SBIR-STTR Award

Subaperture Stitching Interferometry for Large Convex Aspheric Surfaces
Award last edited on: 3/4/2024

Sponsored Program
SBIR
Awarding Agency
NASA : GSFC
Total Award Amount
$625,932
Award Phase
2
Solicitation Topic Code
S2.04
Principal Investigator
Paul E Murphy

Company Information

QED Technologies

1040 University Avenue
Rochester, NY 14607
   (585) 256-6540
   support@qedmrf.com
   www.qedmrf.com
Location: Single
Congr. District: 25
County: Monroe

Phase I

Contract Number: NNG05CA71C
Start Date: 1/25/2005    Completed: 7/25/2005
Phase I year
2005
Phase I Amount
$69,822
The size and accuracy specifications of telescope mirrors are ever more demanding. This is particularly true for secondary mirrors, as they are convex and thus require large-aperture optics to test them. Subaperture stitching has the potential to provide accurate high-resolution maps of large-aperture aspheric optics without the use of dedicated nulls. QED has already developed the subaperture stitching interferometer (SSI), which combines a vertical workstation with a commercially-available 4" or 6" interferometer. Nanometer-level accuracies have been obtained on spherical optics by optimally compensating subaperture placement errors, as well as automatically calibrating for systematic errors such as reference wave error and distortion. Non-null capability is enhanced since the individual subapertures have significantly less aspheric departure. However, the system is currently only capable of testing up to 280 mm optics of mild asphericity. This proposal focuses on innovations for leveraging these considerable benefits of stitching (high resolution, automatic calibration, and flexible aspheric testing) to larger and more aspheric optics. Activities will include novel stitching strategies to calibrate for gravitational deformations, adaptive asphere calibration methods, specialised platform designs, and subscale testing. This will enable more cost-effective production of convex secondary mirrors and facilitate the testing of long-radius concaves, and even of assembled systems).

Phase II

Contract Number: NNGCA0645C
Start Date: 2/7/2006    Completed: 2/6/2008
Phase II year
2006
Phase II Amount
$556,110
The size and accuracy specifications of telescope mirrors are ever more demanding. This is particularly true for secondary mirrors, as they are convex and thus require large-aperture optics to test them. Recent NASA programs, such as the Terrestrial Planet Finder (TPF) and James Webb Space Telescope (JWST), include monolithic secondary mirrors of significant size (larger than half a meter). Secondary mirrors of such large sizes are difficult and expensive to test due to the large-aperture converging and nulling optics required. Furthermore, calibration of these optics to the level required for next-generation programs is extremely challenging. Subaperture stitching has the potential to provide accurate high-resolution maps of large-aperture aspheric optics without the use of even larger aperture optics or dedicated nulls. QED's Subaperture Stitching Interferometer (SSIREG) has achieved nanometer-level accuracies on spherical optics with its novel compensation techniques. Non-null capability is enhanced since the individual subapertures have significantly less aspheric departure. However, the system is currently only capable of testing up to 280 mm optics of mild asphericity. Phase I work demonstrated that the technology is scalable to larger aperture sizes. This proposal focuses on innovations for leveraging the considerable benefits of stitching (high resolution, automatic calibration, and flexible aspheric testing) to aspheric optics. Activities will include uncertainty analyses of aspheric tests, subscale measurement demonstrations, and development of concepts for testing larger amounts of aspheric departure.