Suppose I have a function whose range is a scalar but whose domain is a vector. For example:

```
def func(x):
return x[0] + 1 + x[1]**2
```

What's a good way to find ~~the~~ *a* root of this function? `scipy.optimize.fsolve`

and `scipy.optimize.root`

expect `func`

to return a vector (rather than a scalar), and `scipy.optimize.newton`

only takes scalar arguments. I can redefine `func`

as

```
def func(x):
return [x[0] + 1 + x[1]**2, 0]
```

Then `root`

and `fsolve`

can find a root, but the zeros in the Jacobian means it won't always do a good job. For example:

```
fsolve(func, array([0,2]))
=> array([-5, 2])
```

It'll only vary the first parameter but not the second, meaning that it often finds a zero that's far away.

EDIT: it looks like the following redefinition of func works better:

```
def func(x):
fx = x[0] + 1 + x[1]**2
return [fx, fx]
fsolve(func, array([0,5]))
=>array([-16.27342781, 3.90812331])
```

So it's now willing to change both parameters. The code is still kind of ugly though.

theroot. In the generic case, you should expect the set of solutions to`f(x,y)=0`

to be a curve in the`(x,y)`

plane. You need a second function or a constraint if you want a unique solution. – Warren Weckesser Jun 12 '14 at 17:29`scipy.optimize.fsolve`

or`scipy.optimize.root`

. – lnmaurer Jun 12 '14 at 17:33