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I have seen the great tutorial by Peter Colling Ridge on
and I am extending the PyParticles script
The code is available on the site(for free), I am using PyParticles4.py

Classes used in the tutorial

The Particle Class
Circular 2d objects with radius,mass,velocity,location
The Spring Class
A spring that binds 2 objects (Particles) and uses the Hooke's law (F = -kx) to determine the interaction between them
The Environment Class
The Environment where the Particles interact

I was wondering if I could to use 2 Particles and make a 'Rod' class (like the Spring class in the tutorial) that had a specific length and didn't allow the particles to come closer go further than that (specified) length.
Appling a force (when needed) to each Particle such that if one is pulled toward the left, so does the other, but Realistically..
Much like if a 2 different types of balls were joined(from the center) using a steel rod, but in 2-d..
And I don't want to use 3rd party modules

Thanks in advance..

Tried to apply constraint theorem (it failed)
Here's the code:

class Rod:
    def __init__(self, p1, p2, length=50):
        self.p1 = p1
        self.p2 = p2
        self.length = length

    def update(self):
        'Updates The Rod and Particles'
        # Temp store of co-ords of Particles involved
        x1 = self.p1.x
        x2 = self.p2.x
        ###### Same for Y #######
        y1 = self.p1.y
        y2 = self.p2.y

        # Calculation of d1,d2,d3 and final values (x2,y2) 
        # from currently known values(x1,y1)...
        # From Constraint algorithm(see @HristoIliev's comment)
        dx1 = x2 - x1
        dy1 = y2 - y1
        # the d1, d2, d3
        d1 = math.hypot(dx1,dy1)
        d2 = abs(d1)
        d3 = (d2-self.length)/d2
        x1 = x1 + 0.5*d1*d3
        x2 = x2 - 0.5*d1*d3
        y1 = y1 + 0.5*d1*d3
        y2 = y1 - 0.5*d1*d3

        # Reassign next positions
        self.p1.x = x1
        self.p2.x = x2
        ###### Same for Y #######
        self.p1.y = y1
        self.p2.y = y2
share|improve this question
Why don't you just use a very strong spring? –  Dennis Jaheruddin Jan 3 '13 at 10:58
Nope the objects just keep moving randomly, they don't behave the way I want them to and Python raises an error "OverflowError: Python int too large to convert to C long" –  Pradyun Jan 3 '13 at 11:06
Hard joints such as rods are holonomic constraints. These are usually treated by special constraint algorithms or by modelling them as infinitely stiff springs and explicitly finding the form of the corrections that have to be applied to an unconstrained system (see here for an example). –  Hristo Iliev Jan 3 '13 at 16:40
@HristoIliev what are x1,x2? Could you explain the last 2 equations, i understand i will have to apply them to both x and y components. –  Pradyun Jan 3 '13 at 18:04
@HristoIliev Nope i tried a test code, it didn't work. Used the Constraint Algorithm, it didn't simulate realistically, and collisions made the particles behave abnormally... It was the python implementation of this –  Pradyun Jan 6 '13 at 9:14

1 Answer 1

up vote 3 down vote accepted

A rod in 2D has 3 degrees of freedom (2 velocities/positions + 1 rotation/angular freq).
I would represent the position of the center which is modified by forces in the usual way and calculate the position of the particles using the rotation (for simplicity, about the center of the system) variable.
The rotation is modified by forces by

ang_accel = F * r * sin (angle(F,r)) / (2*M * r^2)


ang_accel is the angular acceleration

F is a force acting on a particular ball so there is 2 torques* that add up as there is two forces that add up (vector-wise) in order to update the position of the center.

r is half of the length
angle(F,r) is the angle between the force vector and the radius vector (from the center to the particle that suffers the force),

So that
F * r * sin (angle(F,r)) is the torque about the center, and
2*M * r^2 is the moment of inertia of the system of two points around the center.

share|improve this answer
is there a typo? ang_accel and dang_accel?? –  Pradyun Jan 31 '13 at 9:45
Yes, typo. And as said I would do it this way rather than based on the particles. You have 3 degrees of freedom and this approach is the most natural for eliminating one of the four that a 2 free particle system would have. –  Zah Feb 1 '13 at 1:17
the masses of the particles is not the same. –  Pradyun Feb 1 '13 at 9:45
You could adjust the anglular acceleration formula to account for mass variation by altering the moment of inertia. –  m.brindley Feb 1 '13 at 11:50

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