At a local minimum (or maximum) `x`

, the derivative of the target function `f`

vanishes: `f'(x) = 0`

(assuming sufficient smoothness of `f`

).

Gradient descent tries to find such a minimum `x`

by using information from the first derivative of `f`

: It simply follows the steepest descent from the current point. This is like rolling a ball down the graph of `f`

until it comes to rest (while neglecting inertia).

Newton's method tries to find a point `x`

satisfying `f'(x) = 0`

by approximating `f'`

with a linear function `g`

and then solving for the root of that function explicitely (this is called Newton's root-finding method). The root of `g`

is not necessarily the root of `f'`

, but it is under many circumstances a good guess (the Wikipedia article on Newton's method for root finding has more information on convergence criteria). While approximating `f'`

, Newton's method makes use of `f''`

(the curvature of `f`

). This means it has higher requirements on the smoothness of `f`

, but it also means that (by using more information) it often converges faster.