Solar System DynamicsCambridge University Press, 13/02/2000 The Solar System is a complex and fascinating dynamical system. This is the first textbook to describe comprehensively the dynamical features of the Solar System and to provide students with all the mathematical tools and physical models they need to understand how it works. It is a benchmark publication in the field of planetary dynamics and destined to become a classic. Clearly written and well illustrated, Solar System Dynamics shows how a basic knowledge of the two- and three-body problems and perturbation theory can be combined to understand features as diverse as the tidal heating of Jupiter's moon Io, the origin of the Kirkwood gaps in the asteroid belt, and the radial structure of Saturn's rings. Problems at the end of each chapter and a free Internet Mathematica® software package are provided. Solar System Dynamics provides an authoritative textbook for courses on planetary dynamics and celestial mechanics. It also equips students with the mathematical tools to tackle broader courses on dynamics, dynamical systems, applications of chaos theory and non-linear dynamics. |
من داخل الكتاب
النتائج 1-5 من 77
الصفحة viii
... Potential Theory Tidal Deformation Rotational Deformation Contents The Darwin - Radau Relation Shapes and Internal Structures of Satellites The Roche Zone Tidal Torques Satellite Tides Spin - Orbit Coupling Introduction Tidal Despinning ...
... Potential Theory Tidal Deformation Rotational Deformation Contents The Darwin - Radau Relation Shapes and Internal Structures of Satellites The Roche Zone Tidal Torques Satellite Tides Spin - Orbit Coupling Introduction Tidal Despinning ...
الصفحة 18
... potential experienced by one orbiting body due to another involves 79 separate cosine arguments and 144 terms ( see Appendix B ) . Consequently the availability of computer algebra systems has greatly enhanced the speed and reliability ...
... potential experienced by one orbiting body due to another involves 79 separate cosine arguments and 144 terms ( see Appendix B ) . Consequently the availability of computer algebra systems has greatly enhanced the speed and reliability ...
الصفحة 38
... potential experienced by one planet or satellite due to another . In that case the expansion is in terms of the eccentricity and inclination of the bodies involved . Throughout this book we make use of a number of expansions . Typically ...
... potential experienced by one planet or satellite due to another . In that case the expansion is in terms of the eccentricity and inclination of the bodies involved . Throughout this book we make use of a number of expansions . Typically ...
الصفحة 47
... , barycentric coordinate system ) and the potential energy . We have ( 2.110 ) ( 2.111 ) m1m2 12 [ R2 + ( R2ƒ ) 2 ] − 911m2 . ( 2.115 ) ( 2.113 ) ( 2.116 ) where C is the energy constant from Eq . ( 2.7 Barycentric Orbits 47.
... , barycentric coordinate system ) and the potential energy . We have ( 2.110 ) ( 2.111 ) m1m2 12 [ R2 + ( R2ƒ ) 2 ] − 911m2 . ( 2.115 ) ( 2.113 ) ( 2.116 ) where C is the energy constant from Eq . ( 2.7 Barycentric Orbits 47.
الصفحة 58
لقد وصلت إلى حد العرض المسموح لهذا الكتاب.
لقد وصلت إلى حد العرض المسموح لهذا الكتاب.
المحتوى
LXVIII | 261 |
LXIX | 264 |
LXX | 270 |
LXXI | 274 |
LXXII | 279 |
LXXIII | 283 |
LXXIV | 289 |
LXXV | 293 |
19 | |
22 | |
23 | |
25 | |
32 | |
37 | |
42 | |
45 | |
48 | |
XIX | 54 |
XX | 57 |
XXI | 60 |
XXII | 63 |
XXIII | 64 |
XXIV | 68 |
XXV | 71 |
XXVI | 74 |
XXVII | 77 |
XXVIII | 83 |
XXIX | 95 |
XXX | 97 |
XXXI | 102 |
XXXII | 107 |
XXXIII | 110 |
XXXIV | 115 |
XXXV | 121 |
XXXVI | 128 |
XXXVII | 130 |
XXXVIII | 131 |
XXXIX | 136 |
XL | 140 |
XLI | 149 |
XLII | 153 |
XLIII | 155 |
XLIV | 158 |
XLV | 160 |
XLVI | 166 |
XLVII | 174 |
XLVIII | 175 |
XLIX | 178 |
L | 183 |
LI | 186 |
LII | 189 |
LIII | 194 |
LIV | 200 |
LV | 210 |
LVI | 215 |
LVII | 217 |
LVIII | 222 |
LIX | 225 |
LX | 226 |
LXI | 228 |
LXII | 233 |
LXIII | 238 |
LXIV | 246 |
LXV | 248 |
LXVI | 251 |
LXVII | 253 |
LXXVI | 299 |
LXXVII | 302 |
LXXVIII | 307 |
LXXIX | 309 |
LXXX | 314 |
LXXXI | 317 |
LXXXII | 318 |
LXXXIII | 321 |
LXXXIV | 326 |
LXXXV | 328 |
LXXXVI | 332 |
LXXXVII | 334 |
LXXXVIII | 337 |
LXXXIX | 341 |
XC | 364 |
XCI | 371 |
XCII | 373 |
XCIII | 375 |
XCIV | 385 |
XCV | 387 |
XCVI | 390 |
XCVII | 394 |
XCVIII | 396 |
XCIX | 399 |
C | 402 |
CI | 405 |
CII | 406 |
CIII | 409 |
CIV | 410 |
CV | 413 |
CVI | 421 |
CVII | 428 |
CVIII | 448 |
CIX | 452 |
CX | 456 |
CXI | 466 |
CXII | 469 |
CXIII | 471 |
CXIV | 474 |
CXVII | 475 |
CXVIII | 481 |
CXIX | 492 |
CXX | 495 |
CXXI | 512 |
CXXII | 515 |
CXXIII | 518 |
CXXIV | 520 |
CXXV | 522 |
CXXVI | 524 |
CXXVII | 526 |
CXXVIII | 527 |
CXXIX | 529 |
CXXX | 530 |
CXXXI | 535 |
CXXXII | 539 |
CXXXIII | 557 |
CXXXIV | 577 |
طبعات أخرى - عرض جميع المقتطفات
عبارات ومصطلحات مألوفة
amplitude angle angular approach approximate argument associated assume asteroid body calculate centre chaotic circle circular close consider constant corresponding curves defined denote derived determined direction distance disturbing function dynamics Earth eccentricity effect encounter energy equal equations equilibrium points evolution example expansion expression follows force frame function given gives gravitational Hamiltonian Hence inclination increase initial inner integration Jupiter libration longitude mass mean motion moving Note numerical objects observed obtain occur orbit origin outer particle path pericentre period perturbations planet planetary plot position possible potential problem quantities radial radius reference relation resonance respectively ring rotating satellite Saturn Sect secular semi-major axis shown in Fig solar system solution stable surface Table theory tidal tide trajectory values variation vector write