For example in Peggle or Apple Jack, the user can move around a curve showing where the ball (or the washing machine / panda or whatever) is about to go before the user has requested that the projectile is launched. I know i need to use an equation to plot the points but I'm no mathematician (anymore :(). Can anybody be so kind as to provide me with the correct equation and tell me what I should substitute in to get my X any Y values given a certain time and initial velocity.
Take a look at my answer to this question. Taken from that answer, the formula you should be using is:
(Displacement equals: initial displacement, plus initial velocity multiplied by time, plus half acceleration multiplied by time squared.) Everything except time there is a vector (acceleration will be your downwards gravity). So simply use that equation on both your X and your Y axis. Of course  the only way to guarantee that the plotted path will match your prediction equation exactly is if they are the same. That is the only way I can see for you to add support for predicting bounces. If your actual game uses something different (like a full physics simulator), and you don't need to predict bounces, and you don't have to be perfectly accurate  then this will give you a suitable approximation for the prediction. 


Simulation would probably be the easiest route to go down: create a dummy object with the specified properties and create a loop to apply the forces and say output the positions to an array and then display it, say: draw a line between the positions or draw a "ghost" of the projectile at each position. A positive thing about simulation is you can control the balance of speed and accuracy by changing how often you record the positions. 


If this is a projectile following a simple ballistic trajectory, you can use the closedform expressions provided here: http://en.wikipedia.org/wiki/Trajectory_of_a_projectile If not, it might be a lot simpler to simulate the effect of all the forces on the body for each (small) timestep, updating its position and velocity accordingly. This technique is more robust; you can add a lot more complexity to the problem without changing the basic methodology. 


You could use newton's method of approx. solving. The problem here is that you need to integrate  so you have to define the tradeoff between preciseness and calculation time. RK4 is the method that is best in my opinion  it is fast and still very precise. You can read more info at http://gafferongames.com/gamephysics/integrationbasics/ 

