Astronomy software predicts the location of the Sun by taking JPL predictions of where the Earth and Sun will be, which the JPL expresses as a series of polynomials that cover specific ranges of dates. Asking “when will the sun be at azimuth *z*?” is asking when three different polynomials, that are each varying at a different rate (the polynomial for the Sun, for the Earth-Moon barycenter revolving around the Sun, and the Earth revolving around the barycenter), will happen to bring the difference between the two positions to precisely a certain angle.

And, it turns out, that problem falls into the class of “gross” math problems — or, as professionals say, “non-closed-form-solution problems.” But I like your word “gross” because it catches very well how most of us feel when we discover that much of the world has to be tackled by trial-and-error instead of just giving us an answer.

Fortunately, a vast enough swatch of science is “gross” in this sense that there are standard ways of asking “when will this big complicated function reach exactly value *z*?” If you are able to install and try out SciPy, the increasingly popular science library for Python, you will find that it has a whole collection of routines that sneak up on solutions, each using a different tactic. The other answerer has already identified one such tactic — halving the search space with each trial — but that is generally the slowest (though in some extreme cases, the safest) approach; here are some others:

http://docs.scipy.org/doc/scipy/reference/optimize.html

Create a little function that returns “how far off” the Sun's azimuth is a time `t`

from the azimuth you want, where the function will finally return zero when the azimuth is exactly right, like:

```
def f(t):
...
return desired_az - sun.az
```

Then try out one of the “root finding scalar functions” from that SciPy page. The `bisect()`

function will, just like the other answerer suggests, keep cutting the search space in half to narrow things down. But my guess is that you'll find a Newton's method to be far less “gross” and far faster — try `newton()`

or `brentq()`

, and see what happens!