# Top-down object movement

If I was looking at a btRigidBody (in BulletPhysics, for example) from top down and I wanted to have the movement be so that when I press forward it will always go in its forward direction, even after I turn it, how would I apply forward movement and rotation?

For direction it appears that I would use applyCentralForce, but what force? Is there a way to apply the forward direction as a force? For rotation would it be as simple as just rotating the transform?

-
How do you know what "forward" is? –  Nicol Bolas Oct 21 '12 at 21:22
Forward being the button I press for input, I know how to do that, just the movement I am unsure of. –  chadb Oct 21 '12 at 21:34
I meant, how do you know what direction forward is? The object can rotate around and so forth, so you have to be able to tell where "forward" is somehow, yes? BulletPhysics certainly doesn't know; it doesn't favor one direction over another. –  Nicol Bolas Oct 21 '12 at 21:41
With a 3x3 row major matrix, the forward direction is 13, 23, 33. –  chadb Oct 21 '12 at 22:10

Well, the way I've applied it in my top down game project is as follows, but there are possibly other solutions:

``````double force = 1.0;
double x = 0;
double y = 0;
std::map<string, int> keyHeld;
if (keyHeld["forward"])
{
x += sin(radian) * force * deltaTime;
y -= cos(radian) * force * deltaTime;
}
``````

This will always move the object at the angle indicated in radians and by an amount that's consistent across multiple computers.

-
Can you please explain how this would work? I am not entirely sure how it would work (and I tried it, and it does not for me so far). –  chadb Oct 24 '12 at 4:29
Well it's very simple physics substitution, so I'm not sure if it's what you're after. However, by moving the x and the y by the sin and the negative cos of the radian respectively, you move the object in the direction the radian dictates it's facing. –  Quarter Oct 26 '12 at 1:30

You need to define what forward is. Usually you have a local coordiante system that your object is defined in. For example you can define the positive z-axis of this coordinate system as forward. If your engine needs you to add forces in a global coordinate system, you need to keep track about the orientation changes of your object and apply this to your forward direction.

Say you have a 4x4 transformation matrix that transforms object local coordinates to world coordinates, take the upper left 3x3 rotation matrix R and use it to transform your local forward (0, 0, 1). Now applay a multiple (by the value of the force) of this direction as the new force to your object.

-
As I explained in the comment above, With a 3x3 row major matrix, the forward direction is 13, 23, 33. –  chadb Oct 23 '12 at 3:51
Yes, but as i wrote it's up to the user to define a local forward direction. So your statement is only true if the local forward is the positive z-axis. Furthermore in your comment it's not clear what 3x3 matrix your'e talking about. But if you know that already why do you asked that question? –  AD-530 Oct 23 '12 at 7:35
I only know what the forward vector is, not as to how it may pertain to how the rotation may also be applied. –  chadb Oct 23 '12 at 7:45
The rotation is included in your forward vector (after transforming it to world coordinates). Say your local forward is v = (0, 0, 1)^T and R holds the rotation of your object, then the forward in world coordinates is R*v what simplifies to just take the 3rd column of R. –  AD-530 Oct 23 '12 at 8:04

Off the top of my head, as I'm dealing with a similar problem, you could use something like this

``````float matrix[3][3];

btVector3 direction(matrix[1][3], matrix[2][3], matrix[3][3]);

direction.normalize();

float proportionalFactor;

bool smoothMovment;

if (smoothMovment)
body->applyCentralForce(direction * proportionalFactor); // brings smooth acceleration
else
body->applyCentralImpulse(direction * proportionalFactor); // brings instant motion

/// you can't change instantly change the orientation (aka rotation), but this could get a smooth rotation toward the desired direction

btVector3 bodyForward(0,0,-1); // it's up to you to devine the initial body forward direction, for instance -Z axis is btVector3(0,0,-1)

btVector3 axisOfRotation = direction.cross(bodyForward).normalized();

float angleOfRotation = acos(direction.dot(bodyForward));

float rotationChangeSmoothness;

body->applyTorqueImpulse(axisOfRotation * angleOfRotation * rotationChangeSmoothness);
``````
-