1. Kepler’s Laws of Planetary Motion
© David Hoult 2009

6. The eccentricity of an ellipse gives an indication of the difference between its major and minor axes

7. The eccentricity of an ellipse gives an indication of the difference between its major and minor axes
The eccentricity depends on the distance between the two points, f (compared with the length of the piece of string)

8. eccentricity = distance between foci / major axis

9. eccentricity = distance between foci / major axis
The eccentricity of the orbits of the planets is low; their orbits are very nearly circular orbits.

10. Law 1
Each planet orbits the sun in an elliptical path with the sun at one focus of the ellipse.

11. Mercury
0.206

12. Mercury
0.206
Venus
0.0068

13. Mercury
0.206
Venus
0.0068
Earth
0.0167

14. Mercury
0.206
Venus
0.0068
Earth
0.0167
Mars
0.0934

15. Mercury
0.206
Venus
0.0068
Earth
0.0167
Mars
0.0934
Jupiter
0.0485

16. Mercury
0.206
Venus
0.0068
Earth
0.0167
Mars
0.0934
Jupiter
0.0485
Saturn
0.0556

17. Mercury
0.206
Venus
0.0068
Earth
0.0167
Mars
0.0934
Jupiter
0.0485
Saturn
0.0556
Uranus
0.0472

18. Mercury
0.206
Venus
0.0068
Earth
0.0167
Mars
0.0934
Jupiter
0.0485
Saturn
0.0556
Uranus
0.0472
Neptune
0.0086

19. Mercury
0.206
Venus
0.0068
Earth
0.0167
Mars
0.0934
Jupiter
0.0485
Saturn
0.0556
Uranus
0.0472
Neptune
0.0086
Pluto
0.25

20. ...it can be shown that...

21. minor axis
= e2
major axis
where e is the eccentricity of the ellipse

22. minor axis
= e2
major axis
where e is the eccentricity of the ellipse
which means that even for the planet (?) with the most eccentric orbit, the ratio of minor to major axis is only about:

23. 0.97 minor axis = 1 - e2 major axis
where e is the eccentricity of the ellipse
which means that even for the planet (?) with the most eccentric orbit, the ratio of minor to major axes is only about:
0.97

24. In calculations we will consider the orbits to be circular

25. Eccentricity of ellipse much exaggerated

31. Law 2
A line from the sun to a planet sweeps out equal areas in equal times.

32. Law 3
The square of the time period of a planet’s orbit is directly proportional to the cube of its mean distance from the sun.

33. r3
= a constant T2

34. Mm F
= G r2

35. Mm F
= G
F =
m r w2 r2

36. Mm F
= G
F =
m r w2 r2

37. Mm F
= G
F =
m r w2 r2
G M m
m r w2 = r2

38. Mm F
= G
F =
m r w2 r2
G M m
m r w2 = r2
2 p
w = T

39. r3 GM = T2
4p2

40. r3 GM = T2
4p2
in which we see Kepler’s third law