Lib/turtledemo/planet_and_moon.py - platform/external/python/cpython3 - Gitiles

 #!/usr/bin/env python3
 """       turtle-example-suite:

         tdemo_planets_and_moon.py

 Gravitational system simulation using the
 approximation method from Feynman-lectures,
 p.9-8, using turtlegraphics.

 Example: heavy central body, light planet,
 very light moon!
 Planet has a circular orbit, moon a stable
 orbit around the planet.

 You can hold the movement temporarily by
 pressing the left mouse button with the
 mouse over the scrollbar of the canvas.

 """
 from turtle import Shape, Turtle, mainloop, Vec2D as Vec

 G = 8

 class GravSys(object):
     def __init__(self):
         self.planets = []
         self.t = 0
         self.dt = 0.01
     def init(self):
         for p in self.planets:
             p.init()
     def start(self):
         for i in range(10000):
             self.t += self.dt
             for p in self.planets:
                 p.step()

 class Star(Turtle):
     def __init__(self, m, x, v, gravSys, shape):
         Turtle.__init__(self, shape=shape)
         self.penup()
         self.m = m
         self.setpos(x)
         self.v = v
         gravSys.planets.append(self)
         self.gravSys = gravSys
         self.resizemode("user")
         self.pendown()
     def init(self):
         dt = self.gravSys.dt
         self.a = self.acc()
         self.v = self.v + 0.5*dt*self.a
     def acc(self):
         a = Vec(0,0)
         for planet in self.gravSys.planets:
             if planet != self:
                 v = planet.pos()-self.pos()
                 a += (G*planet.m/abs(v)**3)*v
         return a
     def step(self):
         dt = self.gravSys.dt
         self.setpos(self.pos() + dt*self.v)
         if self.gravSys.planets.index(self) != 0:
             self.setheading(self.towards(self.gravSys.planets[0]))
         self.a = self.acc()
         self.v = self.v + dt*self.a

 ## create compound yellow/blue turtleshape for planets

 def main():
     s = Turtle()
     s.reset()
     s.getscreen().tracer(0,0)
     s.ht()
     s.pu()
     s.fd(6)
     s.lt(90)
     s.begin_poly()
     s.circle(6, 180)
     s.end_poly()
     m1 = s.get_poly()
     s.begin_poly()
     s.circle(6,180)
     s.end_poly()
     m2 = s.get_poly()

     planetshape = Shape("compound")
     planetshape.addcomponent(m1,"orange")
     planetshape.addcomponent(m2,"blue")
     s.getscreen().register_shape("planet", planetshape)
     s.getscreen().tracer(1,0)

     ## setup gravitational system
     gs = GravSys()
     sun = Star(1000000, Vec(0,0), Vec(0,-2.5), gs, "circle")
     sun.color("yellow")
     sun.shapesize(1.8)
     sun.pu()
     earth = Star(12500, Vec(210,0), Vec(0,195), gs, "planet")
     earth.pencolor("green")
     earth.shapesize(0.8)
     moon = Star(1, Vec(220,0), Vec(0,295), gs, "planet")
     moon.pencolor("blue")
     moon.shapesize(0.5)
     gs.init()
     gs.start()
     return "Done!"

 if __name__ == '__main__':
     main()
     mainloop()
	#!/usr/bin/env python3
	""" turtle-example-suite:

	tdemo_planets_and_moon.py

	Gravitational system simulation using the
	approximation method from Feynman-lectures,
	p.9-8, using turtlegraphics.

	Example: heavy central body, light planet,
	very light moon!
	Planet has a circular orbit, moon a stable
	orbit around the planet.

	You can hold the movement temporarily by
	pressing the left mouse button with the
	mouse over the scrollbar of the canvas.

	"""
	from turtle import Shape, Turtle, mainloop, Vec2D as Vec

	G = 8

	class GravSys(object):
	def __init__(self):
	self.planets = []
	self.t = 0
	self.dt = 0.01
	def init(self):
	for p in self.planets:
	p.init()
	def start(self):
	for i in range(10000):
	self.t += self.dt
	for p in self.planets:
	p.step()

	class Star(Turtle):
	def __init__(self, m, x, v, gravSys, shape):
	Turtle.__init__(self, shape=shape)
	self.penup()
	self.m = m
	self.setpos(x)
	self.v = v
	gravSys.planets.append(self)
	self.gravSys = gravSys
	self.resizemode("user")
	self.pendown()
	def init(self):
	dt = self.gravSys.dt
	self.a = self.acc()
	self.v = self.v + 0.5dtself.a
	def acc(self):
	a = Vec(0,0)
	for planet in self.gravSys.planets:
	if planet != self:
	v = planet.pos()-self.pos()
	a += (Gplanet.m/abs(v)3)v
	return a
	def step(self):
	dt = self.gravSys.dt
	self.setpos(self.pos() + dt*self.v)
	if self.gravSys.planets.index(self) != 0:
	self.setheading(self.towards(self.gravSys.planets[0]))
	self.a = self.acc()
	self.v = self.v + dt*self.a

	## create compound yellow/blue turtleshape for planets

	def main():
	s = Turtle()
	s.reset()
	s.getscreen().tracer(0,0)
	s.ht()
	s.pu()
	s.fd(6)
	s.lt(90)
	s.begin_poly()
	s.circle(6, 180)
	s.end_poly()
	m1 = s.get_poly()
	s.begin_poly()
	s.circle(6,180)
	s.end_poly()
	m2 = s.get_poly()

	planetshape = Shape("compound")
	planetshape.addcomponent(m1,"orange")
	planetshape.addcomponent(m2,"blue")
	s.getscreen().register_shape("planet", planetshape)
	s.getscreen().tracer(1,0)

	## setup gravitational system
	gs = GravSys()
	sun = Star(1000000, Vec(0,0), Vec(0,-2.5), gs, "circle")
	sun.color("yellow")
	sun.shapesize(1.8)
	sun.pu()
	earth = Star(12500, Vec(210,0), Vec(0,195), gs, "planet")
	earth.pencolor("green")
	earth.shapesize(0.8)
	moon = Star(1, Vec(220,0), Vec(0,295), gs, "planet")
	moon.pencolor("blue")
	moon.shapesize(0.5)
	gs.init()
	gs.start()
	return "Done!"

	if __name__ == '__main__':
	main()
	mainloop()