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Kepler conjecture
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The Kepler conjecture, named after the 17th-century mathematician and astronomer Johannes Kepler, is a mathematical theorem about sphere packing in three-dimensionalUltrarelativistic limit (522 words) [view diff] exact match in snippet view article find links to article
massless particles such as the photon from those of massive particles (cf. Kepler problem in general relativity). [citation needed] Below are few ultrarelativisticN. V. V. J. Swamy (1,120 words) [view diff] exact match in snippet view article find links to article
Bidenharn and Swamy published very influential papers on the relativistic Kepler problem. They introduced a symmetric Hamiltonian and solved the Dirac EquationBSSN formalism (209 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonEccentricity vector (265 words) [view diff] case mismatch in snippet view article find links to article
parameter Kepler orbit Orbit Eccentricity Laplace–Runge–Lenz vector Cordani, Bruno (2003). The Kepler Problem. Birkhaeuser. p. 22. ISBN 3-7643-6902-7.Kasner metric (769 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonWeyl–Lewis–Papapetrou coordinates (651 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonManifest covariance (381 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonPseudo-Riemannian manifold (1,174 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonRegge calculus (708 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonMilne model (746 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonTaub–NUT space (494 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonEvent (relativity) (406 words) [view diff] exact match in snippet view article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonCoordinate time (1,514 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonBirkhoff's theorem (relativity) (652 words) [view diff] exact match in snippet view article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonMathisson–Papapetrou–Dixon equations (1,266 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonAbsolute horizon (528 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonHodograph (789 words) [view diff] exact match in snippet view article find links to article
problems. Laplace–Runge–Lenz vector, for an example in solving the Kepler problem "AMS Glossary of Meteorology : Hodograph". Archived from the originalEinstein tensor (1,682 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGeneral Relativity (book) (1,124 words) [view diff] exact match in snippet view article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonRelativistic chaos (240 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonJohn Milnor (2,075 words) [view diff] exact match in snippet view article find links to article
2307/2317182. JSTOR 2317182. Milnor, John (1983). "On the geometry of the Kepler problem". Amer. Math. Monthly. 90 (6): 353–365. doi:10.2307/2975570. JSTOR 2975570List of contributors to general relativity (1,819 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonStellar dynamics (17,631 words) [view diff] no match in snippet view article find links to article
Stellar dynamics is the branch of astrophysics which describes in a statistical way the collective motions of stars subject to their mutual gravity. TheDavid J. Simms (503 words) [view diff] exact match in snippet view article find links to article
professional papers. Geometric quantization of energy levels in the Kepler problem, D.J. Simms - Symposia Mathematica, 1974 David Simms was a member ofLovelock's theorem (397 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGeodetic effect (1,468 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGravitational time dilation (2,402 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonTheory of relativity (2,953 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonLinearized gravity (2,008 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonVan Stockum dust (2,067 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonWhite hole (3,441 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGravitomagnetic time delay (315 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonLemaître coordinates (1,195 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonEinstein–Rosen metric (356 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonDust solution (812 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonShapiro time delay (1,716 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonADM formalism (2,392 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonInterior Schwarzschild metric (1,931 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGravitational singularity (2,887 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonHamilton–Jacobi–Einstein equation (1,960 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonNo-hair theorem (1,482 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonFrom Here to Infinity (book) (367 words) [view diff] case mismatch in snippet view article
include Tarski's circle-squaring problem, Carmichael numbers, and the Kepler Problem. 1st edition (1987): published under the title The Problems of Mathematics1642 (3,170 words) [view diff] exact match in snippet view article find links to article
ISBN 9780385142786. Brackenridge, J (1995). The key to Newton's dynamics: the Kepler problem and the Principia: containing an English translation of sections 1,Lemaître–Tolman metric (1,801 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonHartle–Thorne metric (593 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonAsım Orhan Barut (738 words) [view diff] case mismatch in snippet view article find links to article
the Dirac Electron 1984 Complex-Energy Solutions of the Relativistic Kepler Problem at High Energies 1984 Path-Integral Derivation of the Dirac PropagatorAreal velocity (1,265 words) [view diff] case mismatch in snippet view article find links to article
2735630. Brackenridge, J. B. (1995). The Key to Newton's Dynamics: The Kepler Problem and the Principia. Berkeley: University of California Press. ISBN 978-0-520-20217-7Event horizon (3,590 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGravitomagnetic clock effect (836 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonRiemann curvature tensor (2,934 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonRoger A. Broucke (622 words) [view diff] exact match in snippet view article find links to article
methods for handling Poisson series. Later, he studied the anisotropic Kepler problem, a mathematical model of the motion of an electron trapped in a potentialPenrose–Hawking singularity theorems (3,124 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonPp-wave spacetime (3,411 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonEinstein–Infeld–Hoffmann equations (737 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonWorld line (3,525 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonLense–Thirring precession (2,856 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonCharles-Michel Marle (1,136 words) [view diff] exact match in snippet view article find links to article
property of conformally Hamiltonian vector fields; Application to the Kepler problem". Journal of Geometric Mechanics. 4 (2): 181–206. arXiv:1011.5731. doi:10Exact solutions in general relativity (3,329 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonStress–energy tensor (4,040 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonEinstein–Hilbert action (2,645 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonFluid solution (2,174 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonTime dilation (6,730 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonWormhole (6,941 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonReissner–Nordström metric (3,497 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonQuantum chaos (4,340 words) [view diff] exact match in snippet view article find links to article
integration. Gutzwiller applied the trace formula to approach the anisotropic Kepler problem (a single particle in a 1 / r {\displaystyle 1/r} potential with anTensor density (3,727 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonOld quantum theory (4,834 words) [view diff] exact match in snippet view article find links to article
value of the total angular momentum L, the Hamiltonian for a classical Kepler problem is (the unit of mass and unit of energy redefined to absorb two constants):Hawking radiation (5,968 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonParameterized post-Newtonian formalism (3,338 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGravity (8,799 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonFrame-dragging (4,363 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonPetrov classification (2,699 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGödel metric (3,872 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGravitational lens (5,712 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonTolman–Oppenheimer–Volkoff equation (2,080 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGoldberg–Sachs theorem (1,251 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonFriedmann equations (4,441 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonEquivalence principle (5,570 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonSchwarzschild metric (5,197 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonHistory of general relativity (4,514 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonIntroduction to the mathematics of general relativity (3,180 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonKerr–Newman metric (4,780 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonRedshift (9,212 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonIsaac Newton (18,227 words) [view diff] case mismatch in snippet view article find links to article
Press, (1999) Brackenridge, J. Bruce. The Key to Newton's Dynamics: The Kepler Problem and the Principia: Containing an English Translation of Sections 1,Centripetal force (8,049 words) [view diff] case mismatch in snippet view article find links to article
Brackenridge, John Bruce (1996). The Key to Newton's Dynamics: The Kepler Problem and the Principia. University of California Press. p. 74. ISBN 978-0-520-91685-2Black hole (18,807 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonKerr metric (6,963 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGeodesics in general relativity (6,157 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGravitational redshift (6,013 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonMass in general relativity (3,216 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonSpeed of gravity (5,588 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonMathematics of general relativity (7,044 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonHistory of centrifugal and centripetal forces (2,982 words) [view diff] case mismatch in snippet view article find links to article
Brackenridge, John Bruce (1996). The Key to Newton's Dynamics: The Kepler Problem and the Principia. University of California Press. p. 74. ISBN 978-0-520-91685-2Twin paradox (7,917 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonIntroduction to general relativity (9,148 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGravitational wave (12,709 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonGeneral relativity (22,694 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonCarter constant (2,666 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonPhilosophiæ Naturalis Principia Mathematica (12,094 words) [view diff] exact match in snippet view article find links to article
[2]. See J. Bruce Brackenridge, "The key to Newton's dynamics: the Kepler problem and the Principia", (University of California Press, 1995), especiallyPositive energy theorem (3,567 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonJohndale Solem (3,228 words) [view diff] exact match in snippet view article find links to article
LAUR-96-3067. doi:10.2172/369704. Solem, J. C. (1997a). "Variations on the Kepler problem". Foundations of Physics. 27 (9): 1291–1306. Bibcode:1997FoPh...27.1291STests of general relativity (12,427 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonSimon Caron-Huot (1,208 words) [view diff] exact match in snippet view article find links to article
due to hidden conformal symmetries, similar to the quantum mechanical Kepler problem (with the Laplace-Runge-Lenz vector as a conserved quantity). In 2017Newman–Penrose formalism (6,548 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonNewtonian motivations for general relativity (2,945 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonVaidya metric (3,476 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonTheoretical motivation for general relativity (4,537 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonTimeline of gravitational physics and relativity (15,097 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonOppenheimer–Snyder model (1,567 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizon1640s (23,612 words) [view diff] exact match in snippet view article find links to article
ISBN 9780385142786. Brackenridge, J (1995). The key to Newton's dynamics: the Kepler problem and the Principia: containing an English translation of sections 1,Clebsch–Gordan coefficients for SU(3) (7,751 words) [view diff] exact match in snippet view article
tensor operator analogous to the Laplace–Runge–Lenz vector for the Kepler problem may be defined, A ^ i j = 1 2 p i p j + ω 2 r i r j {\displaystyle {\hatTrigonometric Rosen–Morse potential (4,805 words) [view diff] exact match in snippet view article find links to article
JSTOR 20488434. Barut, A. O.; Wilson, R. (1985). "On the dynamical group of the Kepler problem in a curved space of constant curvature". Phys. Lett. A. 110 (7–8):Newton–Hooke priority controversy for the inverse square law (2,613 words) [view diff] exact match in snippet view article find links to article
JSTOR 531520. See J. Bruce Brackenridge, "The key to Newton's dynamics: the Kepler problem and the Principia", (University of California Press, 1995), especiallyKerr–Newman–de–Sitter metric (3,079 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizonIsaac Newton's apple tree (4,294 words) [view diff] case mismatch in snippet view article find links to article
Brackenridge, J. Bruce (29 February 1996). The Key to Newton's Dynamics: The Kepler Problem and the Principia. University of California Press. ISBN 978-0-520-91685-2Einstein field equations (5,077 words) [view diff] exact match in snippet view article find links to article
Kepler problem Gravitational lensing Gravitational redshift Gravitational time dilation Gravitational waves Frame-dragging Geodetic effect Event horizon