# Predict the position of a Rigidbody Object in x second

Let's say that you have a `Rigidbody` Object that moves. Force is added to this Object via `Rigidbody.AddForce` or `Rigidbody.velocity`. The Object can roll hit another Object and change direction.

I know about Extrapolation but in this case, it's nearly impossible to use some formula to obtain the position of the object in x seconds, since the Object can hit another object and change speed/direction in the process.

Unity 2017 introduced `Physics.autoSimulation` and `Physics.Simulate` to solve this problem. For 2D physics, that is `Physics2D.autoSimulation` and `Physics2D.Simulate`. All I did was first set `Physics.autoSimulation` to false then call the `Physics.Simulate` function.

In my example, I wanted to know where a `Rigidbody` would be in `4` seconds after adding force to it, it seems to work fine for tiny seconds like `1`. The problem is that when I pass in bigger numbers like `5` and above, to the `Simulate` function, the predicted position is not accurate. It's way way off.

Why is this happening and how can I fix it? This problem is worse on Android devices.

My current Unity version is Unity 2017.2.0b5.

Below is the sample code I am using. The `guide` GameObject is simply used to display/show where that predicted position is.

``````public GameObject bulletPrefab;
public float forceSpeed = 50;

public GameObject guide;

// Use this for initialization
IEnumerator Start()
{
//Disable Physics AutoSimulation
Physics.autoSimulation = false;

//Wait for game to start in the editor before moving on(NOT NECESSARY)
yield return new WaitForSeconds(1);

//Instantiate Bullet
GameObject obj = Instantiate(bulletPrefab);

Rigidbody bulletRigidbody = obj.GetComponent<Rigidbody>();

//Calcuate force speed. (Shoot towards the x + axis)
Vector3 tempForce = bulletRigidbody.transform.right;
tempForce.y += 0.4f;
Vector3 force = tempForce * forceSpeed;

//yield break;
//Predict where the Rigidbody will be in 4 seconds
Vector3 futurePos = predictRigidBodyPosInTime(bulletRigidbody, 4f);//1.3f
//Show us where that would be
guide.transform.position = futurePos;
}

Vector3 predictRigidBodyPosInTime(Rigidbody sourceRigidbody, float timeInSec)
{
//Get current Position
Vector3 defaultPos = sourceRigidbody.position;

Debug.Log("Predicting Future Pos from::: x " + defaultPos.x + " y:"
+ defaultPos.y + " z:" + defaultPos.z);

//Simulate where it will be in x seconds
Physics.Simulate(timeInSec);

//Get future position
Vector3 futurePos = sourceRigidbody.position;

Debug.Log("DONE Predicting Future Pos::: x " + futurePos.x + " y:"
+ futurePos.y + " z:" + futurePos.z);

//Re-enable Physics AutoSimulation and Reset position
Physics.autoSimulation = true;
sourceRigidbody.velocity = Vector3.zero;
sourceRigidbody.useGravity = false;
sourceRigidbody.position = defaultPos;

return futurePos;
}
``````

You are even lucky that the value of `1` worked at-all. You shouldn't pass any value above `0.03` to the `Physics.Simulate` or `Physics2D.Simulate` function.

When the value is above `0.03`, you have to it into pieces then use the `Simulate` function in a loop. Decrementing the x time while checking if it is still more or equals to `Time.fixedDeltaTime` should do it.

Replace

``````Physics.Simulate(timeInSec);
``````

with

``````while (timeInSec >= Time.fixedDeltaTime)
{
timeInSec -= Time.fixedDeltaTime;
Physics.Simulate(Time.fixedDeltaTime);
}
``````

Your new complete `predictRigidBodyPosInTime` function should look something like this:

``````Vector3 predictRigidBodyPosInTime(Rigidbody sourceRigidbody, float timeInSec)
{
//Get current Position
Vector3 defaultPos = sourceRigidbody.position;

Debug.Log("Predicting Future Pos from::: x " + defaultPos.x + " y:"
+ defaultPos.y + " z:" + defaultPos.z);

//Simulate where it will be in x seconds
while (timeInSec >= Time.fixedDeltaTime)
{
timeInSec -= Time.fixedDeltaTime;
Physics.Simulate(Time.fixedDeltaTime);
}

//Get future position
Vector3 futurePos = sourceRigidbody.position;

Debug.Log("DONE Predicting Future Pos::: x " + futurePos.x + " y:"
+ futurePos.y + " z:" + futurePos.z);

//Re-enable Physics AutoSimulation and Reset position
Physics.autoSimulation = true;
sourceRigidbody.velocity = Vector3.zero;
sourceRigidbody.useGravity = false;
sourceRigidbody.position = defaultPos;

return futurePos;
}
``````