Your search keyword '"James M. Brase"' showing total 2 results

1. Design, layout, and early results of a feasibility experiment for sodium-layer laser-guide-star adaptive optics

Author

J. A. Horton, D. A. Rapp, J. M. Duff, Horst D. Bissinger, R. Kiefer, Kenneth E. Waltjen, James M. Brase, Herbert W. Friedman, Kenneth Avicola, Scot S. Olivier, J. T. Salmon, Donald T. Gavel, J. R. Morris, R. W. Presta, and Claire E. Max

Subjects

Physics, Dye laser, business.industry, Physics::Optics, Sodium layer, Laser, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, law.invention, Telescope, Optics, Laser guide star, law, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, Physics::Atomic Physics, Computer Vision and Pattern Recognition, Guide star, Atomic vapor laser isotope separation, business, Adaptive optics

Abstract

We describe the design and the early results of a feasibility experiment for sodium-layer laser-guide-star adaptive optics. Copper-vapor-laser-pumped dye lasers from Lawrence Livermore National Laboratory’s Atomic Vapor Laser Isotope Separation program are used to create the guide star. The laser beam is projected upward from a beam director that is located ~5 m from a 0.5-m telescope and forms an irradiance spot ~2 m in diameter at the atmospheric-sodium layer (at an altitude of 95 km). The laser guide star is approximately fifth magnitude and is visible to the naked eye at the top of the Rayleigh-scattered laser beam. To date, we have made photometric measurements and open-loop wave-front-sensor measurements of the laser guide star. We give an overview of the experiment’s design and the laser systems, describe the experimental setup, show preliminary photometric and open-loop wave-front-sensor data on the guide star, and present predictions of closed-loop adaptive-optics performance based on these experimental data. The long-term goal of this effort is to develop laser guide stars and adaptive optics for use with large astronomical telescopes.

Published

1994

2. Sodium-layer laser-guide-star experimental results

Author

Herbert W. Friedman, J. M. Duff, D. A. Rapp, Kenneth Avicola, Horst D. Bissinger, Donald T. Gavel, J. R. Morris, J. T. Salmon, Scot S. Olivier, James M. Brase, Kenneth E. Waltjen, R. W. Presta, and Claire E. Max

Subjects

Physics, business.industry, Irradiance, Sodium layer, Laser, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, law.invention, Optics, Laser guide star, law, Physics::Atomic Physics, Computer Vision and Pattern Recognition, Guide star, Laser power scaling, business, Adaptive optics, Atomic vapor laser isotope separation

Abstract

We describe a series of experiments to characterize the sodium-layer guide star that was formed with the high-power laser developed for the Lawrence Livermore National Laboratory Atomic Vapor Laser Isotope Separation program. An emission spot size of 3.0 m was measured, with an implied laser irradiance spot diameter of 2.0 m. The rms spot motion at the higher laser powers, with active beam-pointing control, was less than 0.5 arcsec and had little effect on the observed spot size under these conditions. We measured the resonant backscatter from the sodium layer as a function of laser power to obtain a saturation curve. With a transmitted power of 1100 W and an atmospheric transmission of 0.6, the irradiance from the guide star at the ground was 10 (photons/cm2)/ms, corresponding to a visual magnitude of 5.1. The implications for the performance of wave-front sensors with a laser guide star of this magnitude and resulting closed-loop adaptive-optics performance are discussed.

Published

1994