Drawing directions fields

Is there a way to draw direction fields in python?

My attempt is to modify http://www.compdigitec.com/labs/files/slopefields.py giving

#!/usr/bin/python

import math
from subprocess import CalledProcessError, call, check_call

def dy_dx(x, y):
try:
return x**2-x-2
except ZeroDivisionError:
return 1000.0

XMIN = -5.0
XMAX = 5.0
YMIN = -10.0
YMAX = 10.0
XSCL = 0.5
YSCL = 0.5

DISTANCE = 0.1

def main():
fileobj = open("data.txt", "w")
for x1 in xrange(int(XMIN / XSCL), int(XMAX / XSCL)):
for y1 in xrange(int(YMIN / YSCL), int(YMAX / YSCL)):
x= float(x1 * XSCL)
y= float(y1 * YSCL)
slope = dy_dx(x,y)
dx = math.sqrt( DISTANCE/( 1+math.pow(slope,2) ) )
dy = slope*dx
fileobj.write(str(x) + " " + str(y) + " " + str(dx) + " " + str(dy) + "\n")
fileobj.close()

try:
check_call(["gnuplot","-e","set terminal png size 800,600 enhanced font \"Arial,12\"; set xrange [" + str(XMIN) + ":" + str(XMAX) + "]; set yrange [" + str(YMIN) + ":" + str(YMAX) + "]; set output 'output.png'; plot 'data.txt' using 1:2:3:4 with vectors"])
except (CalledProcessError, OSError):
exit(1)
print "Saved image to output.png"
call(["xdg-open","output.png"])
return 0

if __name__ == '__main__':
main()

However the best image I get from this is. How can I get an output that looks more like the first image? Also, how can I add the three solid lines?

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–  fjarri Sep 16 '13 at 16:21
yes! i actually made a program to do just this... will try to find it & upload it when i get home. got some really pretty pictures as a result. –  Claudiu Sep 16 '13 at 16:57
slope fields a.k.a. direction fields –  TooTone Sep 16 '13 at 17:15

You can use this matplotlib code as a base. Modify it for your needs. I have updated the code to show same length arrows.

It is also possible to change the axis form "boxes" to "arrows". Let me know if you need that change and I could add it.

import matplotlib.pyplot as plt
from scipy import *
from scipy import integrate
from scipy.integrate import ode
import numpy as np

fig = plt.figure(num=1)

## Vector field function
def vf(t,x):
dx=np.zeros(2)
dx[0]=1
dx[1]=x[0]**2-x[0]-2
return dx

#Solution curves
t0=0; tEnd=10; dt=0.01;
r = ode(vf).set_integrator('vode', method='bdf',max_step=dt)
ic=[[-3.5,-10], [-3,-10], [-2.5,-10]]
color=['r','b','g']
for k in range(len(ic)):
Y=[];T=[];S=[];
r.set_initial_value(ic[k], t0).set_f_params()
while r.successful() and r.t +dt < tEnd:
r.integrate(r.t+dt)
Y.append(r.y)

S=np.array(np.real(Y))
ax.plot(S[:,0],S[:,1], color = color[k], lw = 1.25)

#Vector field
X,Y = np.meshgrid( np.linspace(-5,5,20),np.linspace(-10,10,20) )
U = 1
V = X**2-X-2
#Normalize arrows
N = np.sqrt(U**2+V**2)
U2, V2 = U/N, V/N
ax.quiver( X,Y,U2, V2)

plt.xlim([-5,5])
plt.ylim([-10,10])
plt.xlabel(r"\$x\$")
plt.ylabel(r"\$y\$")
plt.show()
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Thank you. That's great. –  Anush Sep 16 '13 at 17:16

Try changing your values for the parameters to this:

XSCL = .2
YSCL = .2

These parameters determine how many points are sampled on the axes.

As per your comment, you'll need to also plot the functions for which the derivation dy_dx(x, y) applies.

Currently, you're only calculating and plotting the slope lines as calculated by your function dy_dx(x,y). You'll need to find (in this case 3) functions to plot in addition to the slope.

Start by defining a function:

def f1_x(x):
return x**3-x**2-2x;

and then, in your loop, you'll have to also write the desired values for the functions into the fileobj file.

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Thanks. 0.5 seems roughly right. It still doesn't look as good to me (there is no axis for example) but in any case, do you know how to add the three solid lines? My preference would be to do the whole thing in python without gnuplot if that is possible. –  Anush Sep 16 '13 at 16:44

I had a lot of fun making one of these as a hobby project using pygame. I plotted the slope at each pixel, using shades of blue for positive and shades of red for negative. Black is for undefined. This is dy/dx = log(sin(x/y)+cos(y/x)):

You can zoom in & out - here is zoomed in on the middle upper part here:

and also click on a point to graph the line going through that point:

It's just 440 lines of code, so here is the .zip of all the files. I guess I'll excerpt relevant bits here.

The equation itself is input as a valid Python expression in a string, e.g. "log(sin(x/y)+cos(y/x))". This is then compiled. This function here graphs the color field, where self.func.eval() gives the dy/dx at the given point. The code is a bit complicated here because I made it render in stages - first 32x32 blocks, then 16x16, etc. - to make it snappier for the user.

def graphcolorfield(self, sqsizes=[32,16,8,4,2,1]):
su = ScreenUpdater(50)
lastskip = self.xscreensize
quitit = False
for squaresize in sqsizes:
xsquaresize = squaresize
ysquaresize = squaresize

if squaresize == 1:
self.screen.lock()
y = 0
while y <= self.yscreensize:
x = 0
skiprow = y%lastskip == 0
while x <= self.xscreensize:
if skiprow and x%lastskip==0:
x += squaresize
continue

color = (255,255,255)
try:
m = self.func.eval(*self.ct.untranscoord(x, y))
if m >= 0:
if m < 1:
c = 255 * m
color = (0, 0, c)
else:
#c = 255 - 255 * (1.0/m)
#color = (c, c, 255)
c = 255 - 255 * (1.0/m)
color = (c/2.0, c/2.0, 255)

else:
pm = -m
if pm < 1:
c = 255 * pm
color = (c, 0, 0)
else:
c = 255 - 255 * (1.0/pm)
color = (255, c/2.0, c/2.0)
except:
color = (0, 0, 0)

if squaresize > 1:
self.screen.fill(color, (x, y, squaresize, squaresize))
else:
self.screen.set_at((x, y), color)

if su.update():
quitit = True
break

x += xsquaresize

if quitit:
break

y += ysquaresize

if squaresize == 1:
self.screen.unlock()
lastskip = squaresize
if quitit:
break

This is the code which graphs a line through a point:

def _grapheqhelp(self, sx, sy, stepsize, numsteps, color):
x = sx
y = sy
i = 0

pygame.draw.line(self.screen, color, (x, y), (x, y), 2)
while i < numsteps:
lastx = x
lasty = y

try:
m = self.func.eval(x, y)
except:
return

x += stepsize
y = y + m * stepsize

screenx1, screeny1 = self.ct.transcoord(lastx, lasty)
screenx2, screeny2 = self.ct.transcoord(x, y)

#print "(%f, %f)-(%f, %f)" % (screenx1, screeny1, screenx2, screeny2)

try:
pygame.draw.line(self.screen, color,
(screenx1, screeny1),
(screenx2, screeny2), 2)
except:
return

i += 1

stx, sty = self.ct.transcoord(sx, sy)
pygame.draw.circle(self.screen, color, (int(stx), int(sty)), 3, 0)

And it runs backwards & forwards starting from that point:

def graphequation(self, sx, sy, stepsize=.01, color=(255, 255, 127)):
"""Graph the differential equation, given the starting point sx and sy, for length
length using stepsize stepsize."""
numstepsf = (self.xrange[1] - sx) / stepsize
numstepsb = (sx - self.xrange[0]) / stepsize

self._grapheqhelp(sx, sy,  stepsize, numstepsf, color)
self._grapheqhelp(sx, sy, -stepsize, numstepsb, color)

I never got around to drawing actual lines because the pixel approach looked too cool.

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