Clohessy Wiltshire equations

Solution

We can obtain closed form solutions of these coupled partial differential equations in matrix form, allowing us to find the position and velocity of the chaser at any time given the initial position and velocity.

δ r → ( t ) = [ Φ r r ( t ) ] δ r 0 → + [ Φ r v ( t ) ] δ v 0 →

δ v → ( t ) = [ Φ v r ( t ) ] δ r 0 → + [ Φ v v ( t ) ] δ v 0 →

where

Φ r r ( t ) = [ 4 − 3 cos ⁡ n t 0 0 6 ( sin ⁡ n t − n t ) 1 0 0 0 cos ⁡ n t ]

Φ r v ( t ) = [ 1 n sin ⁡ n t 2 n ( 1 − cos ⁡ n t ) 0 2 n ( cos ⁡ n t − 1 ) 1 n ( 4 sin ⁡ n t − 3 n t ) 0 0 0 1 n sin ⁡ n t ]

Φ v r ( t ) = [ 3 n sin ⁡ n t 0 0 6 n ( cos ⁡ n t − 1 ) 0 0 0 0 − n sin ⁡ n t ]

Φ v v ( t ) = [ cos ⁡ n t 2 sin ⁡ n t 0 − 2 sin ⁡ n t 4 cos ⁡ n t − 3 0 0 0 cos ⁡ n t ]

Note that Φ v r ( t ) = d d t Φ r r ( t ) and Φ v v ( t ) = d d t Φ r v ( t )

Since these matrices are easily invertible, we can also solve for the initial conditions given only the final conditions and the properties of the target vehicle's orbit.