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51. KAPAO: a MEMS-based natural guide star adaptive optics system

Author

Olivier, Scot S., Bifano, Thomas G., Kubby, Joel, Severson, Scott A., Choi, Philip I., Contreras, Daniel S., Gilbreth, Blaine N., Littleton, Erik, McGonigle, Lorcan P., Morrison, William A., Rudy, Alex R., Wong, Jonathan R., Xue, Andrew, Spjut, Erik, Baranec, Christoph, Riddle, Reed, Olivier, Scot S., Bifano, Thomas G., Kubby, Joel, Severson, Scott A., Choi, Philip I., Contreras, Daniel S., Gilbreth, Blaine N., Littleton, Erik, McGonigle, Lorcan P., Morrison, William A., Rudy, Alex R., Wong, Jonathan R., Xue, Andrew, Spjut, Erik, Baranec, Christoph, and Riddle, Reed

Abstract

We describe KAPAO, our project to develop and deploy a low-cost, remote-access, natural guide star adaptive optics (AO) system for the Pomona College Table Mountain Observatory (TMO) 1-meter telescope. We use a commercially available 140-actuator BMC MEMS deformable mirror and a version of the Robo-AO control software developed by Caltech and IUCAA. We have structured our development around the rapid building and testing of a prototype system, KAPAO-Alpha, while simultaneously designing our more capable final system, KAPAO-Prime. The main differences between these systems are the prototype's reliance on off-the-shelf optics and a single visible-light science camera versus the final design's improved throughput and capabilities due to the use of custom optics and dual-band, visible and near-infrared imaging. In this paper, we present the instrument design and on-sky closed-loop testing of KAPAO-Alpha as well as our plans for KAPAO-Prime. The primarily undergraduate-education nature of our partner institutions, both public (Sonoma State University) and private (Pomona and Harvey Mudd Colleges), has enabled us to engage physics, astronomy, and engineering undergraduates in all phases of this project. This material is based upon work supported by the National Science Foundation under Grant No. 0960343.

Published
2013

61. Performance of a MEMS-based AO-OCT system

Author

Evans, JW, Olivier, Scot S1, Bifano, Thomas G, Kubby, Joel A, Evans, JW, Zawadzki, RJ, Jones, S, Okpodu, S, Olivier, S, Werner, JS, Evans, JW, Olivier, Scot S1, Bifano, Thomas G, Kubby, Joel A, Evans, JW, Zawadzki, RJ, Jones, S, Okpodu, S, Olivier, S, and Werner, JS

Abstract

Adaptive optics (AO) and optical coherence tomography (OCT) are powerful imaging modalities that, when combined, can provide high-resolution, 3-D images of the retina. The AO-OCT system at UC Davis has been under development for 2 years and has demonstrated the utility of this technology for microscopic, volumetric, in vivo retinal imaging. The current system uses a bimorph deformable mirror (DM) made by AOptix Technologies, Inc. for low-order, high-stroke correction and a 140-actuator mirco-electrical-mechanical-system (MEMS) DM made by Boston Micromachines Corporation for high-order correction. We present our on-going characterization of AO system performance. The AO-OCT system typically has residual wavefront error of 100 nm rms. The correctable error in the system is dominated by low-order error that we believe is introduced by aliasing in the control loop. Careful characterization of the AO system will lead to improved performance and inform the design of future systems.

Published
2008

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