# Import plotting routines
from pylab import *
# 1D ODE that has a pitchfork bifurcation
# x_dot = r * x - x * x * x
def PitchforkODE(r,x):
return r * x - x * x * x
# 1D Euler
def OneDEuler(r,x,f,dt):
return x + dt * f(r,x)
# Improved 1D Euler
def ImprovedOneDEuler(r,x,f,dt):
xtemp = x + dt * f(r,x)
return x + dt * ( f(r,x) + f(r,xtemp) ) / 2.0
# 4th Order Runge-Kutta Euler Method
def RKOneD(r,x,f,dt):
k1 = dt * f(r,x)
k2 = dt * f(r,x + k1/2.0)
k3 = dt * f(r,x + k2/2.0)
k4 = dt * f(r,x + k3)
return x + ( k1 + 2.0 * k2 + 2.0 * k3 + k4 ) / 6.0
# Integrator function that calls one of the three functions
# Fills up array
def Integrator(x1,x2,x3,x4,t,N,Func,dt):
for n in xrange(0,N):
x1.append( Func(r,x1[n],PitchforkODE,dt) )
x2.append( Func(r,x2[n],PitchforkODE,dt) )
x3.append( Func(r,x3[n],PitchforkODE,dt) )
x4.append( Func(r,x4[n],PitchforkODE,dt) )
t.append( t[n] + dt )
# Simulation parameters
# Integration time step
dt = 0.2
# Control parameter of the pitchfork ODE:
r = 1.0
# Set up arrays of iterates for four different initital conditions
x1 = [ 0.1]
x2 = [-0.1]
x3 = [ 2.1]
x4 = [-2.1]
x5 = [ 0.1]
x6 = [-0.1]
x7 = [ 2.1]
x8 = [-2.1]
x9 = [ 0.1]
x10 = [-0.1]
x11 = [ 2.1]
x12 = [-2.1]
# Time
t = [ 0.0]
# The number of time steps to integrate over
N = 50
#The different functions
a = OneDEuler
b = ImprovedOneDEuler
c = RKOneD
# Setup the plot
subplot(3,1,1)
Func = a
Integrator(x1,x2,x3,x4,t,N,Func,dt)
ylabel('x(t)') # set y-axis label
title(str(Func.func_name) + ': Pitchfork ODE at r= ' + str(r)) # set plot title
axis([0.0,dt*(N+1),-2.0,2.0])
# Plot the time series
plot(t,x1,'b')
plot(t,x2,'r')
plot(t,x3,'g')
plot(t,x4,'m')
subplot(212)
Func = b
Integrator(x5,x6,x7,x8,t,N,Func,dt)
ylabel('x(t)') # set y-axis label
title(str(Func.func_name) + ': Pitchfork ODE at r= ' + str(r)) # set plot title
axis([0.0,dt*(N+1),-2.0,2.0])
# Plot the time series
plot(t,x5,'b')
plot(t,x6,'r')
plot(t,x7,'g')
plot(t,x8,'m')
subplot(3,1,3)
Func = c
Integrator(x9,x10,x11,x12,t,N,Func,dt)
xlabel('Time t') # set x-axis label
ylabel('x(t)') # set y-axis label
title(str(Func.func_name) + ': Pitchfork ODE at r= ' + str(r)) # set plot title
axis([0.0,dt*(N+1),-2.0,2.0])
# Plot the time series
plot(t,x9,'b')
plot(t,x10,'r')
plot(t,x11,'g')
plot(t,x12,'m')
I'm trying to plot 3 different subplots on the same display window. One on top of the other. So basically, 3 rows 1 column. Each plot represents a different function a, b or c. Each plot should have 4 different lines.
Well...It looks like you are doing the plotting part correctly. The code below gives you the figure further below.
from pylab import *
subplot(3,1,1)
plot(arange(33))
subplot(3,1,2)
plot(arange(44))
subplot(3,1,3)
plot(arange(55),'r')
Your code does have some problems though, the first thing I found was that your t and x vectors aren't the same size.