Publications

Proceedings of SPIE - The International Society for Optical Engineering

Romero, Edward; Paez, Thomas L.; Brown, Timothy L.; Miller, Timothy

Sandia National Laboratories currently utilizes two laser tracking systems to provide time-space-position-information (TSPI) and high speed digital imaging of test units under flight. These laser trackers have been in operation for decades under the premise of theoretical accuracies based on system design and operator estimates. Advances in optical imaging and atmospheric tracking technology have enabled opportunities to provide more precise six degree of freedom measurements from these trackers. Applying these technologies to the laser trackers requires quantified understanding of their current errors and uncertainty. It was well understood that an assortment of variables contributed to laser tracker uncertainty but the magnitude of these contributions was not quantified and documented. A series of experiments was performed at Sandia National Laboratories large centrifuge complex to quantify TSPI uncertainties of Sandia National Laboratories laser tracker III. The centrifuge was used to provide repeatable and economical test unit trajectories of a test-unit to use for TSPI comparison and uncertainty analysis. On a centrifuge, testunits undergo a known trajectory continuously with a known angular velocity. Each revolution may represent an independent test, which may be repeated many times over for magnitudes of data practical for statistical analysis. Previously these tests were performed at Sandia's rocket sled track facility but were found to be costly with challenges in the measurement ground truth TSPI. The centrifuge along with on-board measurement equipment was used to provide known ground truth position of test units. This paper discusses the experimental design and techniques used to arrive at measures of laser tracker error and uncertainty. © 2009 Copyright SPIE - The International Society for Optical Engineering.

Society for Experimental Mechanics - 11th International Congress and Exhibition on Experimental and Applied Mechanics 2008

Miller, Timothy J.; Schreier, Hubert W.; Valley, Michael T.; Brown, Timothy L.

Conventional tracking systems measure time-space-position data and collect imagery to quantify the flight dynamics of tracked targets. However, they do not provide 6-degree-of-freedom measurements combined with spin rate, wobble, and other flight related parameters associated with non-rigid body motions. Using high-speed digital video cameras and image processing techniques, it may be possible to measure test-unit attitude and surface deformations during key portions of the test-unit's trajectory. This paper discusses the viability of applying Digital Image Correlation (DICa) methods to image data collected from two laser tracking systems. Stereo imaging methods have proven effective in the laboratory for quantifying temporally and spatially resolved 3D motions across a target surface. The principle limitations of the DIC method have been the need for clean imagery and fixed camera positions and orientations. However, recent field tests have demonstrated that these limitations can be overcome to provide a new method for quantifying flight dynamics with stereo laser tracking and high-speed video imagery in the presence of atmospheric turbulence. © 2008 Society for Experimental Mechanics Inc.

Valley, Michael T.; Brown, Timothy L.

Abstract not provided.

Valley, Michael T.; Brown, Timothy L.

Abstract not provided.

Brown, Timothy L.; Davie, Neil T.; Dykes, James A.; Neidigk, Matthew N.

Abstract not provided.