1. Solar System Astrometry Carlos E. Lopez Universidad Nac. de San Juan, Argentina, and Yale Southern Observatory

2. Measuring the Positions of: Asteroids Comets Natural Satellites Space Debris Occultations

3. Ptolomy’s Solar System

4. Copernicus’s scheme of the Solar System

5. The Solar System Before 1801 (and after the Copenican theory had been accepted) Ceres The Solar System on Jan 1st, 1801

6. The Solar System as of Jun 8, 2005 around 150,000 objects

7. The Kuiper belt is thought to be the source of short-period comets and of centaurs. It is named after Gerard Kuiper who predicted its existence in 1951 but is also sometimes referred to as the Edgeworth-Kuiper belt, in recognition of the amateur astronomer Kenneth Edgeworth (1880-1972) who, in his only scientific paper, published in the Journal of the British Astronomical Association in 1942, was the first to suggest the existence of a region of comet-like objects beyond the outer planets. The first observational support for it came in 1992 when David Jewitt of the University of Hawaii and Jane Luu of the University of California, Berkeley discovered a 200-kilometer-wide object circling the Sun beyond the orbit of Pluto. An Outer Belt?

8. Orbit of 1996 TL66

9. The Outer Solar System by the End of 1999

10. As of Jul 12, 890 objects have been identified. It is assumed there must be on the order of 70,000 such objects. As of Jul 12, 890 objects have been identified. It is assumed there must be on the order of 70,000 such objects. The first TNO ever discovered was 1992 QB1. The first TNO ever discovered was 1992 QB1. The last one to be discovered was 2005 JR179. The last one to be discovered was 2005 JR179. How many TNOs have been identified so far?

12. 1801 1199916794 1802 1200025330 1804 1200113296 1807 12002 5597 1845 12003 1055 184732004 260 Discovery rate

13. The name of an Asteroid could be: Temporary Provisional Permanent

14. Provisional Designations

15. Provisional Designations (cont.)  If there are more than 25 discoveries in any one half-month period, the second letter is recycled and a numeral `1' is added to the end of the designation. If more than 50 discoveries, the second-letter is again recycled, with a numeral ‘2' appended after the second letter. Discoveries 76-100 have numeral ‘3' added, numbers 101-125 numeral `4', etc. When possible, these additional numbers should be indicated using subscript characters.  Thus the order of assignment of designations in a particular half-month period is as follows: 1995 SA, 1995 SB,..., 1995 SY, 1995 SZ, 1995 SA1,..., 1995 SZ1, 1995 SA2,..., 1995 SZ9, 1995 SA10, etc.

16. J95X00A = 1995 XA J95X01L = 1995 XL1 J95F13B = 1995 FB13 J98SA8Q = 1998 SQ108 J98SC7V = 1998 SV127 J98SG2S = 1998 SS162 K99AJ3Z = 2099 AZ193 The provisional designations stored on the orbit and observations is stored in a 7-character packed format

17. 2005 OH = 5O5604D(July 20.49 UT) 2005 OE = 5O3EC49(July 19.47 UT) 2005 OB = 77G001 (July 18.37 UT) 5NA1C16 does not exist (July 17.93 UT) P03DDA does not exist (July 17.49 UT) 2005 NP82 = 5N5545E(July 17.49 UT) 2005 NW80 = SW40Pz (July 16.66 UT) 2005 NV80 = UHAZ01 (July 16.66 UT) From temporary to provisional designations

18. Asteroids: Areas for Study Shape and Structure Composition Mass Surface Structure Moons Magnetometry

19. Classification of Asteroids The classification can be made from two very different points of view: Location within the Solar System Physical characteristics

20. Physical Characteristics (main classes only) C class: they have a dark appearance, implying a composition of rocky material mixed with dark carbon compounds. This class is thought to consist of primitive matter. S class: this is a rather small group –compared with the C ones. They are more reflective and show a preponderance of silicate rock. This is the S class, which stands for stony class. M class: this group consists of bodies with large amounts of metal, such as iron and nickel. Apparently these asteroids come from differentiated bodies that have fractured by collisions. V class: a small number of asteroids have basaltic surfaces. These basaltic asteroids evidently had great flows of lava. D class: a few asteroids having a dark surface. In fact the surface of many of these is dark red. Several of these asteroids, beyond the orbits of Saturn, are called Centaur asteroids.

21. Distribution of Inclinations

22. Kirkwood Gaps

23. Dsitribution of the Lagrangian Points

24. Mercury Venus Earth Mars The Inner Most Solar System Sun

26. Classification of NEAs

27. HDiameter H H Conversion Between Absolute Magnitude (H) and Diameter

28. "The potential catastrophe of an asteroid hitting Earth should no longer be ignored. We need to know what is out there. Accounts of asteroids passing close to Earth with almost no prior warning should be enough to get our attention. The first step is to assess the threat. Given the vast number of asteroids and comets that inhabit the Earth's neighborhood, greater efforts for tracking and monitoring these objects are critical. This bill would direct NASA to expand their current program to track and detect potential threats and would provide a funding authorization. Any threat that would wreak havoc on or world should be studied and prevented if possible. We have the technology, we need the direction - this bill provides that." Rep. Rohrabacher The Beginning

29. "All of these bills will improve our lives through increasing our understanding of the Earth, how it works and what may threaten it." Science Committee Chairman Sherwood Boehlert The Beginning (cont.)

30. Search Programs

32. The Discovery Channel Telescope

37. The only requirements for participation in the FMO project are 1) interest, 2) sharp eyes and 3) access to a computer during the hours that the Spacewatch mosaic system is in operation. If you are interested in participating, please refer to How to Find FMOs for more information.How to Find FMOs

42. The Ritcher’s Scale of Asteroid Impacts

43. Upcoming Ecounters

46. How Many NEAs are there? 286 Atens 1662 Apollos 1471 Amors

47. IAU Minor Planet Center

53. Results should be submitted in the MPC format: COD (observatory code) (YSO = 808) CON (followed by the contact details) OBS (followed by the list of observers) MEA (followed by the list of measurers) TEL (followed by details of the telescope) NET (followed by the abbreviated name(s) of the catalogue(s) used for the reductions). BND (followed by single character representing the mag band) COM (followed by a textual comment) NUM (followed by a count of the observations in this batch)

54. P Photographic (default if column is blank) E Encoder C CCD T Meridian or transit circle M Micrometer V/v "Roving Observer" observation R/r Radar observation S/s Satellite observation c Corrected-without-republication CCD observation Accepted Detectors

55. USNO SA2.0 USNO A2.0 Tycho 2 ACT UCAC 2 USNO B1.0 GSC 2.2 Reference Catalogues Recommended by the IAU Minor Planet Center

56. Image mining

57. SkyMorph: image mining facility for moving objects

61. Addition of the three previous singlets Asteroid 2002 NT7 detected by NEAT

62. The DSS Plate Finder

63. 1999 AN10 POSS Image obtained in 1955, 34 years before the official discovery of the asteroid!!!

64. A new asteroid? 1955 1953

65. Radar-Detected Asteroids 97 Main-Belt Asteroids 175 Near-Earth Asteroids

66. High-resolution Model of Asteroid 4179 Toutatis Radar Observations Hudson, R. et al., 2003, Icarus, 161, 346

67. Current Status

68. Coming Radar Observations

69. Radar Observations (cont.)

70. Major Planets and Satellites

71. Galileo’s notes on the discovery of the “Medicean planets”

72. On the 7th day of January in the present year, 1610, … I noticed a circumstance which I had never been able to notice before, namely that three little stars, small but very bright, were near the planet; and although I believed them to belong to a number of the fixed stars, yet they made me somewhat wonder, because they seemed to be arranged exactly in a straight line, parallel to the ecliptic… I therefore concluded, that there are three stars in the heavens moving about Jupiter, as Venus and Mercury around the Sun …

73. Orbits of Jupiter’s Known Satellites

75. Discovery Images of S/2000 J8 (taken with the University of Hawaii 88-inch telescope + 8-K CCD Camera)

76. Pascu, D. et al. 1987. AJ 93, 963-1007.

77. Veiga, C., and Vieira Martins. 1995, A&ASS, 111, 387-392 Contour Density of Uranus and … …Miranda

78. Veiga, C., and Vieira Martins. 1995, A&ASS, 111, 387-392

81. Observing Mars Satellites Colas, F., and Arlot, J. 1991, A&A, 252, 402

82. Space Debris

83. 1. In its resolution 51/123, paragraph 32, of 13 December 1996, the General Assembly considered it essential that Member States pay more attention to the problem of collisions of space objects, including nuclear power sources, with space debris, and other aspects of space debris, and called for the continuation of national research on that question, for the development of improved technology for the monitoring of space debris and for the compilation and dissemination of data on space debris. To the extent possible, the Assembly considered that information thereon should be provided to the Scientific and Technical Subcommittee of the Committee on the Peaceful Uses of Outer Space.

84. Low Earth Orbits (between the surface of the Earth and 2,000 km)

85. Geosynchronous Region (around 35,785 km altitude)

86. Since 1961, more than 170 man-made objects in Earth orbit have undergone moderate to serious breakups. Another 40 have undergone less energetic debris-producing events. Only three of these fragmentations are known to have been caused by deliberate or accidental collisions. The vast majority of fragmentations appear to have arisen from explosions involving residual propellants or pressurants, battery malfunctions, self-destruction charges, or space defense activities. Space Debris Facts

87. IAU Minor Planet Center

90. Stellar Occultations by Solar System Objects

91. The IOTA Home Page http://www.lunar-occultations.com/iota/iotandx.htm

92. The Occultation Path of 1300 Marcelle

93. Yale Southern Obs. The Occultation Path of 203 Pompeja

94. The Diameter of Juno from its Occultation of AG +0º 1022 The Observations are well represented by a mean elliptical limb profile having semimajor and semiminor axes of 145.2+0.8 and 122.8+1.9 km (Millis, R. et al. 1981, AJ 86, 306)

95. Light variations of SAO 158687 as it was being occulted by Uranu’s disk in 1977 The discovery of Uranu’s rings

96. Jul 03 - Asteroid 496 Gryphia Occults HIP 69127 (6.5 Magnitude Star)Asteroid 496 Gryphia Occults HIP 69127 Jul 07 - Jupiter Occults PPM 178840 (10.2 Magnitude Star)Jupiter Occults PPM 178840 Jul 13 - Moon Occults JupiterMoon Occults Jupiter Jul 14 - Asteroid 253 Mathilde Occults TYC 5684-00949-1 (11.3 Magnitude Star)Asteroid 253 Mathilde Occults TYC 5684-00949-1 Jul 15 - Asteroid 14 Irene Occults HIP 75118 (6.1 Magnitude Star)Asteroid 14 Irene Occults HIP 75118 Jul 22 - Asteroid 39 Laetitia At Opposition (9.6 Magnitude)Asteroid 39 LaetitiaAt Opposition Jul 23 - Asteroid 538 Friederike Occults HIP 88504 (7.5 Magnitude Star)Asteroid 538 Friederike Occults HIP 88504 Jul 29 - Asteroid 1233 Kobresia Occults HIP 18491 (7.5 Magnitude Star)Asteroid 1233 Kobresia Occults HIP 18491 Occultations Predicted for July 2005

97. Extrasolar Planetary Systems

98. The Martir Filippo (Giordano) Bruno (1548 – 1600)

99. Bruno affirmed that the universe was homogeneous, made up everywhere of the four elements (water, earth, fire, and air), rather than having the stars be composed of a separate quintessence. Essentially, the same physical laws would operate everywhere in the universe. Under Bruno’s model, the Sun was simply one more star, and the stars all suns, each with its own planets. Bruno saw a Solar System of a sun/star with planets as the fundamental unit of the universe. According to Bruno, infinite God necessarily created an infinite universe, formed of an infinite number of solar systems, separated by vast regions full of Aether, because empty space could not exist. (Bruno did not arrive at the concept of a galaxy.) Each comet is a world, a permanent celestial body, formed of the four elements. Bruno’s Thoughts

100. His observations led him to conclude in 1935 that the average separation between the components of binary stars was about 20 AU, which is similar to the distance of the gas giants from the Sun… Extrapolating from the fact that about 10% of binaries contained companion stars that were one-tenth or less as massive as the primaries, Kuiper suggested there might be 100 billion planetary systems in our Galaxy alone. Gerard Peter Kuiper (1905 – 1973)

101. Searching for Extrasolar Planets Two Basic Methods Direct Detections Indirect Detections

102. http://exoplanets.org/exoplanets_pub.html Spectroscopy: Doppler spectroscopy is used to detect the periodic velocity shift of the stellar spectrum caused by an orbiting giant planet. Transit Photometry: Photometry measures the periodic dimming of the star caused by a planet passing in front of the star along the line of sight from the observer. Astrometry: Astrometry is used to look for the periodic wobble that a planet induces in the position of its parent star.

103. The apparent orbit of the Sun around the center of mass of the Solar System from 1960 to 2025. The tic marks are in intervals of 0.2 mas. Astrometry

104. Spectroscopy

105. Apparent radial velocity of the Sun as it orbits the centrer of mass of the Solar System from 1960 to 2025 as viewed from the vernal equinox.

106. Title: Proposal for a project of high-precision stellar radial velocity work Author: Otto Struve Journal: The Observatory, Vol. 72, p. 199-200 (1952) Submission Date: 24 July 1952 Publication Date: October 1952

107. Transit Photometry

108. Transit of Venus, June 2004 Second contact June 8, 2004, 05:39:47.7 UT Lasne, Belgium Third contact June 8, 2004, 11:03:59.8 UT Lasne, Belgium

110. Planetary Transit in HD 209458 Artwork by Lynette Cook

111. Transit in HD 2049458: light variation

112. Some Results from the University of New South Wales Extrasolar Planets Search Hidas, M. et al. 2005. MNRAS, 360, 703.

113. The Future

115. Darwin will use a flotilla  of six space telescopes, each of which will be at least 1.5 metres in diameter. They will work together to scan the nearby Universe, looking for signs of life on Earth-like planets. At optical wavelengths, a star outshines an Earth-like planet by a billion to one. Partly to alleviate this difficulty, Darwin will observe in the mid-infrared. At these wavelengths, the star-planet contrast drops to a million to one, making detection somewhat more manageable. Another key reason for observing in the infrared is because life on Earth leaves its mark at these wavelengths. To see planets around nearby stars would require a telescope of roughly 30 metres in size and this is way beyond the current limits of technology. To overcome this limitation, Darwin will use six telescopes. Mission facts

117. OBSS is an astrometric satellite designed to determine with unprecedented accuracy the positions, distances, and motions of a billion stars within our galaxy. OBSS will be optimized for the detection of extrasolar giant planets of 10 Jupiter masses and less, orbiting all Sun-like stars within 300 light-years of the solar system with orbital periods of up to 10 years. OBSS will detect more than 80 percent of near asteroids with a radius greater than 140 meter. It will also detect hundreds of new Kuiper Belt and trans-Neptunian objects. OBSS will yield a comprehensive characterization of stars in a volume that will encompass half the Galaxy, including the solar neighborhood and the galactic nucleus. The OBSS's 1-metre optical telescope would orbit the Sun for five years. It would view each star about 400 times to pinpoint stellar positions to a precision of 100 microarcseconds - 10 times the accuracy of Hipparcos.

118. NASA finds conclusive evidence there once was water on Mars