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()
ax2 = fig2.add_subplot(111)
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."

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