问题
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:
# declare your dy/dx here:
return x**2-x-2
except ZeroDivisionError:
return 1000.0
# Adjust window parameters
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):
print "Error: gnuplot not found on system!"
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?
回答1:
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)
ax=fig.add_subplot(111)
## 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()
回答2:
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.
回答3:
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.
来源:https://stackoverflow.com/questions/18832763/drawing-directions-fields