Adding constant acceleration to this pendulum code

How can I add constant acceleration to this pendulum as a whole while using this code? The code right now is describing a pendulum, how would I alter it to describe a pendulum in a moving train (where the train has a constant acceleration)? Any help would be appreciated, thank you in advance.

``````from math import sin, pi

from time import sleep

from turtle import *

GA = 9.80665 # Gravitational Acceleration (meters per second squared)

FORM = 'Time={:6.3f}, Angle={:6.3f}, Speed={:6.3f}'

def main():

length = 10.0            # Of pendulum (meters)
ngol = - GA / length    # Negative G over L
total_time = 0.0        # Seconds
angle = 1.0             # Initial angle of pendulum (radians)
speed = 0.0             # Initial angular velocity (radians/second)
time_step = 0.05        # Seconds
acc = 1
while total_time < 30.0:
total_time += time_step
speed += ngol * sin(angle) * time_step
angle += speed * time_step
#print(FORM.format(total_time, angle, speed))
if draw(angle, length): break
sleep(time_step)

def init():

setup()
mode('logo')
speed(0)
hideturtle()
tracer(False)
penup()

def draw(angle, length):

if speed() != 0: return True
clear()
pensize(max(round(length), 1))
pendown()
forward(length * 25)
penup()
dot(length * 10)
home()
update()

if __name__ == '__main__':

init()
main()
bye()
``````
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`speeed +=` that does have constant acceleration (read "what am I missing")? –  user166390 May 11 '11 at 22:23
Do you want the acceleration to be in the direction that the pendulum in currently moving or at some other angle, say downwards? –  Peter Collingridge May 11 '11 at 22:37
I apologize for the unclear question. I wanted to have the whole system be in a constant acceleration, instead of angular acceleration. EX: A pendulum inside a moving train. –  Arash Memarzadeh May 11 '11 at 23:45
A normal train does not have constant acceleration. –  Ben Jackson May 11 '11 at 23:49
How many degrees of freedom exist in the pendulum joint? How does the direction of acceleration compare to the initial plane of motion of the pendulum? Do you like multivariate calculus? –  Ben Voigt May 11 '11 at 23:49

It seems to me that you just need to specify the horizontal position ( assuming you are on a train that is moving only in the horizontal direction ) to your draw function.

``````def draw(angle, length, horiz_pos):

if speed() != 0: return True
clear()
forward(horiz_pos)
pensize(max(round(length), 1))
pendown()
forward(length * 25)
penup()
dot(length * 10)
home()
update()
``````

And then modify the call to the draw() function by passing a position based on speed*time_step where speed is increasing ( i.e. accelerating ).

``````acc = 1
while total_time < 30.0:
total_time += time_step
speed_horiz += accel_constant * time_step
speed += ngol * sin(angle) * time_step
pos += speed_horiz * time_step
angle += speed * time_step
if draw(angle, length, pos): break
sleep(time_step)
``````
-

For constant angular acceleration w(t):

``````acc = 1
while total_time < 30.0:
...
angle += acc * speed * time_step
acc += 0.1
``````

Тhere is a good Simple harmonic motion wikipedia article, that describes pendulum motion.

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I apologize for the unclear question. I wanted to have the whole system be in a constant acceleration, instead of angular acceleration. EX: A pendulum inside a moving train. –  Arash Memarzadeh May 11 '11 at 23:42