# Implementing Projectile Motion

I've scored the internet for sources and have found a lot of useful information, but they are math sites trying to tell me how to solve what angle an object has to be at to reach y location. However, I'm trying to run a simulation, and haven't found any solid equations that can be implemented to code to simulate a parabolic curve. Can those with some knowledge of physics help me on this?

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what about air friction (Windage) ? –  osgx Mar 20 '10 at 0:55
For simplicity, I'm going to say no. That just complicates stuff for now :) –  DMan Mar 20 '10 at 0:56

While Benny's answer is good, especially in its generality, you can solve your problem exactly rather than using finite integration steps. The equation you want is:

``````s = u*t + 0.5*a*t^2;
``````

Look here for an explanation of where this comes from.

Here s is the displacement, u is the initial speed, a is the acceleration and t is time. This equation is only 1 dimensional, but can be easily used for your problem. All you need to do is split the motion of your projectile into two components: one parallel to your acceleration and one perpendicular. If we let Sx describe the displacement in the x direction and Sy the displacement in the y direction we get:

``````Sx = Ux*t + 0.5*Ax*t;
Sy = Uy*t + 0.5*Ay*t;
``````

Now in your particular example Ax is 0 as the only acceleration is due to gravity, which is in the y direction, ie Ay = -g. The minus comes from the fact that gravity will be acting in the opposite direction to the original motion of the object. Ux and Uy come from simple trigonometry:

``````Ux = U*cos(angle);
Uy = U*sin(angle);
``````

Putting this all together you get two equations describing where the projectile will be at a time t after being launched, relative to its starting position:

``````Sx = U*cos(angle)*t;
Sy = U*sin(angle)*t - 0.5*g*t^2;
``````
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Unless I really screwed up on this, my guy doesn't move at all. Code is here pastebin.com/zecMTnDi- then these values are added to the x and y values. –  DMan Mar 20 '10 at 2:30
Link does not work. I'd imagine that the reason your guy isn't moving is that your not updating your time variable t. So on every frame you should be doing something like t += 0.05; –  pheelicks Mar 20 '10 at 10:57
Well, my time variable is gameTime, which in XNA represents the time elapsed either between frames, or the total time elapsed since the game started. Neither works. –  DMan Mar 20 '10 at 15:10
I can't see why it wouldn't work. There must be a problem with your code elsewhere. In the equations I've given you it is clear that Sx and Sy will change if t changes, so a stationary object implies that either your t is not changing or you're not updating the position of the projectile correctly. I would avoid using gameTime as this assumes the projectile is launched when the game starts. Instead have a variable t which is set to 0 at launch and increases by a finite amount on each frame, e.g. t += 0.05 –  pheelicks Mar 20 '10 at 20:58

Don't use the equations for position. Instead, use the equations for velocity. Calculate the new velocity each loop of your simulation from the object's old velocity and apply it to your object. You will need to know the elapsed time between each loop of the simulation. Of course, this works for vertical or horizontal velocity.

``````v_new = v_old + acceleration * delta_time  (from wikipedia)
``````

Then apply:

``````position_new = position_old + v_new * delta_time;
``````

You can use a simple acceleration of `-9.8 m/s` (don't forget that "down" on the screen is really an increase in the vertical position! So you can use `+9.8` for simplicity). Or you could get fancy and add variable acceleration (for example, from wind, if you are also modeling the horizontal motion of the object).

Basically, the acceleration you apply is based on the sum of forces applied to the object (force of gravity, friction, jet propulsion, etc.).

``````F_final = F1 + F2 + ... + Fn
``````

If you are modeling a force applied to the object, first break the force into it's horizontal and vertical components using:

``````F_horiz = F * sin( angle )
F_vert =  F * cos( angle )  where angle is the angle between the force and the horizontal.
``````

Then calculate the acceleration from the force using:

``````a = F / mass
``````

(I give all credit for this knowledge to my first programming experience: GORILLA.BAS =) )

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Thanks for this lead. I'll go about checking some equations on my own as well. –  DMan Mar 20 '10 at 0:43
big +1 for gorilla basic reference. Good times!!! –  Pierreten Mar 20 '10 at 0:46
I just played the Gorilla game... and sucked at it :( –  DMan Mar 20 '10 at 0:50
position_new = position_old + v_new * delta_time; Nope. That doesn't work, because the velocity is not constant during the time interval. In fact, the acceleration isn't either, unless you are simply dropping the object. Back to the drawing board. Take a peek at the answer by pheelicks if you get stuck. –  Jive Dadson Mar 20 '10 at 2:18
@Jive: Acceleration is constant if you're neglecting air resistance and other subtler points . . . it's just the acceleration due to gravity. This is true whether dropping it or throwing it -- the difference between the two is just the initial velocity. It's true that the velocity isn't constant, but if you choose your time interval small enough you can closely approximate the true trajectory with linear segments (i.e. with velocity constant within each segment). –  Tim Goodman Mar 20 '10 at 3:10
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Some definitions:

``````x = x-coordinate (horizontal)
y = y-coordinate (vertical)
Vx = x-velocity
Vy = y-veloctiy
t = time
A = initial angle
V0 = intial velocity
g = acceleration due to gravity
``````

Some equations:

``````Vx = V0*cos(A)
Vy = V0*sin(A) - g*t
x = V0*cos(A)*t
y = V0*sin(A)*t - (1/2)*g*t^2
``````
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Here I'm calling the initial position `x=0`, `y=0` I'm also neglecting air resistance and various other effects such as the Coriolis force due to the rotation of the Earth -- which would matter if, say, we were talking about the trajectory of an ICBM or something. –  Tim Goodman Mar 20 '10 at 0:50
So I'm guessing I add vx and vy to x and y respectively? –  DMan Mar 20 '10 at 0:51
You can either add `Vx` and `Vy` to the previous position at every step, or just calculate the new position using the formula for `x` and `y` as functions of `t`. –  Tim Goodman Mar 20 '10 at 0:53
Thanks, I'll try both methods. –  DMan Mar 20 '10 at 0:55
Incidentally with integral calculus one can see that the equations for `x` and `y` are just the equations for `Vx` and `Vy` integrated with respect to `t`. For that matter, the equations for velocity are just the time integrals of the equations for acceleration, `Ax = 0` and `Ay = -g`. So if you know how to take an integral you never have to worry about remembering these -- the derivation is immediate. –  Tim Goodman Mar 20 '10 at 0:56