When you input a vector `x`

to the net, the net will give an output depend on all the weights (vector `w`

). There would be an error between the output and the true answer. The average error (`e`

) is a function of the `w`

, let's say `e = F(w)`

. Suppose you have one-layer-two-dimension network, then the image of `F`

may look like this:

When we talk about training, we are actually talking about finding the `w`

which makes the minimal `e`

. In another word, we are searching the minimum of a function. **To train is to search**.

So, you question is how to choose the method to search. My suggestion would be: **It depends on how the surface of **`F(w)`

looks like. The wavier it is, the more randomized method should be used, because the simple method based on gradient descending would have bigger chance to guide you trapped by a local minimum - so you lose the chance to find the global minimum. On the another side, if the suface of `F(w)`

looks like a big pit, then forget the genetic algorithm. A simple back propagation or anything based on gradient descending would be very good in this case.

You may ask that **how can I know how the surface look like**? That's a skill of experience. Or you might want to randomly sample some `w`

, and calculate `F(w)`

to get an intuitive view of the surface.