Creative and Dedicated
Chris Rollins, Ph.D., Vice President
System Science, Radiometric Calibration,Space Instrumentation, Hyperspectral Imagery, Sparse aperture arrays, Optical Design.
Mark Boies, M.S., Principal Research Scientist
Space instrumentation, System Engineering, IR Optical Design, Lidar systems, Contamination Science, System Calibration.
James N. Caron, Ph.D., Principal Research Scientist
Sparse aperture imaging, polarimetric imaging, acoustics, advanced image processing, imaging field tests, nondestructive evaluation of materials, and laser-based ultrasound.
Jemma F. Kline, M.S., Principal Research Scientist
Micro-optical systems, Space propulsion, Plasma physics, High energy laser physics, Satellite optical communications, and Pulsed power.
Burta McDonald, Administrator, Security Officer
Duane Simonson, Ph.D., Principle Scientist, Material Science, Specialized Coatings, Contamination Specialist
Varun Tangri, Ph.D., Principle Scientist, Plasma Physics, Theory and Simulation
Andrey Beresnyak, Ph.D., Principle Scientist, Plasma Physics, Astronomy
Susan DeWaters, NRL On-site administration and technical document specialist.
Tai Ragan, Engineer
Consultants: Dr. Wallace Manheimer, Dr. Robert Lehmberg, Dr. Joel Fedder, Dr. Antonio Ting
Dr. Chris Rollins, Senior Scientist, Vice President
Education: Ph.D., Physics, Northeastern University, 1984 M.S.,
Physics, Northeastern University, 1980 B. A., English Literature,
University of Rochester, 1976
Dr. Chris Rollins is Vice President and Chief Operating Officer of RSI. Dr. Rollins joined RSI in 1992, to collaborate with the Naval Research Laboratory (NRL) on the Clementine lunar spacecraft project. Since that time he has been active in several spacecraft programs including TICAS, NRL-HSI, NEMO, RIT, TacSat-4, and JMAPS, and has worked in all phases of spacecraft development, from initial design through launch and operations. For Clementine, Dr. Rollins performed systems engineering and functioned as a key technical liaison between NRL and LLNL. From February 1995 to June 1996, Dr. Rollins participated in the TICAS tactical imager architecture study. From June 1996 to March 2002, Dr. Rollins worked on the Navy EarthMap Observer (NEMO) satellite. Dr. Rollins authored the baseline hyperspectral payload design for the NEMO RFP, performed systems engineering studies, and conducted performance tests on the NEMO instruments. From September 1996 to March 1997, Dr Rollins worked on the NRL-HSI hyperspectral satellite. For this activity, he developed the baseline optical design. From June, 1997 to October 2003 , Dr. Rollins worked on the Revolutionary Imaging Technology (RIT) program in sparse-aperture space-based imaging. For the RIT program he led the development of a 16-channel multicolor camera, and participated in optical analyses and test-bed development. From October 2003 to present, Dr. Rollins has been working in the NRL Surrogate Sensor Experiment (SSE) program which evaluates large format (16 Megapixel and larger) imaging arrays for remote sensing applications. From February 2005 to July 2007, Dr. Rollins worked for the NRL TMA program and its descendent, TacSat-4, performing system trades and analyses for tactical satellite payloads. From August 2005 to present, Dr. Rollins has supported the JMAPS program and is currently the JMAPS Systems Scientist.
Mark Boies, Principal Research Scientist,
M.S. degree in Physics from Johns Hopkins University in 1988.
B.S. degrees (with honors) in both Physics and Computer Science from Colorado State University in 1984.
Experience: Mark is responsible for the business development of remote sensors and products with emphasis on the aerospace market. He has developed laser radar systems and passive spectral imagers. Many of these instruments have been flown on space-based platforms.
Mark is currently the deputy program manager for the HICO/RAIDS mission at the Naval Research Laboratory. This mission represents the first launch of a NASA payload on a Japanese launch vehicle. It will be deployed on JAXA’s JEM-EF module on the International Space Station and meets both NASA and JAXA manned mission safety requirements. Mark is also the program liaison for a sounding rocket program that provides target intercept assessment through spectral evaluation of the impact event. He is a technology liaison for NASA on the focal plane module development for the GOES-R Advanced Baseline Imager (ABI) program
He led the RSI team that developed a non-imaging spectrometer to measure spectral signatures at ultra-high speeds (125 kHz). He was the program manager for an international program with the Japanese government to design and build a vehicle-based DIAL (differential absorption laser radar) system for detection of methane gas leaks. Mark was a principal investigator on the MSX (Midcourse Space Experiment) environmental monitoring science team. Mark has been program manager for a frequency agile Lidar receiver developed for the Air Force and has been involved in the development of a spectral imaging system (visible to LWIR) used to help fight forest fires. These various projects have required that he design several infrared optical elements including several for use in a cryogenic dewar. He provides spaceborn environmental (contamination) instrument development and scientific analysis for sensors in the Hubble Service Missions (shuttle based). He has authored many papers and presentations covering optical instrumentation, space flight hardware, satellite contamination, and space born environmental findings.
Dr. James N. Caron, Principal Research Scientist,
Dr. Caron is the supervisor for our NRL On-site employees. He received his M.S. (1995) and Ph.D. (1997) in Physics from the University of Delaware, Newark, DE. During graduate study and post-doctorate work, Dr. Caron was the main researcher in the UD Laser Acoustics Lab producing seven years of experience in acoustics, optics, and electronics. He researched, designed, constructed, and operated the laser-based ultrasonic systems at UD. This includes designing and building photodetectors, servo circuits, filters, and amplifiers suitable for laser ultrasonics, operating and maintaining the Nd:YAG lasers, maintaining the laser ultrasonic system, and determining the course of the research. In this time, he invented Gas-coupled Laser Acoustic Detection. He has programming experience in Fortran, Turbo Pascal, Visual Basic and V++. Since his arrival at RSI, Dr. Caron has been researching a possible alternative to space-borne telescopes for the Naval Research Laboratory in Washington, DC; developing improved processing techniques for digital videos; and developing image-based methods to characterize laser beams. To meet the project goals, he has developed a large ensemble of novel image processing techniques, handling tasks such as image registration, spectral signature identification, polarimetric imaging, super-sampling, and most notably blind deconvolution. His SeDDaRA blind deconvolution technique has been named Advanced Imaging Magazine's 2004 ``Imaging Solution of the Year''.
Jemma F. Kline, Principal Research Scientist
Jemma F. Kline is the Founder/Manager of RSI Princeton Operations. Kline was Principal Investigator for the CAMERA retroreflector project for NIST, the MASS microspeaker Phase II SBIR project for AFRL, Electron Beam-Controlled, Microwave-Driven Plasmas SBIR Phase II project for AFRL, the Nonequilibrium Ionization MHD project for AFRL, the Mars MHD Aerobraking project for NASA, the Microwave Electrothermal Ignition Source project for NASA, the Compact Micro-Torus eXperiment (CMTX) for NASA and the International Space Sciences Organization (ISSO). Ms. Kline was Co-PI for development of new commercial high speed fiber optic pressure probes for use at the Naval Research Laboratory (NRL). Ms. Kline has experience with micro-optical systems, space propulsion, plasma physics, high energy laser physics, satellite optical communications, and pulsed power. Projects in-house at RSI and on-site at NRL have included development of a family of electrothermal thrusters, a plasma diagnostic system, micromachined optics, electron beam windows, micromachined ion optics, an X-ray multichannel detector for the NOVA laser fusion facility, an atmospheric pressure plasma generator, and a quantum well modulator optical link. Kline has provided support for the measurement of high-energy, laser-produced shocks and infrared thermal imaging for CW laser survivability tests for NRL, and high-speed photography of advanced munitions tests for the Raytheon Company.