# Python: Filling in a gap between two plots

How can I connect two plots at a discontinues point? I have an equation for the point of discontinuity.

``````import numpy as np
import pylab

r1 = 1  #  AU Earth
r2 = 1.524  #  AU Mars
deltanu = 75 * np.pi / 180  #  angle in radians
mu = 38.86984154054163

c = np.sqrt(r1 ** 2 + r2 ** 2 - 2 * r1 * r2 * np.cos(deltanu))

s = (r1 + r2 + c) / 2

am = s / 2

def f(a):
alpha = 2 * np.arcsin(np.sqrt(s / (2 * a)))
beta = 2 * np.arcsin(np.sqrt((s - c) / (2 * a)))
return (np.sqrt(a **3 / mu) * (alpha - beta - (np.sin(alpha)
- np.sin(beta))))

def g(a):
alphag = 2* np.pi - 2 * np.arcsin(np.sqrt(s / (2 * a)))
betag = -2 * np.arcsin(np.sqrt((s - c) / (2 * a)))
return (np.sqrt(a ** 3 / mu)
* (alphag - betag - (np.sin(alphag) - np.sin(betag))))

a = np.linspace(am, 2, 500000)

fig = pylab.figure()
ax.plot(a, f(a), color = '#000000')
ax.plot(a, g(a), color = '#000000')
pylab.xlim((0.9, 2))
pylab.ylim((0, 2))

pylab.show()
``````

The equation that reflects the point is: `dt = np.sqrt(s ** 3 / 8) * (np.pi - betam + np.sin(betam))` where `betam = 2 * np.arcsin(np.sqrt(1 - c / s))` so `dt = 0.5` at `a = s / 2`. However, the gap between the plots looks bigger than a point.

I added: `ax.plot([am, am], [.505, .55], color = '#000000')` which fills in the gap but it feels out of place.

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Are you sure that your `g` function is defined correctly? I find that `g(am)==0.551860976346`, which is not the same as `f(am)==0.5`. –  esmit Jun 24 '13 at 16:13
@esmit according to the book it is. I have re-checked all the equations numerous times. –  dustin Jun 24 '13 at 16:17
Have you rederived the equations yourself? The book could be wrong. What is the physical meaning of the discontinuity? –  esmit Jun 24 '13 at 21:38
@esmit that is where the the time of transfer is the minimum energy transfer. –  dustin Jun 24 '13 at 22:06

It seems as though perhaps you should only be using one value for `betag`:

``````import numpy as np
import matplotlib.pyplot as plt

r1 = 1  #  AU Earth
r2 = 1.524  #  AU Mars
deltanu = 75 * np.pi / 180  #  angle in radians
mu = 38.86984154054163
c = np.sqrt(r1 ** 2 + r2 ** 2 - 2 * r1 * r2 * np.cos(deltanu))
s = (r1 + r2 + c) / 2
am = s / 2

def g(a, alphag, betag):
return (np.sqrt(a ** 3 / mu)
* (alphag - betag - (np.sin(alphag) - np.sin(betag))))

a = np.linspace(am, 2, 500000)

fig, ax = plt.subplots()

alphag = 2 * np.pi - 2 * np.arcsin(np.sqrt(s / (2 * a)))
betag = 2 * np.arcsin(np.sqrt((s - c) / (2 * a)))
ax.plot(a, g(a, alphag, betag), color = 'r')
alphag = 2 * np.arcsin(np.sqrt(s / (2 * a)))
ax.plot(a, g(a, alphag, betag), color = 'r')

plt.show()
``````

yields

I really don't know what's going on here; I found this serendipitously.

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These formulas are based on transfer times in orbital mechanics. `betag` is only when the angle is greater than 180 but less than 360. –  dustin Jun 22 '13 at 15:01
It is great that it works but I believe we should be able to achieve the result with the three equations too. Well at least that is what the book has led me to believe. –  dustin Jun 22 '13 at 15:04
If you overlay the two plots, this plot bottom portion is higher than the original plot. –  dustin Jun 22 '13 at 19:00

`ax.plot([am,am],[f(am),g(am)],color== '#000000')`

-

So I set `beta` and `betag` equal which did the trick. It was supposed to be negative `betag` but that didn't work.

``````def g(a):
alphag = 2* np.pi - 2 * np.arcsin(np.sqrt(s / (2 * a)))
betag = 2 * np.arcsin(np.sqrt((s - c) / (2 * a)))
return (np.sqrt(a ** 3 / mu)
* (alphag - betag - (np.sin(alphag) - np.sin(betag))))

def f(a):
alpha = 2 * np.arcsin(np.sqrt(s / (2 * a)))
beta = 2 * np.arcsin(np.sqrt((s - c) / (2 * a)))
return (np.sqrt(a **3 / mu) * (alpha - beta - (np.sin(alpha)
- np.sin(beta))))
``````

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This is in essence what @unutbu said. If so, you should accept his answer. –  esmit Jun 25 '13 at 16:42
@esmit when I used his solution though, it raised the the lower portion of the plot though something else was also different. –  dustin Jun 25 '13 at 16:49