# using arctan / arctan2 to plot a from 0 to 2π

I am trying to replicate a plot in Orbital Mechanics by Curtis but I just can't quite get it. However, I have made head way by switching to `np.arctan2` from `np.arctan`.

Maybe I am implementing `arctan2` incorrectly?

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

e = np.arange(0.0, 1.0, 0.15).reshape(-1, 1)

nu = np.linspace(0.001, 2 * np.pi - 0.001, 50000)
M2evals = (2 * np.arctan2(1, 1 / (((1 - e) / (1 + e)) ** 0.5 * np.tan(nu / 2) -
e * (1 - e ** 2) ** 0.5 * np.sin(nu) / (1 + e * np.cos(nu)))))

fig2 = pylab.figure()

for Me2, _e in zip(M2evals, e.ravel()):
ax2.plot(nu.ravel(), Me2, label = str(_e))

pylab.legend()
pylab.xlim((0, 7.75))
pylab.ylim((0, 2 * np.pi))
pylab.show()
``````

In the image below, there are discontinuities popping up. The function is supposed to be smooth and connect at 0 and 2 pi in the y range of (0, 2pi) not touching 0 and 2pi.

Textbook plot and equation:

At the request of Saullo Castro, I was told that:

"The problem may lie in the arctan function which gives "principle values" as output.

Thus, arctan(tan(x)) does not yield x if x is an angle in the second or third quadrant. If you plot arctan(tan(x)) from x = 0 to x = Pi, you will find that it has a discontinuous jump at x = Pi/2.

For your case, instead of writing arctan(arg), I believe you would write arctan2(1, 1/arg) where arg is the argument of your arctan function. That way, when arg becomes negative, arctan2 will yield an angle in the second quadrant rather than the fourth."

-
To use arctan2 correctly, you need an equation for x, and an equation for y. The whole point of arctan2 is that the ratio y/x is ambiguous about the quadrant: -/- == +/+ and -/+ == +/-. If you put in y as a constant, you can still only occupy two quadrants in the result. So what you're saying doesn't make sense: this can't both be the equation and fill the quadrants you say. (Since all you're saying now is "I have this equation and it doesn't work", we don't have enough info to answer this and it's not a question that can be answered.) –  tom10 May 17 '13 at 17:02
great! note that in the equation from the textbook, the arctan is only over the first term, not the whole equation. –  tom10 May 17 '13 at 17:27
Look at the parenthesis directly right of tan^-1, where's the matching parenthesis. It's after the tan(theta/2), not at the end of the whole equation. In your equation, you're doing the arctan of the whole thing. –  tom10 May 17 '13 at 17:30
I agree with @tom10, it seems like a case of a misplaced closing paren. Or two. –  user629132 May 17 '13 at 20:54
This question should just be closed, imho. It's just a parenthesis typo on the part of the OP, and sheds no light on anything else (especially not arctan vs arctan2 due to the misdirection). Therefore, closed as "too localized". –  tom10 May 17 '13 at 23:40

The common practice is to sum 2*pi in the negative results of `arctan()`, which can be done efficiently. The OP's suggestion to replace arctan(x) by arctan2(1,1/x), despite not yet explained, produces the same results without the need to sum 2*pi. Both are shown below:

``````import pylab
import numpy as np
e = np.arange(0.0, 1.0, 0.15).reshape(-1, 1)
nu = np.linspace(0, 2*np.pi, 50000)
x =  ((1-e)/(1+e))**0.5 * np.tan(nu/2.)
x2 = e*(1-e**2)**0.5 * np.sin(nu)/(1 + e*np.cos(nu))
using_arctan = True
using_OP_arctan2 = False

if using_arctan:
M2evals = 2*np.arctan(x) - x2
M2evals[ M2evals<0 ] += 2*np.pi
elif using_OP_arctan2:
M2evals = 2 * np.arctan2(1,1/x) - x2

fig2 = pylab.figure()