Programmable Adaptive Metrology for Conformal Optics Testing
Navy SBIR FY2008.1

Sol No.: Navy SBIR FY2008.1
Topic No.: N08-029
Topic Title: Programmable Adaptive Metrology for Conformal Optics Testing
Proposal No.: N081-029-0156
Firm: Physical Optics Corporation
Applied Technologies Division
20600 Gramercy Place, Bldg.100
Torrance, California 90501-1821
Contact: Yunlu Zou
Phone: (310) 320-3088
Web Site: www.poc.com
Abstract: To address the Navy need for measuring optical figures on an aspheric dome and the associated corrector optics, Physical Optics Corporation (POC) proposes to develop a new programmable adaptive metrology (PAM) for aspheric, nonaxially (nonrotationally) symmetric, conformal optical surfaces. Current interferometry techniques have limitations on testing strong aspheres and optical domes. Recent efforts have extended metrology capabilities to optics with departures from a best-fit sphere of 50-100 microns. The PAM system will be capable of measuring conformal domes and optics with departures from a best-fit sphere of millimeters. In Phase I POC will demonstrate the feasibility of PAM via a subscale prototype and associated algorithms on material such as glass or fused silica. A clear path to scale the approach to larger sizes and infrared-transparent materials in Phase II will be planned. In Phase II POC will develop a prototype for robust, reliable operation in the required operational environments, and to demonstrate the capability to measure the steeper aspheres and conformal optics on infrared-transparent materials, and with sizes up to 200 x 200 mm. The final optical figure should be within 0.1 wavelength root-mean-square deviation at 633 nm over the full clear aperture of the part.
Benefits: The advanced testing capabilities of the proposed PAM system would significantly enhance the state of the art for both military and commercial applications. This will include correcting spherical aberrations of primary mirrors in telescopes, and improving consumer products such as scanners, head-mounted displays, light projectors, and other devices. This technology can enable multiple optical surfaces to be easily replaced by a single aspheric surface, thus reducing the number of elements, weight, assembly complexity, and overall size of optical systems.

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