I created a program that generates the placement of the pendulum, length, position of the ball, velocity, angles, and trajectory. The program's task is to find a solution where the ball can land safely through a 'cave'. The pendulum is inside an 85.75 by 66.75 area, length < 65, ball radius = 1.25

I want to create a simulation of the experiment in pygame, that will run my 1st program to generate all the parameters, and then display the solution and path the ball will follow. I have spent the past couple days learning pygame, but can't figure out how to 'transfer' my first program. Ive looked at other pendulum simulators, and tried to change it to work for my experiment, but I got lost and decided to come to StackOverflow for advice. If anyone could show me where I went wrong in making the simulation, it would be very appreciated.

first program

```
import math as m
import numpy as np
# Variables
c = 28.5
Wx = 20
Wy = 30
d = 85.75
f = 66.75
g = 385.826772
ay = -g
# Calculations
for theta in np.arange(1, 90, .01):
l = Wx + (m.tan(m.radians(theta)) * (f - Wy))
if Wx <= l <= d:
phi = 90 - theta
v = (d - l) / m.sin(m.radians(phi))
vc = v - 1.25
if (f - Wy) <= v <= 65:
h = f - (m.cos(m.radians(phi)) * v)
a = v * m.sin(m.radians(theta))
b = v * m.cos(m.radians(theta))
by = f - b
bx = l - a
if h <= f and by <= c:
vel = m.sqrt((2 * g) * (h - by)) * .95
velx = vel * m.cos(m.radians(theta))
vely = vel * m.sin(m.radians(theta))
y = (-vely**2) / (2 * ay)
Ymax = y + by
if m.isclose(Ymax, c, abs_tol= .01):
t1 = -vely / ay
t2 = m.sqrt((2 * Ymax) / -ay)
T = t1 + t2
x = velx * T
print(' l: {0} v: {1} vc: {2} h: {3}\n bx: {4} by: {5}\n vel: {6} velx: {7} vely: {8}\n y: {9} Ymax: {10} x: {11} T: {12}\n theta: {13} phi: {14}\n'
.format(l, v, vc, h, bx, by, vel, velx, vely, y, Ymax, x, T, theta, phi))
```

Simulator

```
import pygame
import numpy as np
import math as m
from math import pi
# Tarzan Variables
c = 28.5
Wy = 30
Wx = 20
d = 85.75
f = 66.75
# Colors
black = (0, 0, 0)
red = (255, 0, 0)
white = (255, 255, 255)
green = (0, 255, 0)
# Pygame Variables
theta = 0
v = 0
vel = 0
acc = 0
# Start Pygame
width, height = 900, 700
pygame.init()
background = pygame.display.set_mode((width, height))
clock = pygame.time.Clock()
# Tarzan
class Pendulum(object):
def __init__(self, XY, l, radius):
self.x = XY[0]
self.y = XY[1]
self.l = l
self.radius = radius
def draw(self, bg):
pygame.draw.line(bg, white, (self.l, 0), (self.x, self.y), 4)
pygame.draw.circle(bg, red, (self.x, self.y), self.radius)
pygame.draw.line(bg, green, (Wx, height), (Wx, (height - Wy)), 4)
# pygame.draw.circle(bg, white, (self.l, 0), int(v)) --- to see if pendulum is following an arc
def theta_v():
v = m.sqrt(m.pow(pendulum.x - (width / 2), 2) + m.pow(pendulum.y, 2))
theta = m.asin(((pendulum.x - (width / 2)) / v))
return theta, v
def get_path(theta, v):
pendulum.x = round(pendulum.l + (v * m.sin(theta)))
pendulum.y = round(v * m.cos(theta))
pendulum.l = pendulum.x - (v * m.sin(m.radians(theta)))
def redraw():
background.fill(black)
pendulum.draw(background)
pygame.display.update()
pendulum = Pendulum((75, 67), 500, 15)
# Close Pygame
stop = False
acceleration = False
while not stop:
clock.tick(60)
for event in pygame.event.get():
if event.type == pygame.QUIT:
stop = True
if event.type == pygame.MOUSEBUTTONDOWN:
pendulum = Pendulum(pygame.mouse.get_pos(), 500, 15)
theta, v = theta_v()
acceleration = True
if acceleration:
acc = -.005 * m.sin(theta)
vel += acc
vel *= .995
theta += vel
get_path(theta, v)
print(pendulum.x, pendulum.y, (theta * (180 / pi)), v, vel, pendulum.l)
redraw()
pygame.quit()
quit()
```