%0 Journal Article %1 CARR1995 %A CARR, M. H. %A BELTON, M. J. S. %A BENDER, K. %A BRENEMAN, H. %A Greeley, R. %A HEAD, J. W. %A KLAASEN, K. P. %A MCEWEN, A. S. %A MOORE, J. M. %A MURCHIE, S. %A PAPPALARDO, R. T. %A PLUTCHAK, J. %A SULLIVAN, R. %A THORNHILL, G. %A VEVERKA, J. %D 1995 %J Journal of Geophysical Research-Planets %K imported %N E9 %P 18935--18955 %T THE GALILEO IMAGING TEAM PLAN FOR OBSERVING THE SATELLITES OF JUPITER %V 100 %X The Galileo spacecraft carries a 1500-nm focal length camera with a 800 X 800 CCD detector that will provide images with a spatial resolution of 10 mu rad/pixel. The spacecraft will fly by Io at the time of Jupiter Orbit Insertion (JOI) and, subsequently, while in Jupiter's orbit, will have a total of 10 close passes by Europa, Ganymede, and Callisto. These dose passes, together with more distant encounters, will be used by the imaging experiment primarily to obtain high-resolution coverage of selected targets, to fill gaps left in the Voyager coverage, to extend global color coverage of each satellite, and to follow changes in the volcanic activity of Io. The roughly 390 Mbit allocated for imaging during the tour will be distributed among several hundred frames compressed by factors that range from 1 to possibly as high as 50. After obtaining high-resolution samples during the initial Io encounter at JOI, roughly 10% of imaging resources are devoted to near-terminator mapping of Io's topography at 2- to 10-km resolution, monitoring color and albedo changes of the Ionian surface, and monitoring plume activity. Observations of Europa range in resolution from several kilometers per pixel to 10 m/pixel. The objectives of Europa are (1) to determine the nature, origin, and age of the tectonic features, (2) to determine the nature, rates, and sequence of resurfacing events, (3) to assess the satellite's cratering history, and (4) to map variations in spectral and photometric properties. Europa was poorly imaged by Voyager, so the plan includes a mix of high- and low-resolution sequences to provide context. The imaging objectives at Ganymede are (1) to characterize any volcanism, (2) to determine the nature and timing of any tectonic activity, (3) to determine the history of formation and degradation of impact craters, and (4) to determine the nature of the surface materials. Because Ganymede was well imaged by Voyager, most of the resources at Ganymede are devoted to high-resolution observations. The Callisto observations will be directed mostly toward (1) filling Voyager gaps, (2) acquiring high-resolution samples of typical cratered terrain and components of the Valhalla and Asgaard basins, (3) acquiring global color, and (4) determining the photometric properties of the surface. A small number of frames will be used to better characterize the small inner satellites of Jupiter, Thebe, Amalthea, Metis, and Adrastea.

@article{CARR1995, abstract = {The Galileo spacecraft carries a 1500-nm focal length camera with a 800 X 800 CCD detector that will provide images with a spatial resolution of 10 mu rad/pixel. The spacecraft will fly by Io at the time of Jupiter Orbit Insertion (JOI) and, subsequently, while in Jupiter's orbit, will have a total of 10 close passes by Europa, Ganymede, and Callisto. These dose passes, together with more distant encounters, will be used by the imaging experiment primarily to obtain high-resolution coverage of selected targets, to fill gaps left in the Voyager coverage, to extend global color coverage of each satellite, and to follow changes in the volcanic activity of Io. The roughly 390 Mbit allocated for imaging during the tour will be distributed among several hundred frames compressed by factors that range from 1 to possibly as high as 50. After obtaining high-resolution samples during the initial Io encounter at JOI, roughly 10% of imaging resources are devoted to near-terminator mapping of Io's topography at 2- to 10-km resolution, monitoring color and albedo changes of the Ionian surface, and monitoring plume activity. Observations of Europa range in resolution from several kilometers per pixel to 10 m/pixel. The objectives of Europa are (1) to determine the nature, origin, and age of the tectonic features, (2) to determine the nature, rates, and sequence of resurfacing events, (3) to assess the satellite's cratering history, and (4) to map variations in spectral and photometric properties. Europa was poorly imaged by Voyager, so the plan includes a mix of high- and low-resolution sequences to provide context. The imaging objectives at Ganymede are (1) to characterize any volcanism, (2) to determine the nature and timing of any tectonic activity, (3) to determine the history of formation and degradation of impact craters, and (4) to determine the nature of the surface materials. Because Ganymede was well imaged by Voyager, most of the resources at Ganymede are devoted to high-resolution observations. The Callisto observations will be directed mostly toward (1) filling Voyager gaps, (2) acquiring high-resolution samples of typical cratered terrain and components of the Valhalla and Asgaard basins, (3) acquiring global color, and (4) determining the photometric properties of the surface. A small number of frames will be used to better characterize the small inner satellites of Jupiter, Thebe, Amalthea, Metis, and Adrastea.}, added-at = {2009-11-03T20:21:25.000+0100}, author = {CARR, M. H. and BELTON, M. J. S. and BENDER, K. and BRENEMAN, H. and Greeley, R. and HEAD, J. W. and KLAASEN, K. P. and MCEWEN, A. S. and MOORE, J. M. and MURCHIE, S. and PAPPALARDO, R. T. and PLUTCHAK, J. and SULLIVAN, R. and THORNHILL, G. and VEVERKA, J.}, biburl = {https://www.bibsonomy.org/bibtex/2c942461e405f38a4bc8c809c33908f0b/svance}, citedreferences = {BELTON MJS, 1992, SPACE SCI REV, V60, P413 ; BENDER KC, 1995, IN PRESS US GEOL SUR ; BIANCHI R, 1986, Icarus, V67, P237 ; BINZEL RP, 1992, Icarus, V99, P238 ; BURATTI B, 1988, Icarus, V75, P437 ; BURATTI BJ, 1991, Icarus, V92, P312 ; BURNS JA, 1984, PLANETARY RINGS, P200 ; CHAPMAN CR, 1986, SATELLITES, P492 ; CRAWFORD GD, 1988, Icarus, V73, P66 ; CROFT SK, 1983, J GEOPHYS RES S, V88, B71 ; DEVINE N, 1983, J GEOPHYS RES, V88, P6889 ; DOMINGUE DL, 1991, Icarus, V90, P30 ; FINK U, 1992, Icarus, V97, P145 ; FINNERTY AA, 1981, Nature, V289, P24 ; GASKELL RW, 1988, GEOPHYS RES LETT, V15, P581 ; GOLOMBEK MP, 1990, Icarus, V83, P441 ; GRADIE J, 1980, Icarus, V44, P373 ; Greeley R, 1982, SATELLITES JUPITER, P340 ; HARTMANN WK, 1980, Icarus, V44, P441 ; HELFENSTEIN P, 1985, Icarus, V61, P175 ; HELFENSTEIN P, 1986, THESIS BROWN U PROVI ; HOREDT GP, 1984, Icarus, V60, P710 ; KLAASEN KP, 1984, OPT ENG, V23, P334 ; LUCCHITTA BK, 1980, Icarus, V44, P481 ; LUCCHITTA BK, 1982, SATELLITES JUPITER, P521 ; MALIN MC, 1986, SATELLITES, P689 ; MATSON DL, 1993, LUNAR PLANET SCI, V24, P939 ; MCCAULEY JF, 1978, Nature, V280, P736 ; MCEWEN AS, 1986, J GEOPHYS RES-SOLID, V91, P8077 ; MCEWEN AS, 1986, Nature, V321, P49 ; MCEWEN AS, 1989, NASA SP, V494, P11 ; MCKINNON WB, 1986, SATELLITES, P718 ; MELOSH HJ, 1993, Nature, V365, P735 ; MOORE JM, 1988, GEOPHYS RES LETT, V15, P225 ; MOORE JM, 1993, B AM ASTRON SOC, V25, P112 ; MUELLER BEA, 1992, Icarus, V97, P150 ; MURCHIE SL, 1986, J GEOPHYS RES, V91, E222 ; MURCHIE SL, 1988, J GEOPHYS RES, V93, P8795 ; MURCHIE SL, 1989, Icarus, V81, P271 ; MURCHIE SL, 1990, J GEOPHYS RES-SOLID, V95, P10743 ; Ojakangas GW, 1989, Icarus, V81, P220 ; PAPPALARDO ET, 1995, LUNAR PLANET SCI C, V26, P1097 ; PAPPALARDO RT, 1995, J GEOPHYS RES-PLANET, V100, P18985 ; PASCU D, 1992, Icarus, V98, P38 ; PASSEY QR, 1982, SATELLITES JUPITER, P379 ; PASSEY QR, 1983, Icarus, V53, P105 ; PIERI DC, 1981, Nature, V289, P17 ; PURVES NG, 1980, Icarus, V43, P51 ; REMSBERG A, 1981, LUNAR PLANET SCI, V12, P874 ; SCHENK P, 1992, EOS T AGU S, V73, P179 ; SCHENK PM, 1989, Icarus, V79, P75 ; SCHENK PM, 1991, Icarus, V89, P318 ; SCHENK PM, 1991, J GEOPHYS RES-PLANET, V96, P15635 ; SCHENK PM, 1993, J GEOPHYS RES-PLANET, V98, P7475 ; SCHENK PM, 1995, J GEOPHYS RES-PLANET, V100, P19009 ; SHAYA EJ, 1984, Icarus, V58, P74 ; SHOEMAKER EM, 1982, SATELLITES JUPITER, P277 ; SHOWALTER MR, 1987, Icarus, V69, P458 ; SMITH BA, 1979, Science, V204, P951 ; SMITH BA, 1979, Science, V206, P927 ; SPENCER JR, 1984, GEOPHYS RES LETT, V11, P1223 ; SPENCER JR, 1987, Icarus, V70, P99 ; SPENCER JR, 1990, Nature, V348, P618 ; Squyres SW, 1983, Nature, V301, P225 ; STOOKE PJ, 1989, LUNAR PLANET SCI C, V20, P1072 ; STROM RG, 1981, J GEOPHYS RES, V86, P8659 ; THOMAS PJ, 1986, J GEOPHYS RES S, V81, D453 ; THOMAS PJ, 1990, J GEOPHYS RES-SOLID, V95, P19161 ; VEVERKA J, 1981, J GEOPHYS RES, V86, P8675 ; WORONOW A, 1981, GEOPHYS RES LETT, V8, P891}, interhash = {962a6ce9f363de357e34f98e2b79fdbc}, intrahash = {c942461e405f38a4bc8c809c33908f0b}, journal = {Journal of Geophysical Research-Planets}, keywords = {imported}, number = {E9}, owner = {svance}, pages = {18935--18955}, timestamp = {2009-11-03T20:21:42.000+0100}, title = {THE GALILEO IMAGING TEAM PLAN FOR OBSERVING THE SATELLITES OF JUPITER}, volume = 100, year = 1995 }