Keplers Laws of Planetary Motion

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SUMMARY

Kepler's Laws of Planetary Motion describe the motion of planets around the Sun, which is treated as a fixed point at the origin. The governing equation is r'' = -ur^(-3) r, where u equals y ms, with y being the universal gravitational constant and ms the mass of the Sun. The discussion emphasizes deriving the energy equation and obtaining the Lenz-Runge vector through angular momentum considerations. Additionally, the polar equation of the planet's path is expressed as l/r = 1 - ecos(theta), where l and e are constants specific to the orbit.

PREREQUISITES
  • Understanding of differential equations, specifically second-order equations.
  • Familiarity with gravitational physics and the universal gravitational constant.
  • Knowledge of angular momentum and its vector representation.
  • Basic understanding of polar coordinates and their applications in orbital mechanics.
NEXT STEPS
  • Study the derivation of the energy equation in gravitational systems.
  • Learn about the Lenz-Runge vector and its implications in orbital mechanics.
  • Explore the integration techniques for second-order differential equations.
  • Investigate the applications of polar coordinates in celestial mechanics.
USEFUL FOR

Students of physics, astrophysics enthusiasts, and anyone interested in the mathematical foundations of celestial mechanics and planetary motion.

Gwilim
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[problem]

State Keplers laws of planetary motion.

The motion of a planet about the Sun, assumed to be fixed at the origin, may be approximated by

r''= -ur^(-3) r

for u=y ms, where y is the universal gravitational constant and ms is the mass of the Sun. Derive the energy equation for this system, and by considering hXr''. where h is the angular momentum vector, obtain the Lenz-Runge vector. Now show that the path of the planet has polar equation

l/r = 1 - ecos(theta)

for suitable l and e.

[/problem]

There's so much I don't understand there it isn't even funny (obviously Keplers laws themselves will be no problem to learn, applying them however is something else). If someone can show me how to solve this type of problem once, I might be able to learn from there.
 
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Hi Gwilim! How's it going? :smile:
Gwilim said:
The motion of a planet about the Sun, assumed to be fixed at the origin, may be approximated by

r''= -ur^(-3) r

Hint: the trick with equations involving r'' and r is to introduce r' …

in other words, how do you integrate r'.r or r''.r' ?

(and r'' x r ?)
 
Umm I think I'll go learn a bit about vectors and then come back to this
 

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