Machine acceleration effects on computer controlled polishing

Oliver Faehnle; Christina Reynolds; Guoyu Yu; David Walker

doi:10.1364/OFT.2017.OM4B.1

Optical Design and Fabrication 2017 (Freeform, IODC, OFT)
OSA Technical Digest (online) (Optica Publishing Group, 2017),
paper OM4B.1
•https://doi.org/10.1364/OFT.2017.OM4B.1

Machine acceleration effects on computer controlled polishing

Oliver Faehnle, Christina Reynolds, Guoyu Yu, and David Walker

Optical Fabrication and Testing 2017

Denver, Colorado United States
9–13 July 2017
ISBN: 978-1-943580-31-6

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Novel Optical Fabrication Processes (OM4B)

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O. Faehnle, C. Reynolds, G. Yu, and D. Walker, "Machine acceleration effects on computer controlled polishing," in Optical Design and Fabrication 2017 (Freeform, IODC, OFT), OSA Technical Digest (online) (Optica Publishing Group, 2017), paper OM4B.1.

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Abstract

This paper analyzes the impact of tool mass acceleration (TMA) values onto footprint shape stability in computer controlled polishing, presenting the second derivative footprint recording (SECondo) method. First experimental evidence is presented, demonstrating that for bonnet polishing, acceleration of tool mass significantly alters the pressure distribution within the footprint and consequently affects its cross section. In addition, we present experimental data indicating that it is possible to compensate for TMA effects by adjusting the inclination angle of precession during CCP accordingly.

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