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DoD mission support: missile tracking, satellite signatures, sensor development. ... Sidereal tracking of Comet Linear VZ 13 with the 2.4m Telescope on July 6, 2007 ...
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Slide 1:Space Object Characterization Studies and the Magdalena Ridge Observatory’s 2.4-meter Telescope
Photo by Mark Vincent Eileen V. Ryan and William H. Ryan New Mexico Institute of Mining and Technology
Collaborators: Dr. William H. Ryan (NMT/MRO) Dr. Van Romero (NMT/MRO) Dr. Mark Pesses (SAIC) Mr. James Brown (AFRL/VSBYB) Lt. Justin Cowley (AFRL/VSBYB) Dr. Phan Dao (AFRL/VSBYB) Dr. Michael Kendra (AFRL/VSBYB) Dr. Patrick McNicholl (AFRL/VSBYB) Mr. Robert O’Neil (AFRL/VSBYB) Dr. James Murguia (SSSC) Mr. Jonathon Mooney (SSSC) Mr. Rick Nelson (SSSC) Mr. Greg Diaz (SSSC) Mr. Toby Reeves (SSSC) Dr. Mara Payne (Boeing) Dr. Steve Gregory (Boeing) Site Location Classical astronomical research, with queue & remote observing (e.g., small bodies, transient phenomena). DoD mission support: missile tracking, satellite signatures, sensor development. (The telescope is fast-tracking and can point 2? below horizon). Support & enhance NM education & public outreach. The 2.4 meter telescope has three basic objectives: The MRO 2.4-meter Project: Elevation over azimuth gimbaled telescope. Optical design is f/8.8 modified Ritchey-Chrétien, with 2 Nasmyth & 4 bent-Cass. ports. (FOV: 19 arcmin) Shack-Hartmann Sensor Includes auto-guiding, a field derotator, & baffles. Instrumentation: 4Kx4K CCD imager, guest IR Camera, and low-resolution Spectrograph. Telescope Configuration:Slide 5:Current Status:
First Light Occurred on October 31, 2006, & the Telescope is Undergoing Commissioning and Integration. Research and Space Situational Awareness Work is Underway. First Science: Observations of Pluto as it occulted a 15th magnitude star on March 18, 2007 to monitor Pluto’s atmospheric variability.
Slide 6:Near-Earth Comet Linear VZ 13
Sidereal tracking of Comet Linear VZ 13 with the 2.4m Telescope on July 6, 2007
Slide 7:Tracking NEA 2007 FK1
Non-sidereal tracking of near-Earth Asteroid 2007 FK1 with the 2.4m Telescope on May 14, 2007
Slide 8:Tracking LEO NORAD: 31793
Non-sidereal tracking of a LEO (altitude ~850 km) NORAD 31793 rocket body on July 18, 2007
Slide 9:Science Focus Areas: Asteroids
NASA-Funded Vesta Asteroid Family Project: (E. Ryan & B. Ryan) Direct model simulation with two objects: a good general match to features in the observed lightcurve for 3155 Lee. Complex lightcurve of asteroid 3155 Lee taken 1.8m VATT telescope.
Slide 10:Characterization of NEOs
Follow-up and Physical Characterization of Near-Earth Objects (Capability extends to asteroids = 140m) Lightcurve and polarization work in collaboration with Catalina Sky Survey. The 2.4m has a large enough aperture for astrometry of the smallest bodies (currently 30% of 1km discovered objects are lost). A collaborative with Pan-STARRS & CSS is being established for this work.
Slide 11:Non-Resolved Imaging of RSOs
Spectrophotometry & Forward Modeling Polarimetric Photometry (M. Pesses, this session) Simultaneous Observations from Multiple Sites Simultaneous Temporal and Spectral Sensor Testing Space Weather Monitoring (V. Romero et al., this session) Techniques: Emphasis on LEO Objects
Slide 12:Lightcurves & Direct Modeling
Complex Shapes Multiple Objects
Slide 13:Simultaneous Lightcurves: Shapes
LEO Objects HEO/GEO Objects
Slide 14:Sensor Testing: Multi-Spectral Imaging
• Real-time spectral imaging (no temporal latency) • Temporal co-registration between color images • Spatial co-registration between color images • Color bands can be designed for specific applications Faster-than-Video frame rates (90 Hz)
Slide 15:Visible Multi-Wavelength Spectral Sensor
MRO is working on the testing of a visible spectral microlens sensor in collaboration with Hanscom Air Force Research Laboratory, Battlespace Surveillance Innovation Center. The objective is to improve space object identification techniques. Data taken with the microlens sensor (developed by Solid State Scientific Corporation) can simultaneously and instantaneously obtain images in 16 different spectral bands (at visible wavelengths: 0.43 – 0.83 microns). 16-Color Visible Spectral Imager
Slide 16:Multi-Spectral Imaging
A test Observing Run will take place September 19 – 30, 2007 coupling this microlens sensor to MRO’s 2.4-meter telescope. Objects will be LEOs brighter than 5th visual magnitude. Spectro-Photometry of LEOs at millisec rates
Slide 17:Summary
Spectrophotometry of LEOs Sensor Development & Deployment Polarimetric Photometry Simultaneous Observations from Multiple Sites Space Environment Monitoring Initiating Testing Phase during Telescope Commissioning
Slide 18:Selected Image Reconstruction
Binary Star: Zeta Bootis (0.7" separation). Images taken with the 2.4m telescope on May 28, 2007. Conditions: 36 mph winds, 1.3 arcsec seeing, thin clouds, 1 second exposures. Radial plot Selected Image Reconstruction: 13 best of 1000 images taken with 0.001 second exposures, aligned and averaged. Before After
Slide 19:Selected Image Reconstruction
Another Binary Star: Rotanev (0.6" separation). Images taken with the 2.4m telescope on May 28, 2007. Rotanev and SIR: 15 best of 1000 images taken with 0.001 second exposures, aligned and averaged using the MRO 2.4m telescope on May 28, 2007. Rotanev and AO: Imaged at Starfire Optical Range using Adaptive Optics.
Slide 20:Tracking Low-Earth Orbit Objects
International Space Station Observation of the ISS taken with the 2.4m telescope on July 14, 2007
