You want to minimize a differentiable real-valued function `f`

on a smooth hypersurface `S`

. If such a minimum exists - in the situation after the edit it is guaranteed to exist because the hypersurface is compact - it occurs at a critical point of the restriction `f|S`

of `f`

to `S`

.

The critical points of a differentiable function `f`

defined in the ambient space restricted to a manifold `M`

are those points where the gradient of `f`

is orthogonal to the tangent space `T(M)`

to the manifold. For the general case, read up on Lagrange multipliers.

In the case where the manifold is a hypersurface (it has real codimension 1) defined (locally) by an equation `g(x) = 0`

with a smooth function `g`

, that is particularly easy to detect, the critical points of `f|S`

are the points `x`

on `S`

where `grad(f)|x`

is collinear with `grad(g)|x`

.

Now the problem is actually a real (as in concerns the real numbers) problem and not a complex (as in concerning complex numbers) one.

Stripping off the unnecessary imaginary parts, we have

- the hypersurface
`S`

, which conveniently is the unit sphere, globally defined by `(x|x) = 1`

where `(a|b)`

denotes the scalar product `a_1*b_1 + ... + a_k*b_k`

, the gradient of `g`

at `x`

is just `2*x`

- a real linear function
`L(x) = (c|x) = c_1*x_1 + ... + c_k*x_k`

, the gradient of `L`

is `c`

independent of `x`

So there are two critical points of `L`

on the sphere (unless `c = 0`

in which case `L`

is constant), the points where the line through the origin and `c`

intersects the sphere, `c/|c|`

and `-c/|c|`

.

Obviously `L(c/|c|) = 1/|c|*(c|c) = |c|`

and `L(-c/|c|) = -1/|c|*(c|c) = -|c|`

, so the minimum occurs at `-c/|c|`

and the value there is `-|c|`

.

`F`

is complex valued, so do you want to minimize a) the real part, b) the imaginary part, c) the absolute modulus, d) something else? – Daniel Fischer Apr 17 '12 at 12:03