Applications of Systems of Equations(x(t), y(t))
-μ 1-μ
Figure 10.27 The Restricted Three-Body Problem
and Associated Critical Points495xUsing Newton's second law of motion and the inverse square law of motion,
it can be shown that the equations of motion for the spaceship arex" = 2 y' + x (1 - μ)(x + μ) μ(x - 1 + μ)
r3 s3
(1)
y" = -2x' + y - (l - μ)y - μy
r3 s3
where r = ((x + μ)^2 + y^2 )^112 and s = ((x - 1 + μ)^2 + y^2 )^112. Thus, r is
the distance of the spaceship from the earth and s is its distance from the
moon. If we let Y1 = x, Y2 = x', y3 = y, and y4 = y', we obtain the following
equivalent system of four first-order equations
(2.1) y~ = Y2
I (1 - μ)(Y1 + μ)
(2.2) Y2 = 2y4 + Y1 - ((yi + μ)2 + y~)3/2μ(y1 - 1 + μ)
((y1 - 1 + μ)2 + y~)3/2