CRYOGENICOPTICAL SENSOR Project U039k, ProjectManager V. Yatsenkos

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CRYOGENIC-OPTICAL SENSOR(Project U039k,
Project-Manager V. Yatsenko)s

• Our scientific group was started in 2002
  for the purpose of developing and utilizing
  Environmental optical-cryogenic capabilities and
  technology in the commertial market-place.
• Our goal is to provide the highest level
  of research, quality, manufacturing of
  experimental device, and support to our clients
  in the disciplines of Cryogenic, Optics and
  Software.

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CRYOGENIC-OPTICAL SENSOR(Project U039k,
Project-Manager V. Yatsenko)s

• Our product line includes laboratory
  optic-cryogenic sensors, electro-optic test
  equipment, magnetic suspensions, models and
  signal processing tool.
• Today, we are actively involved in
  supporting superconducting sensing technologies,
  a Maglev high speed train systems, control
  systems, signal processing technologies, and the
  application of magnetic levitation to in
  navigation technologies.

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ISR FMCI

• V. A. YATSENKO - 03022 Prospect Glushkova 40
• Institute of Space Research NASU-NSAU
• Tel, Fax (044) 380-266-41-24
• E-mail
• fmci_at_public.icyb.kiev.ua
• vitaliy_yatsenko_at_yahoo.com

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DESIGN ENGINEERING CAPABILITIES

• Custom Signal Processing Components
• Custom Optical Components
• Custom Magnetic Components
• Accessories for Superconducting Gravimeter

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CRYOGENIC-OPTICAL SENSORInstitute of Space
Research NASU-NSAUInstitute of Physics of
the National Academy of Science of UkraineThe
Scientific Research Institute Algorithm
Engineering of Academy of Sciences. Uzbekistan
Scientific Foundation of Researchers and
Specialists on Molecular Cybernetics and
Informatics

• Laboratory sensors
• Environmental sensors
• Space application

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LABORATORY SENSORS

• Scientific Sensor
• Special Sensor

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ENVIRONMENTAL SENSORS

• Superconductive Gravimeter
• Magnetic Suspension
• Optical registration system,
• Control System
• Signal processing tool
• Method of a superconducting probe suspension
• (equilibrium positions, resulsive forces
  levitation etc.)
• Mathematical Models
• Global Optimization Methods of gravimeters
  design.
• Method of the absolute and relative gravity
  acceleration measure by superconductive devices

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OPTICAL SENSOR

• Basic ?lements
• Light source laser diode
• Method of light supply to a probe ?ptical fibre
• ?nterferometer two bundle Michelson
  interferometer
• Signal light intensity reflected from
  interferometer or change of radiation power of
  the laser diode under changing a probe position

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OPTICAL SENSOR

• Expected parameters
• Legth of lazer radiation wave, ?? - 635
• Power of a laser diode ?W - 10
• Length of the optical fiber, ? - 5
• Length of laser coherence, ? - 0,1 1
• Distance from the probe surface to the fiber,
  ?? - 1
• ??nimal detected distance, ?? - 10

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SIGNAL PROCESSING TOOL

• Filters
• Estimators
• Neural Networks
• Compensators
• Simulation
• Global Optimization

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MAGNETIC SUSPENSION

• Sensitivity g g.
• Stable null-point
• Stable performance for the long time

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SUPPORT SERVICES

• Measurement and Control
• Propotype Development
• Design Development
• Custom Manufecturing and
• Integration