If there is a maximum at which the ship rotation speed can decrease/increase, you cannot prevent overshooting a target set by the player if she changes her target while still moving towards another target. What you can do, however, is ensure that you adapt your current speed in such a manner that you reach the final goal at zero speed (i.e. without overshooting) as fast as possible. See http://en.wikipedia.org/wiki/Optimal_control for a general method for solving optimal control problems. Optimal control typically involves accelerating/decellerating at full-thrust always (until the target is reached).
To solve the problem, denote the current angle at the moment a new command is given by C, and the target angle by T. Angular speed at the moment the new target is received is denoted by V', max acceleration will be denoted by M. Positive V corresponds to rotating clockwise, negative V with moving counterclockwise.
Say your initial angular speed is bigger than 0 (V'>0), then there are two possibilities to reach T:
1) increase V for a period U, and then decrease it until it is zero. Then your final angle will be (draw a picture of velocity vs time, and determine it's area to verify):
C+ V'^2/(2 M) + 2U*V' + M U^2
Which should be equated to T to find U (ABC formula), unless it gives no solution (negative discriminant), in which option 2) should give a solution.
2) decrease V for a while, eventually changing the sign of V, and then increase V until at zero. Drawing a picture gives:
C+ V^2/(2 M) - M U^2.
equating to T gives U.
You will find that their is a very simple condition which determines whether option 1) or 2) gives a solution.
The case in which initial velocity V'<0 is similar (1 and 2, and maybe some signs, flip). Again, draw a picture in case you get confused.
There is some subtle thing here, because if you want to be at T', then T'+K 360 degrees (/2 pi radians) will also do (provided you can go fully round the clock). So you can actually choose the alias of T that will be easiest to go to.