Planetary geodesy

Bills, B. G.; Synnott, S. P.

doi:10.1029/rg025i005p00833

Cited by 10 publications

(4 citation statements)

References 81 publications

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“…In order to compare with other researcher's results, using the six-layer lunar model constructed by Bills and Ferrari (1977) (simplified as BF-6) we completed also the same computation. For the model BF-6 the algorithm used in the determination of the values of p(r), Vp(r) and Vs(r) is based on a cubic spline.…”

Section: The Calculated Results Of the Love Numbersmentioning

confidence: 99%

“…Due to recent achievements in planetary geodesy, at present important geodetic parameters of these planets are provided with high accuracy (e.g., Bills and Synnott, 1987). The geodetic parameters of the terrestrial planets and the Moon adopted in this study can be found in Table II.…”

Section: The Parametric Models Of the Internal Structure For The Moonmentioning

confidence: 99%

“…Bills and Ferrari (1977) constructed the lunar interior model and gave the profiles of the density, p(r), and seismic velocities, Vp(r) and Vs(r), for this model. Siegfried II andSolomon (1974), Zharkov (1983), and Johnston and Toks6z (1977) discussed the task involves the construction of internal structure models for Mercury, Venus, and Mars, respectively.…”

Section: The Parametric Models Of the Internal Structure For The Moonmentioning

confidence: 99%

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Love numbers of the moon and of the terrestrial planets

Zhang

1992

Earth Moon Planet

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In the IERS Standards (1989), for the Moon the adopted value of the tide Love number, k2, is equal to 0.0222. In this paper using the latest geodetic parameters of the Moon a group of internal structure models are constructed for this celestial body (see Table V), then the dependence of the Moon's core size on calculated value of k2 is explored. The obtained results indicate that the second degree Love number, k2 = 0.02664, of the lunar model 91-04 is near its observed value (0.027 -+ 0.006). This implies that the Moon may possess an outer core of 660 km radius and of 300 kbar mean rigidity. With the same method the static Love numbers from degree 2 to 30 are computed for the terrestrial planets -Mercury, Venus, and Mars (see Table VII), and the influence of some parameters (such as the rigidity) of the outer core on low degree Love numbers is discussed. Finally, the likely range of the second degree Love numbers is determined for the terrestrial planets (see Table XI). It seems that if low degree Love numbers of a terrestrial planet can be detected in the future space explorations, there is some possibility to improve the planetary internal structure model. For example, as soon as space techniques yield an observed value of k2 > 0.10 for Mercury, there will be reason to anticipate that a partly melted iron core exists in this planet.

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Section: The Calculated Results Of the Love Numbersmentioning

confidence: 99%

Section: The Parametric Models Of the Internal Structure For The Moonmentioning

confidence: 99%

Section: The Parametric Models Of the Internal Structure For The Moonmentioning

confidence: 99%

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Love numbers of the moon and of the terrestrial planets

Zhang

1992

Earth Moon Planet

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“…I note at the outset that the determination of such cartographically significant but essentially astronomical values as the rotation period and axis orientation, and the definition of cardinal directions and prime meridians, are outside the scope of this paper. The procedures are fully documented in the astronomical literature (e.g., Davies et al 1986Davies et al , 1994; a useful review is given by Bills and Synnott 1987).…”

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confidence: 99%

Mapping Worlds With Irregular Shapes

Stooke

1998

Canadian Geographies / Géographies canadiennes

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Near‐spherical worlds may be mapped using conventional techniques, but many solar system objects with diameters less than 500 km have very irregular shapes and pose special problems for cartographers. I describe the history and current status of exploration and mapping of these bodies with emphasis on cartographic problems, their solutions, and unusual cases requiring novel approaches to mapping. These include binary and multi‐lobed objects, and faceted shapes for which near‐global maps may be simultaneously equivalent and conformal. On peut faire des cartes de corps célestes qui ont une forme presque sphérique en utilisant des techniques conventionnelles, mais la plupart des petits corps célestes (diamètre de moins de 500 km) sont loin d'être sphériques et présentent des problèmes particuliers pour les cartographes. Je discute de l'histoire et de l'état actuel de l'exploration et de la cartographie de ces corps célestes ‐ et j'examine de près les problèmes cartographiques, leurs solutions, et des cas particuliers qui doivent être examinés d'un nouveau point de vue. Ceux‐ci incluent les objets avec deux lobes ou plus ainsi que les formes à facettes, dont les cartes peuvent être équivalentes et conformes en même temps.

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