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But why an elliptical orbit
In everything I've read about planets and elliptical orbits, I can't
ever recall any author (Feynman, Newton, 'Ask an Astronomer' etc.), explaining exactly 'why' the orbit is elliptical. Oh sure there's been lots of mathematics to explain the orbit and how it works, but most of the explanations don't provide a definitive statement as to why it IS elliptical. Until someone can do the 'why', I'm going to assume that either: 1. it's because the Sun is in a rotation of it's own and all the planets have to scoot to 'catch' up with it. But since the Sun is moving too, the now-receding planet's momentum carries it further away than it expected, so it maps out a stretched circle, longer than it thought was necessary. So it's stretching the distance on the long-arm of the orbit and has to scoot back in again, chasing that moving Sun. or 2. the minute gravitational tug of the planet pulls the Sun closer (out of its 'fixed' position relative to the planet) which increases the mutual gravitational attraction so that they are each attracted that little bit stronger. But since the Plant is still in orbit, it follows the short arm of the ellipse that little bit faster or a little more energised. It then maps out the long-arm of the ellipse and gravitational attraction recedes just a little bit, allowing it to 'stretch that circle'. or (this space left blank for the correct answer) Greg |
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On 11 Oct 2005 20:27:05 -0700, "tt40" wrote:
In everything I've read about planets and elliptical orbits, I can't ever recall any author (Feynman, Newton, 'Ask an Astronomer' etc.), explaining exactly 'why' the orbit is elliptical. Oh sure there's been lots of mathematics to explain the orbit and how it works, but most of the explanations don't provide a definitive statement as to why it IS elliptical. Until someone can do the 'why', I'm going to assume that either: 1. it's because the Sun is in a rotation of it's own and all the planets have to scoot to 'catch' up with it. But since the Sun is moving too, the now-receding planet's momentum carries it further away than it expected, so it maps out a stretched circle, longer than it thought was necessary. So it's stretching the distance on the long-arm of the orbit and has to scoot back in again, chasing that moving Sun. or 2. the minute gravitational tug of the planet pulls the Sun closer (out of its 'fixed' position relative to the planet) which increases the mutual gravitational attraction so that they are each attracted that little bit stronger. But since the Plant is still in orbit, it follows the short arm of the ellipse that little bit faster or a little more energised. It then maps out the long-arm of the ellipse and gravitational attraction recedes just a little bit, allowing it to 'stretch that circle'. The correct answer is found in the mathematics. Any attempt to explain it in English is a poor approximation at best (your first suggestion is entirely incorrect; you are sort of on the right track with the second). In a two body system, with the bodies acting under the force of gravity, an elliptical path is simply what happens. The math that describes that is really the answer. http://en.wikipedia.org/wiki/Kepler%27s_laws http://astron.berkeley.edu/~converse/Lagrange/Kepler'sFirstLaw.htm Maybe Brian Tung will chip in. He has a talent for putting the math into English. _________________________________________________ Chris L Peterson Cloudbait Observatory http://www.cloudbait.com |
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tt40 wrote:
It then maps out the long-arm of the ellipse and gravitational attraction recedes just a little bit, allowing it to 'stretch that circle'. Are you asking why it is an ellipse rather than a circle? If so, the answer is easy. You can create a perfectly circular orbit with only two bodies --- the sun and the planet. But when you introduce everything else, they will not stay perfectly circular. And, given the chaotic nature of the solar system's creation, it is too much to ask that it create perfectly circular orbits at the start. A circle and an ellipse are the only two possibilities that work. And to be "perfect" about it, they aren't even perfectly elliptical. There is always a little tugging and pulling by other bodies that alter the orbits from perfect. But apart from those tiny imperfections, they are ellipses. Hope this helps. Chuck Taylor ********************************************* Do you observe the moon? If so, try http://groups.yahoo.com/group/lunar-observing/ If you enjoy optics, try http://groups.yahoo.com/group/ATM_Optics_Software/ ********************************************* |
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tt40 wrote:
In everything I've read about planets and elliptical orbits, I can't ever recall any author (Feynman, Newton, 'Ask an Astronomer' etc.), explaining exactly 'why' the orbit is elliptical. Oh sure there's been lots of mathematics to explain the orbit and how it works, but most of the explanations don't provide a definitive statement as to why it IS elliptical. The answer lies in mathematics of Kepler, and especially Newton. Johannes Kepler -- more than 900 pages of calculation in about four years attempted to measure the orbit of Mars o from a moving platform o who's orbit was not centered on the Sun o rotating on its axis o of a planet varying in its orbital speed around the Sun. Kepler's calculations were immensely difficult... but he eventually realized that an ellipse with an eccentricity of about nine percent agreed with Tycho Brahe's observational data. Kepler found that the orbits of planets in our solar system follow ellipses, sweeping out equal areas in equal times (Newton would later show this as the conservation of angular momentum as you point out). Newton discovered (and showed mathematically) that objects in free fall (such as planets influenced by a central force like the Sun's gravity) follow the paths of conic sections. Ref: http://learning.physics.iastate.edu/DemoRoom/MU.htm#22 The combination of Newton's law of gravity and F=ma . The task of deducing all three of Kepler's laws from Newton's universal law of gravitation is known as the Kepler problem. Its solution is one of the crowning achievements of Western thought. A model for Gravitation was essential. http://scienceworld.wolfram.com/physics/Gravity.html |
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tt40 wrote:
In everything I've read about planets and elliptical orbits, I can't ever recall any author (Feynman, Newton, 'Ask an Astronomer' etc.), explaining exactly 'why' the orbit is elliptical. Oh sure there's been lots of mathematics to explain the orbit and how it works, but most of the explanations don't provide a definitive statement as to why it IS elliptical. I'm afraid there *is* no intuitive reason why it's an ellipse. You have to remember that a mathematical derivation is generally a rather terse and compact description of "why" something is true. As Chris says, it's difficult to translate that into English without losing precision. You can do it, but then the English is much longer than the math. Even so, the derivation of a simple fact like Newton's law of universal gravitation leading to an elliptical orbit is fairly involved. If there really were a simple and intuitive explanation why it's an ellipse, the mathematics would be pretty short and straightforward. The fact that it isn't reveals something deep about mathematics and celestial mechanics. I think it's one of the most beautiful aspects of theoretical astronomy, and a major reason why Newton's Principia Mathematica is considered the crowning achievement of science. -- Brian Tung The Astronomy Corner at http://astro.isi.edu/ Unofficial C5+ Home Page at http://astro.isi.edu/c5plus/ The PleiadAtlas Home Page at http://astro.isi.edu/pleiadatlas/ My Own Personal FAQ (SAA) at http://astro.isi.edu/reference/faq.txt |
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tt40 wrote:
In everything I've read about planets and elliptical orbits, I can't ever recall any author (Feynman, Newton, 'Ask an Astronomer' etc.), explaining exactly 'why' the orbit is elliptical. Oh sure there's been lots of mathematics to explain the orbit and how it works, but most of the explanations don't provide a definitive statement as to why it IS elliptical. or (this space left blank for the correct answer) It is a direct consequence of conserving angular momentum and total energy when a body moves in an inverse square law gravitational field. You can derive the equations for orbital motion this way starting from first principles. Most decent physics text books should cover this in some detail. The orbit is elliptical because an ellipse is one solution of the equations of motion (for a bound orbit). The other solutions are a parabola for a particle just able to escape, and a hyperbola for a particle with more than enough kinetic energy to break free (typically non-periodic comets follow these paths). Regards, Martin Brown |
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"tt40" wrote in message oups.com... In everything I've read about planets and elliptical orbits, I can't ever recall any author (Feynman, Newton, 'Ask an Astronomer' etc.), explaining exactly 'why' the orbit is elliptical. Oh sure there's been lots of mathematics to explain the orbit and how it works, but most of the explanations don't provide a definitive statement as to why it IS elliptical. Until someone can do the 'why', I'm going to assume that either: 1. it's because the Sun is in a rotation of it's own and all the planets have to scoot to 'catch' up with it. But since the Sun is moving too, the now-receding planet's momentum carries it further away than it expected, so it maps out a stretched circle, longer than it thought was necessary. So it's stretching the distance on the long-arm of the orbit and has to scoot back in again, chasing that moving Sun. or 2. the minute gravitational tug of the planet pulls the Sun closer (out Hi, Orbits are not elliptical although Kepler as so-called "demonstrated" it. Planets and satellites are in mutual interactions more or less pronounced with all other bodies, they are thus perturbated in their circular rotation. We usually refer to the ellipse by abuse of language, doing a very rought approximation because to be accurate trajectories (geodesics) are not really elliptical but much more complex. Thierry http://www.astrosurf.org/lombry of its 'fixed' position relative to the planet) which increases the mutual gravitational attraction so that they are each attracted that little bit stronger. But since the Plant is still in orbit, it follows the short arm of the ellipse that little bit faster or a little more energised. It then maps out the long-arm of the ellipse and gravitational attraction recedes just a little bit, allowing it to 'stretch that circle'. or (this space left blank for the correct answer) Greg |
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On 2005-10-12, tt40 wrote:
In everything I've read about planets and elliptical orbits, I can't ever recall any author (Feynman, Newton, 'Ask an Astronomer' etc.), explaining exactly 'why' the orbit is elliptical. Oh sure there's been lots of mathematics to explain the orbit and how it works, but most of the explanations don't provide a definitive statement as to why it IS elliptical. Orbits are elliptical because of the inverse square law of gravity and Newton's three laws of motion. Isaac Newton worked it out in Principia back in the 17th century. -- The night is just the shadow of the Earth. |
#9
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In article ,
Martin Brown wrote: tt40 wrote: In everything I've read about planets and elliptical orbits, I can't ever recall any author (Feynman, Newton, 'Ask an Astronomer' etc.), explaining exactly 'why' the orbit is elliptical. Oh sure there's been lots of mathematics to explain the orbit and how it works, but most of the explanations don't provide a definitive statement as to why it IS elliptical. or (this space left blank for the correct answer) It is a direct consequence of conserving angular momentum and total energy when a body moves in an inverse square law gravitational field. This is part of it, but you missed one important reason: it is also because gravity varies inversely with the square of the distance. If gravity had varied with distance in some other way, the orbits would get different shapes - even if angular momentum and energy are conserved. You can derive the equations for orbital motion this way starting from first principles. Most decent physics text books should cover this in some detail. The orbit is elliptical because an ellipse is one solution of the equations of motion (for a bound orbit). The other solutions are a parabola for a particle just able to escape, and a hyperbola for a particle with more than enough kinetic energy to break free (typically non-periodic comets follow these paths). Regards, Martin Brown -- ---------------------------------------------------------------- Paul Schlyter, Grev Turegatan 40, SE-114 38 Stockholm, SWEDEN e-mail: pausch at stockholm dot bostream dot se WWW: http://stjarnhimlen.se/ |
#10
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In article , Brian Tung wrote:
tt40 wrote: In everything I've read about planets and elliptical orbits, I can't ever recall any author (Feynman, Newton, 'Ask an Astronomer' etc.), explaining exactly 'why' the orbit is elliptical. Oh sure there's been lots of mathematics to explain the orbit and how it works, but most of the explanations don't provide a definitive statement as to why it IS elliptical. I'm afraid there *is* no intuitive reason why it's an ellipse. Yes, there is an intuitive reason: the orbits are ellipses with the Sun at one of the foci because gravity follows an inverse-square law. If gravity had varied in some other way, then the orbits would (usually) not have been ellipses. One example: if gravity would have been directly proportional to distance (i.e. if gravity had *increased* with distance - we could call this hypothetical case "rubber band gravity") the orbits would have been ellipses too, but the Sun would have been at the *center* of the ellipse, not at one of the foci of the ellipse. This case can be simulated with a little ball attached to a stick with a very elastic rubber band. Another hypothetical case: if gravity would have varied as the inverse *fifth* power of the distance, all orbits would have been spirals. I.e. all planets would have either spiralled into the Sun or spiralled out into space. Needless to say, a solar system would under such circumstances become very short-lived. You have to remember that a mathematical derivation is generally a rather terse and compact description of "why" something is true. As Chris says, it's difficult to translate that into English without losing precision. You can do it, but then the English is much longer than the math. Even so, the derivation of a simple fact like Newton's law of universal gravitation leading to an elliptical orbit is fairly involved. If there really were a simple and intuitive explanation why it's an ellipse, the mathematics would be pretty short and straightforward. The fact that it isn't reveals something deep about mathematics and celestial mechanics. I think it's one of the most beautiful aspects of theoretical astronomy, and a major reason why Newton's Principia Mathematica is considered the crowning achievement of science. -- Brian Tung The Astronomy Corner at http://astro.isi.edu/ Unofficial C5+ Home Page at http://astro.isi.edu/c5plus/ The PleiadAtlas Home Page at http://astro.isi.edu/pleiadatlas/ My Own Personal FAQ (SAA) at http://astro.isi.edu/reference/faq.txt -- ---------------------------------------------------------------- Paul Schlyter, Grev Turegatan 40, SE-114 38 Stockholm, SWEDEN e-mail: pausch at stockholm dot bostream dot se WWW: http://stjarnhimlen.se/ |
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