# variable timestep and acceleration

To move objects with a variable time step I just have to do:

``````ship.position += ship.velocity * deltaTime;
``````

But when I try this with:

``````ship.velocity += ship.power * deltaTime;
``````

I get different results with different time steps. How can I fix this?

EDIT:

I am modelling an object falling to the ground on one axis with a single fixed force (gravity) acting on it.

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How are the results it different? If you set the time step to a very small number then you should get good results. Does that work for you? Please show some code? It is difficult to help you. – nielsle Jan 16 '11 at 18:37
@nielsle I made a testcase here: paste.ubuntu.com/554854 This seems to work perfectly with 1ms time-step and 100ms. So I have no idea what i was doing wrong before – tm1rbrt Jan 16 '11 at 20:40

``````ship.position = ship.position + ship.velocity * deltaTime + 0.5 * ship.power * deltaTime ^ 2;
ship.velocity += ship.power * deltaTime;
``````

The velocity part of your equations is correct and they must both be updated at every time step.

This all assumes that you have constant power (acceleration) over the deltaTime as pointed out by belisarius.

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but your not changing ship.velocity? – tm1rbrt Jan 15 '11 at 22:33
The velocity equation in the question is correct, unless the acceleration is non-constant over deltaTime. – Brian Erickson Jan 15 '11 at 22:35
Brian I can't wrap my heads around ship.velocity not changing. Could you look at my current function and see what I mean? paste.ubuntu.com/554516 – tm1rbrt Jan 15 '11 at 22:41
I'm sorry if I wasn't clear. You need to update both velocity and position at every step. The velocity equation you had to start with was correct. I've updated my answer include velocity. – Brian Erickson Jan 15 '11 at 22:46
You should roll back your correction -- you got it right first, and now it is wrong. The first equation (in the current version of your answer) describes the motion completely, with `ship.velocity` being the initial speed of the ship. The initial speed never changes, of course. – Sven Marnach Jan 15 '11 at 23:04

What you are doing (mathematically) is evaluating integrals. In the first case, the linear approximation is exact, as you have a linear relationship.

In the second case, you have at least a parabola, so your results are only approximate. You may get better results by using a smaller deltaTime, or by using the real integral equations, if available.

Edit

Brian's answer is right as long as the ship.power remains always constant, and you recalculate ship.velocity at each step. It is indeed the integral equation for a constant accelerated movement.

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This is an inherent problem trying to integrate numerically. There will be an error. Lowering delta will give you more accurate results, but more computation is needed. If your power function is integrable, you could try that.

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Or you can stick with larger timesteps and use a higher order integration scheme (say 2nd (or higher) order Runga-Kutta).... – dmckee Jan 15 '11 at 22:28

Your simulation is numerically solving the equation of motion for a single mass point. The time discretisation you are using is called "Euler method", and it is possible to show that it does not preserve energy (as the exact solution does in some way). A much better yet simple way of solving equations of motion is the "leapfrog integration".

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I think that it is difficult to see from his code if he is already using the leapfrog method. We need more code before we can judge. – nielsle Jan 16 '11 at 18:33
@nielsle: He obviously is not -- it would solve the case of constant acceleration exactly. – Sven Marnach Jan 16 '11 at 20:21
The equations for leapfrog integration are x[i+1] = x[i] + v[i+1/3 ]*dt – nielsle Jan 18 '11 at 8:50
@nielsle: It's 1/2 instead of 1/3 -- see the Wikipedia link. But my point was that the OP observed that his solution changed depending on the timestep even for constant acceleration. This simply would not happen if he would have used leapfrog integration, because you get the exact solution regardless of the timestep for this case. So we can tell he did not use leapfrog integration. – Sven Marnach Jan 18 '11 at 9:54

You can use Verlet integration to calculate position and velocity of object. Acceleration you can calculate from a = m*F where m is mass and F is force. This is one of the easiest algorithm

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In your code you use setInterval(moveBoxes,20) to update the boxes, and subsequently you use (new Date()).getTime()) to calculate deltaT. This is somewhat redundant, because you could have used the number 20 to calculate deltaT directly.

It is better write the code so that you use exacly the same value for deltaT during each time step. (In other words deltaT should not depend on the value of (new Date()).getTime())). This way your code becomes reproducible and it is easier for you to write unit tests.

Let us look at a situation where the browser has less CPU-time available for a short time interval. In this situation you want to avoid long term effects on the dynamics. One the lack of CPU-time is over you want the browser to return to a state that is unaffected by the short lack of CPU-time. You can achieve this by using the same value of deltaT in each time step.

By the way. I think that the following code

``````if(box.x < 0) {
box.x = 0;
box.vx *= -1;
}
``````

Could be replaced with

``````if(box.x < 0) {
box.x *= -1 ;
box.vx *= -1;
}
``````

Good luck with the project - and please include code samples in the first version of your question next time you ask :-)

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I was finding that on some browsers (Internet explorer) drawing the moving elements was slower than the interval. Hence the need for variable time steps. – tm1rbrt Jan 18 '11 at 9:45
I see you point. In that case I would prefer to add some code that detected the slowness of the browser and increased deltaT to a new constant value. If all the CPU-time is spend drawing of the graphics, then you could perhaps let your differential equation solver take several time steps between each update of the graphics. – nielsle Jan 18 '11 at 11:08