Cowyeet/physics/parabelfunc.py
2023-12-29 20:00:39 +01:00

116 lines
3.5 KiB
Python
Executable file

#!/usr/bin/python3
# -*- coding: utf-8 -*-
import os, sys, termios, tty, time, random
from math import sin, cos, tan, sqrt
from time import sleep
########################################################################################
def berechneflugbahn(xmin, xmax, ymin, ymax, xsteps, startwinkel, startgeschwindigkeit, starthoehe=0, gravitation=9.81, xstep=1):
x = 0
y = x**2
# in scala the resulting coordinates will be returned
scala = []
startwinkel = startwinkel * deg2rad
# Calculate time of flight, actually not used
flugdauer = startgeschwindigkeit * sin(startwinkel) / gravitation
# Calculate maximum height
hoehe = 0.5 * gravitation * flugdauer**2 + starthoehe
# calculate length of flight, actually not used
wurfweite = (
startgeschwindigkeit
* cos(startwinkel)
* (startgeschwindigkeit * sin(startwinkel) + sqrt(startgeschwindigkeit**2 * sin(startwinkel) ** 2 + 2 * gravitation * starthoehe))
) / gravitation
# cowlength is 2, if cow is an UTF8-Icon, otherwise 1
for x in range(xmin, xsteps - 1, xstep):
# the formula, which generates the y position for the corresponding x, shamelessly ripped from some schoolbook and modified.
y = (-(gravitation / (2 * startgeschwindigkeit**2 * cos(startwinkel) ** 2)) * x**2) + (tan(startwinkel) * x + starthoehe)
# Ensure, that nothing has to be drawn outside the viewport
if y <= ymax and y >= ymin:
# Stash away the coordinates into scala, which will be returned
scala += [x, int((y * 100 + 50) / 100)]
elif y <= ymin:
scala += [x, ymin]
break
else:
scala += [x, ymax]
return scala
#############################################################################################
# berechneflugbahn(cow, xmin, xmax, ymin, ymax, startwinkel, startgeschwindigkeit, starthoehe):
# some useful control
clear, home, curoff, curon = "'\x1b[2J\x1b[H", "\x1b[H", "\x1b[?25l", "\x1b[?25h"
g_erde = 9.81 # gravitation examples
mond = 1.6
jupiter = 24
# set position of cursor
def curpos(x, y):
print("\033[%d;%dH" % (ymax - y, x), end="", flush=True)
if __name__ == "__main__":
# Randomly choose a cow
cows = "🐵🐒🦍🦧🐕🐯🦝🐩🐅🐴🐎🦄🦌🐗🐂🐃🐄🐪🐫🦙🦒🐹🦘🦡🐧🕊️ 🦅🦆🦉🐍🦎🐊🦜🦚🦩🐲🐉🦕"
cowlistlength = len(cows)
cow = cows[random.randint(0, cowlistlength - 1)]
# pi is not defined by default
pi = 3.1416
deg2rad = pi / 180
# Needed: find our screensize. We are in textmode here
termsize_xy = os.get_terminal_size()
### I m p o r t a n t p a r a m e t e r s ###
# X-Resolution of the display
xmax = termsize_xy[0] - 1
xsteps = xmax
ymax = termsize_xy[1]
ymin = 0
xmin = 0
startwinkel = 34
startgeschwindigkeit = 31
starthoehe = 0
schlafzeit = 0.05
###
# needed for erasing old position
xold = xmin
yold = ymin
x = xmin
y = xmin
# Call the function, which calculates the coordinates)
ergebnis = berechneflugbahn(xmin, xmax, ymin, ymax, xsteps, startwinkel, startgeschwindigkeit, starthoehe, g_erde, 2)
print(curoff)
# here we draw the cow
for count in range(xmin, len(ergebnis), 2):
xold, yold = x, y
x, y = ergebnis[count], ergebnis[count + 1]
curpos(x, y)
print(cow, end="")
sleep(schlafzeit)
curpos(xold, yold)
print("☁️ ", end="")
sleep(2)
sys.exit(home + curon)