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Deep Interior Mission: Imaging the Interior of Near-Earth Asteroids Using Radio Reflection TomographyNear-Earth asteroids are important exploration targets since they provide clues to the evolution of the solar system. They are also of interest since they present a clear danger to Earth. Our mission objective is to image the internal structure of two NEOs using radio reflection tomography (RRT) in order to explore the record of asteroid origin and impact evolution, and to test the fundamental hypothesis that some NEOs are rubble piles rather than consolidated bodies. Our mission s RRT technique is analogous to doing a CAT scan of the asteroid from orbit. Closely sampled radar echoes are processed to yield volumetric maps of mechanical and compositional boundaries, and to measure interior material dielectric properties. The RRT instrument is a radar that operates at 5 and 15 MHz with two 30-m (tip-to-tip) dipole antennas that are used in a cross-dipole configuration. The radar transmitter and receiver electronics have heritage from JPL's MARSIS contribution to Mars Express, and the antenna is similar to systems used in IMAGE and LACE missions. The 5-MHz channel is designed to penetrate greater than 1 km of basaltic rock, and 15-MHz penetrates a few hundred meters or more. In addition to RRT volumetric imaging, we use redundant color cameras to explore the surface expressions of unit boundaries, in order to relate interior radar imaging to what is observable from spacecraft imaging and from Earth. The camera also yields stereo color imaging for geology and RRT-related compositional analysis. Gravity and high fidelity geodesy are used to explore how interior structure is expressed in shape, density, mass distribution and spin. Ion thruster propulsion is utilized by Deep Interior to enable tomographic radar mapping of multiple asteroids. Within the Discovery AO scheduling parameters we identify two targets, S-type 1999 ND43 (approximately 500 m diameter) and V-type 3908 Nyx (approximately 1 km), asteroids whose compositions bracket the diversity of solar system materials that we are likely to encounter, from undifferentiated to highly evolved. The 5-15 MHz radar is capable of probing more primitive bodies (e.g. comets or C-types) that may be available given other launch schedules. 5 MHz radar easily penetrates, with the required SNR , greater than 1 km of basalt (a good analog for Nyx). Basalt has a greater loss tangent than expected for most asteroids, although iron-rich M-types are probably not appropriate targets. 15 MHz radar penetrates the outer approximately 100 m of rocky 1 km asteroids and the deep interiors of comets. Laboratory studies of the most common NE0 materials expected (S-, C- and V-type meteorite analogs) will commence in 2005.
Document ID
20050161989
Acquisition Source
Headquarters
Document Type
Conference Paper
Authors
Safaeinili, A.
(Jet Propulsion Lab., California Inst. of Tech. Pasadena, CA, United States)
Asphaug, E.
(California Univ. Santa Cruz, CA, United States)
Rodriquez, E.
(Jet Propulsion Lab., California Inst. of Tech. Pasadena, CA, United States)
Gurrola, E.
(Jet Propulsion Lab., California Inst. of Tech. Pasadena, CA, United States)
Belton, M.
(Belton Space Exploration Initiatives)
Klaasen, K.
(Jet Propulsion Lab., California Inst. of Tech. Pasadena, CA, United States)
Ostro, S.
(Jet Propulsion Lab., California Inst. of Tech. Pasadena, CA, United States)
Plaut, J.
(Jet Propulsion Lab., California Inst. of Tech. Pasadena, CA, United States)
Yeomans, D.
(Jet Propulsion Lab., California Inst. of Tech. Pasadena, CA, United States)
Date Acquired
August 23, 2013
Publication Date
February 10, 2005
Publication Information
Publication: Workshop on Radar Investigations of Planetary and Terrestrial Environments
Subject Category
Lunar And Planetary Science And Exploration
Distribution Limits
Public
Copyright
Public Use Permitted.
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