# example of point-based gravity in c++

I am trying to figure out how to implement gravity into my application i'm creating. I have a sphere in Opengl and im wanting to give it gravity like a planet. so any small objects near it will "fall" to the surface of it. Every where I go on the net it shows formulas but never show examples. Im wondering if anyone could point me in the direction of a example in c++. I dont really want to use a physics library, I want to be able to look at the example and learn from it to understand it myself.

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Do you understand the formula? If not, then go to a library (an actual library, a real-world building with paper books inside) and consult a physics textbook. You can't write code that works if you don't understand the physics, and if you try to take a shortcut by studying physics simulations, you'll just wind up coming back here over and over again. – Beta Apr 1 '11 at 12:47

You need to write a function that implements the gravity formula, for example:

``````const float g = 9.81f;  // Gravity of Earth in m/s²
float gravity(Vec3 p1_pos, Vec3 p2_pos, float p1_mass, float p2_mass)
{
float distance = (p2_pos - p1_pos).length();
return g * p1_mass * p1_mass / (distance*distance);
}
``````

Multiply the magnitude of the force by the unit vector parallel top2_pos - p1_pos to give the force a direction. Then, simply compute the acceleration on the object using F = ma

``````struct object
{
Vec3 pos;
Vec3 vel;
float mass;

};

{
vel += (force / mass) * dt;
}
``````

Be sure to multiply the acceleration by dt, the number of seconds per frame. This allows your simulation to progress at a regular speed regardless of the speed of the computer. I have written an NBody simulation that uses a technique quite similar to the one above to simulate an arbitrary number of planets and calculates the force they attract each other with. For every object that you want to simulate, use the gravity function to get the magnitude of the force and call add_force() on the object to push it. You will need to substitute Vec3 for your own vector class, and make sure it has operator overloading. OpenGL probably provides one.

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In your example you should name your vel accel, because it is an acceleration an not a velocity. To get the velocity you have constantly increase your vel by accel. – flolo Apr 1 '11 at 7:30
Also, you have to take into account the delta time between 2 calculations, as it is probably rendered with a variable fps, and is for demonstration (not simulation) purposes, it means you cannot rely on a constant time between frames, you have to get the current system time (with a precision to the millisecond) and calculate the new values according to the current delta time (actual time - previous time, obviously). – Léo Germond Apr 1 '11 at 7:36
No, the acceleration is equal to force / mass. It is the change in velocity, which is why that value is being added to vel. For your second comment, you are correct. I simplified the code because I don't the project with me. Will add that later. – jeffythedragonslayer Apr 1 '11 at 7:39
you are right, I overread the += and saw just a = – flolo Apr 1 '11 at 7:43
You are using the wrong gravitational constant. While it's true that at the surface of the Earth, the acceleration due to gravity is 9.8 m/s^2, this is NOT what should be used in the gravitational equation. You need to use the Gravitational Constant, G, which is true for all massive objects, not just the Earth. The value for G is 6.67 x 10E-11 with units of Newtons * meters^2 / kg^2. – OrangeWombat Nov 29 '12 at 18:13

Maybe it is too late for this, but at least others might get something from this.

Here is a program I just wrote in C++ and OpenGL of gravity simulation. Hope it will help. The source code is in the description of the video and can be found here as well.

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You might not want to user a physics library, but if you take a look at the source code for one, it would probably help you to understand the formula's you keep seeing a bit better. Box2D is an open source physics engine that you might want to take a look at. Alternately, Bullet is an open source 3d physics engine.

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I think there is a mistake. The formula that calculates the force between object A of mass mA and object B of mass mB at distance r is: [g * (mA * mB)] / (r^2)

Same as above until now. The mistake is that when using meters for distances and kg for mass there is a constant that makes the force porportional with the measurments in real world. That constant is in my fomula noted as 'g'. This 'g' is not 9.81 . This 'g', the gravitational constant. is equal with: 6.67300 × 10^-11 m^3 / (kg * s^2) .

So, for objects A and B both having masses of 1 kg, and the distance 'r' being 1 meter the force between them will be: 6.67300 × 10^-11 (kg * m) / (s^2) , or 6.67300 × 10^-11 Newtons . This is a very small force :) Our planet hass mA HUGE :D . This mass is what gives at the surface a force of 9.81 Newtons on a body with mass of 1 kg.

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