Publications

Jasica, Matthew J.; Wampler, William R.; Doyle, Barney L.; Vizkelethy, Gyorgy V.; Pickrell, Gregory P.; Cowan, William D.; Colón, Albert; Bielejec, Edward S.

Abstract not provided.

Reza, Shahed R.; Colón, Albert; Cowan, William D.; Baca, A.G.; Briggs, R.D.; Neely, Jason C.

Abstract not provided.

Jasica, Matthew J.; Wampler, William R.; Doyle, Barney L.; Vizkelethy, Gyorgy V.; Pickrell, Gregory P.; Cowan, William D.; Colón, Albert; Bielejec, Edward S.

Abstract not provided.

Jasica, Matthew J.; Wampler, William R.; Doyle, Barney L.; Vizkelethy, Gyorgy V.; Pickrell, Gregory P.; Cowan, William D.; Colón, Albert; Van Heukelom, Michael V.; Glaser, Caleb E.

Abstract not provided.

Transactions of the American Nuclear Society

Jasica, Matthew J.; Wampler, William R.; Doyle, Barney L.; Pickrell, Gregory P.; Cowan, William D.; Colón, Albert; Van Heukelom, Michael V.; Glaser, Caleb E.

Abstract not provided.

Colón, Albert; Austin, Franklin H.; Baca, A.G.; Briggs, Samuel B.; Cowan, William D.; Dickerson, Jeramy R.; Douglas, Erica A.; Doyle, Barney L.; Glaser, Caleb E.; Gunning, Brendan P.; Hattar, Khalid M.; Klein, Brianna A.; Koleske, Dan K.; Tauke-Pedretti, Anna; Pickrell, Gregory P.; Vizkelethy, Gyorgy V.

Abstract not provided.

Proceedings of SPIE - The International Society for Optical Engineering

Anderson, Betty L.; Ho, James G.; Cowan, William D.; Spahn, Olga B.; Yi, Allen Y.; Flannery, Martin R.; Rowe, Delton J.; McCray, David L.; Rabb, David J.; Chen, Peter

An ultra-compact optical true time delay device is demonstrated that can support 112 antenna elements with better than six bits of delay in a volume 16″x5″x4″ including the box and electronics. Free-space beams circulate in a White cell, overlapping in space to minimize volume. The 18 mirrors are slow-tool diamond turned on two substrates, one at each end, to streamline alignment. Pointing accuracy of better than 10?rad is achieved, with surface roughness ∼45 nm rms. A MEMS tip-style mirror array selects among the paths for each beam independently, requiring ∼100 μs to switch the whole array. The micromirrors have 1.4° tip angle and three stable states (east, west, and flat). The input is a fiber-andmicrolens array, whose output spots are re-imaged multiple times in the White cell, striking a different area of the single MEMS chip in each of 10 bounces. The output is converted to RF by an integrated InP wideband optical combiner detector array. Delays were accurate to within 4% (shortest delay) to 0.03% (longest mirror train). The fiber-to- detector insertion loss is 7.82 dB for the shortest delay path. © 2010 SPIE.

Czaplewski, David A.; Patrizi, G.A.; Cowan, William D.; Kraus, Garth K.; Dyck, Christopher D.; Sullivan, Charles T.

Abstract not provided.

Resnick, Paul J.; Okandan, Murat O.; Draper, Bruce L.; Cowan, William D.

Abstract not provided.

Okandan, Murat O.; Draper, Bruce L.; Cowan, William D.

Abstract not provided.

Nordquist, Christopher N.; Czaplewski, David A.; Kraus, Garth K.; Cowan, William D.; Sullivan, Charles T.

Abstract not provided.

Journal of Microelectromechanical Systems

Czaplewski, David A.; Dyck, Christopher D.; Sumali, Hartono S.; Massad, Jordan M.; Kuppers, Jaron D.; Reines, Isak C.; Cowan, William D.; Tigges, Chris P.

A soft-landing actuation waveform was designed to reduce the bounce of a single-pole single-throw (SPST) ohmic radio frequency (RF) microelectromechanical systems (MEMS) switch during actuation. The waveform consisted of an actuation voltage pulse, a coast time, and a hold voltage. The actuation voltage pulse had a short duration relative to the transition time of the switch and imparted the kinetic energy necessary to close the switch. After the actuation pulse was stopped, damping and restoring forces slowed the switch to near-zero velocity as it approached the closed position. This is referred to as the coast time. The hold voltage was applied upon reaching closure to keep the switch from opening. An ideal waveform would close the switch with near zero impact velocity. The switch dynamics resulting from an ideal waveform were modeled using finite element methods and measured using laser Doppler vibrometry. The ideal waveform closed the switch with an impact velocity of less than 3 cm/s without rebound. Variations in the soft-landing waveform closed the switch with impact velocities of 12.5 cm/s with rebound amplitudes ranging from 75 to 150 nm compared to impact velocities of 22.5 cm/s and rebound amplitudes of 150 to 200 nm for a step waveform. The ideal waveform closed the switch faster than a simple step voltage actuation because there was no rebound and it reduced the impact force imparted on the contacting surfaces upon closure. © 2006 IEEE.

Proceedings of SPIE - The International Society for Optical Engineering

Sweatt, W.C.; Spahn, Olga B.; Cowan, William D.; Wick, David V.

Micromirrors arrays can be used to correct residual wavefront aberrations in certain optical systems. The aberration correction capability of arrays of piston-only and piston-tip-tilt micromirrors are compared. Sandia's micromirror fabrication program is discussed and two example systems are presented. © 2006 SPIE-OSA.

Cowan, William D.; Bagwell, Brett B.; Spahn, Olga B.; Sweatt, W.C.

Abstract not provided.

Cowan, William D.; Peters, D.W.; Crawford, Mary H.; Allerman, A.A.; Fischer, Arthur J.; Bogart, Katherine B.; Figiel, J.J.; Dagel, Daryl D.; Nielson, Gregory N.; Watts, Michael W.; Tigges, Chris P.; Kemme, S.A.; Sweatt, W.C.; Wendt, J.R.; Cruz-Cabrera, A.A.

Abstract not provided.

Cowan, William D.; Dagel, Daryl D.; Nielson, Gregory N.; Resnick, Paul J.; Jokiel, Bernhard J.; Tigges, Chris P.

Abstract not provided.

Dagel, Daryl D.; Cowan, William D.; Resnick, Paul J.

Abstract not provided.

Proposed for publication in the Journal of Microelectromechanical Systems.

Dyck, Christopher D.; Sumali, Hartono S.; Massad, Jordan M.; Reines, Isak C.; Cowan, William D.; Tigges, Chris P.

Abstract not provided.

Carton, Andrew J.; Sullivan, Charles T.; Dyck, Christopher D.; Nordquist, Christopher N.; Cowan, William D.; Reines, Isak C.; Kraus, Garth K.; Webster, James R.; Czaplewski, David A.; Jokiel, Bernhard J.

Abstract not provided.

Proposed for publication in the IEEE Journal of Selected Topics in Quantum Electronics.

Dagel, Daryl D.; Cowan, William D.; Spahn, Olga B.; Resnick, Paul J.; Jokiel, Bernhard J.

Abstract not provided.

Sweatt, W.C.; Cowan, William D.; Spahn, Olga B.; Dagel, Daryl D.; Wick, David V.

Abstract not provided.

Dyck, Christopher D.; Jokiel, Bernhard J.; Kraus, Garth K.; Plut, Thomas A.; Cowan, William D.; Sullivan, Charles T.

Abstract not provided.

Dyck, Christopher D.; Jokiel, Bernhard J.; Kraus, Garth K.; Plut, Thomas A.; Cowan, William D.; Sullivan, Charles T.

Abstract not provided.

Spahn, Olga B.; Dagel, Daryl D.; Mani, Seethambal S.; Sweatt, W.C.; Turner, Fawn R.; Grine, Alejandro J.; Adams, David P.; Resnick, Paul J.; Cowan, William D.

Recent world events have underscored the need for a satellite based persistent global surveillance capability. To be useful, the satellite must be able to continuously monitor objects the size of a person anywhere on the globe and do so at a low cost. One way to satisfy these requirements involves a constellation of satellites in low earth orbit capable of resolving a spot on the order of 20 cm. To reduce cost of deployment, such a system must be dramatically lighter than a traditional satellite surveillance system with a high spatial resolution. The key to meeting this requirement is a lightweight optics system with a deformable primary and secondary mirrors and an adaptive optic subsystem correction of wavefront distortion. This proposal is concerned with development of MEMS micromirrors for correction of aberrations in the primary mirror and improvement of image quality, thus reducing the optical requirements on the deployable mirrors. To meet this challenge, MEMS micromirrors must meet stringent criteria on their performance in terms of flatness, roughness and resolution of position. Using Sandia's SUMMIT foundry which provides the world's most sophisticated surface MEMS technology as well as novel designs optimized by finite element analysis will meet severe requirements on mirror travel range and accuracy.