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Sergey A Telenkov

from Sunrise, FL
Age ~62
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Also known as:
Segey Telenkov
Phone and address:
11035 39Th St, Fort Lauderdale, FL 33351
(954) 749-5089
Connected to:
Alyssa Telenko, 33Andrei A Telenkov, 64Holly Telenko, 45Josephine S Telenko, 81Janet Telenson, 99Matthew G Telepak, 56Lance K Telepnev, 60Sean M Telepo, 53Angela H Telepun, 56Jozef Telepun, 48

Sergey Telenkov Phones & Addresses

  • 11035 39Th St, Sunrise, FL 33351 (954) 749-5089
  • 1130 Woodward Heights Blvd, Hazel Park, MI 48030
  • 5604 Southwest Dr, Austin, TX 78735 (512) 358-7528
  • 2101 Burton Dr, Austin, TX 78741 (512) 442-7683
  • 2904 Barton Skwy, Austin, TX 78746 (512) 347-9236
  • San Francisco, CA
  • Detroit, MI
  • Canton, MI

Business Records

Name / Title
Company / Classification
Phones & Addresses
Sergey Telenkov
Vice Presi, Vice President
CENTRAL TEXAS SOCIETY FOR OPTICS
PO Box 66056, Austin, TX 78766
1406 3 Pts Rd, Pflugerville, TX 78660
5604 SW Pkwy APT 631, Austin, TX 78735

Publications

Us Patents

Non-Invasive Biothermophotonic Sensor For Blood Glucose Monitoring

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US Patent:
7729734, Jun 1, 2010
Filed:
Mar 7, 2006
Appl. No.:
11/368698
Inventors:
Andreas Mandelis - Toronto, Ontario, CA
Sergey Telenkov - Sunrise FL, US
International Classification:
A61B 5/145
US Classification:
600316
Abstract:
There is provided a glucose monitoring method and apparatus based on the principle of Wavelength-Modulated Differential Laser Photothermal Radiometry (WM-DPTR). Two intensity modulated laser beams operating in tandem at specific mid-infrared (IR) wavelengths and current-modulated synchronously by two electrical waveforms 180 degrees out-of-phase, are used to interrogate the tissue surface. The laser wavelengths are selected to absorb in the mid infrared range (8. 5-10. 5 μm) where the glucose spectrum exhibits a discrete absorption band. The differential thermal-wave signal generated by the tissue sample through modulated absorption between two specific wavelengths within the band (for example, the peak at 9. 6 and the nearest baseline at 10. 5 μm) lead to minute changes in sample temperature and to non-equilibrium blackbody radiation emission.

Method And Apparatus For Differential Phase Optical Coherence Tomography

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US Patent:
20030020920, Jan 30, 2003
Filed:
Jan 11, 2002
Appl. No.:
10/044421
Inventors:
Digant Dave - Austin TX, US
Thomas Milner - Austin TX, US
Sergey Telenkov - Austin TX, US
International Classification:
G01B009/02
US Classification:
356/479000
Abstract:
One form of the present invention is a dual channel optical reflectometer composed of a birefringent path coupler and an optical source path that is optically connected to the path coupler. After entering the path coupler, light is split into birefringent reference and sample paths. The reference path is optically aligned with a first collimating lens, and the collimating lens is directed into a scanning delay line. There is also a birefringent optical sample path that is also optically connected to the path coupler. The sample path is optically aligned with a polarization channel separator/combiner and a lens, to focus and direct optical beams into the turbid sample. Light backscattered from the turbid sample is collected by the second lens and orthogonal polarization channels are reunited by the polarization channel combiner. An analog-to-digital converter is connected to the amplifier, and a computer is connected to the analog-to-digital converter to analyze the output.
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Sergey A Telenkov from Sunrise, FL, age ~62 Get Report