File:Magnetic field of an idealized dipole.svg
Summary
Category:Uploaded with en.wp upload wizard#79878784000001| Description |
English: magnetic field of an idealized dipole |
| Date | |
| Source | python/matplotlib |
| Author | Andre.holzner |
| SVG development | |
| Source code | Python codefrom pylab import *
xpoints = arange(-6,6,0.05)
ypoints = arange(-6,6,0.05)
X,Y = meshgrid(xpoints, ypoints)
circularMask = False
areaRadius = 4
# order of the magnet
n = 1
def func(x,y):
# the function to draw
return ((x + 1j * y)**(n)).real
func = vectorize(func)
V = func(X,Y)
# mask points which we don't want to draw
if circularMask:
# circular mask
distance = sqrt(X**2 + Y**2)
V = ma.masked_where(distance > areaRadius, V)
else:
# polygonal mask
# principal directions are at (i + 0.5) / (2n) * 2pi
#
for i in range(2*n):
angle = (i + 0.5) / float(2*n) * 2*pi
# define a straight angle perpendicular to angle
# mask all points on one side of this line
anchor_x = areaRadius * cos(angle)
anchor_y = areaRadius * sin(angle)
normal_x = cos(angle)
normal_y = sin(angle)
def acceptFunc(x,y):
value = (x - anchor_x) * normal_x + (y - anchor_y) * normal_y
return value > 0
acceptFunc = vectorize(acceptFunc)
V = ma.masked_where(acceptFunc(X,Y), V)
if True:
# levels equidistant in function value
V /= V.max()
levels = arange(-2,2,0.05)
else:
# levels equidistant on x and y axis
# determine the levels to draw from values on one of the axes
levels = [ float(func(x,0)) for x in arange(min(xpoints), max(xpoints),0.50) ] + \
[ float(func(0,y)) for y in arange(min(ypoints), max(ypoints),0.50) ]
levels = sorted(list(set(levels)))
figure(figsize=(6,6));
Q = contour(X,Y, V, colors= 'black', linestyles = 'solid',
levels = levels
)
axis([-5,5,-5,5])
xlabel("x coordinate")
ylabel("y coordinate")
# mask points which we don't want to draw
if not circularMask:
# polygonal mask
# principal directions are at (i + 0.5) / (2n) * 2pi
#
for i in range(2*n):
angle = (i + 0.5) / float(2*n) * 2*pi
if i % 2:
label = "N"
color = 'red'
else:
label = "S"
color = 'green'
anchor_x = 1.1 * areaRadius * cos(angle)
anchor_y = 1.1 * areaRadius * sin(angle)
text(anchor_x, anchor_y, label, size = 20, color = color,
horizontalalignment='center',
verticalalignment='center')
|
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