US
William A. Parkyn - Lomita CA, US
Oliver Dross - Köln, DE
Assignee:
Light Prescriptions Innovators, LLC - Altadena CA
International Classification:
F21V 7/00
US Classification:
36229601, 362297, 362373, 362346
Abstract:
A cylindrical light source comprises multiple LEDs mounted on either the exterior or interior surface of the cylinder, with heat-sink fins respectively on its interior or exterior. The LEDs emit radially, but their emission is redirected along the cylinder axis by individual ellipsoidal reflectors.
Passive Electro-Optical Tracker
View pageUS Patent:
8280113, Oct 2, 2012
Filed:
May 24, 2010
Appl. No.:
12/786196
Inventors:
Ilya Agurok - Santa Clarita CA, US
Waqidi Falicoff - Stevenson Ranch CA, US
Waqidi Falicoff - Stevenson Ranch CA, US
Assignee:
Light Prescriptions Innovators, LLC - Altadena CA
International Classification:
G06K 9/00
G06F 19/00
G06F 19/00
US Classification:
382103, 382291, 235411
Abstract:
A passive electro-optical tracker uses a two-band IR intensity ratio to discriminate high-speed projectiles and obtain a time-varying speed estimate from their time-varying temperature, as well as determining the trajectory back to the source of fire. In an omnidirectional system a hemispheric imager with an MWIR spectrum splitter forms two CCD images of the environment. Various methods are given to determine the azimuth and range of a projectile, both for clear atmospheric conditions and for nonhomogeneous atmospheric conditions. One approach uses the relative intensity of the image of the projectile on the pixels of a CCD camera to determine the azimuthal angle of trajectory with respect to the ground, and its range. A second uses a least squares optimization over multiple frames based on a triangle representation of the smeared image to yield a real-time trajectory estimate.
Passive Electro-Optical Tracker
View pageUS Patent:
8355536, Jan 15, 2013
Filed:
Feb 22, 2010
Appl. No.:
12/709780
Inventors:
Ilya Agurok - Santa Clarita CA, US
Waqidi Falicoff - Stevenson Ranch CA, US
Roberto Alvarez - Glendale CA, US
Waqidi Falicoff - Stevenson Ranch CA, US
Roberto Alvarez - Glendale CA, US
Assignee:
Light Prescriptions Innovators LLC - Altadena CA
International Classification:
G06K 9/00
US Classification:
382103, 235411, 250330, 250334, 250348, 329301, 348274, 351206, 367129, 382141, 382274
Abstract:
A passive electro-optical tracker uses a two-band IR intensity ratio to discriminate high-speed projectiles and obtain a speed estimate from their temperature, as well as determining the trajectory back to the source of fire. In an omnidirectional system a hemispheric imager with an MWIR spectrum splitter forms two CCD images of the environment. Three methods are given to determine the azimuth and range of a projectile, one for clear atmospheric conditions and two for nonhomogeneous atmospheric conditions. The first approach uses the relative intensity of the image of the projectile on the pixels of a CCD camera to determine the azimuthal angle of trajectory with respect to the ground, and its range. The second calculates this angle using a different algorithm. The third uses a least squares optimization over multiple frames based on a triangle representation of the smeared image to yield a real-time trajectory estimate.
Luminaire Illumination System And Method
View pageUS Patent:
8576406, Nov 5, 2013
Filed:
Jul 23, 2009
Appl. No.:
12/508500
Inventors:
Tomasz Jannson - Torrance CA, US
Ilya Agurok - Long Beach CA, US
Thomas Forrester - Hacienda Heights CA, US
Ranjit Pradhan - Torrance CA, US
Min-Yi Shih - Redondo Beach CA, US
Ilya Agurok - Long Beach CA, US
Thomas Forrester - Hacienda Heights CA, US
Ranjit Pradhan - Torrance CA, US
Min-Yi Shih - Redondo Beach CA, US
Assignee:
Physical Optics Corporation - Torrance CA
International Classification:
G01B 9/02
US Classification:
356496
Abstract:
A method of constructing a non-imaging beam transformer includes reducing a tailored illumination function from a predetermined light source to a source point response illumination function; calculating a plurality of transformation pairs for the predetermined light source, the transformation pairs identifying the radii of illumination of the light source at given source output angles; determining a desired lighting profile for light output at a region of interest to be illuminated by the beam transformer; determining a surface profile of a surface of the beam transformer such that for given output angles of the light source, the transformation pairs at those output angles are satisfied to correspond to the desired lighting profile; and constructing the beam transformer having the surface profile determined based on the transformation pairs. The method can include characterizing a specific angular output distribution of a light source to calculate the transformation pairs.