Use Newton-Raphson via scipy.optimize.newton. It finds roots of an equation, i.e., values of *x* for which f(*x*) = 0. In the example, you can cast the problem as looking for a root of the function f(*x*) = *x*² - *y*. If you supply a lambda that computes *y*, you can provide a general solution thus:

```
def inverse(f, f_prime=None):
def solve(y):
return newton(lambda x: f(x) - y, 1, f_prime, (), 1E-10, 1E6)
return solve
```

Using this function is quite simple:

```
>>> sqrt = inverse(lambda x: x**2)
>>> sqrt(2)
1.4142135623730951
>>> import math
>>> math.sqrt(2)
1.4142135623730951
```

Depending on the input function, you may need to tune the parameters to `newton()`

. The current version uses a starting guess of 1, a tolerance of 10^{-10} and a maximum iteration count of 10^{6}.

For an additional speed-up, you can supply the derivative of the function in question:

```
>>> sqrt = inverse(lambda x: x**2, lambda x: 2*x)
```

In fact, without it, the function actually uses the secant method instead of Newton-Raphson, which relies on knowing the derivative.