No that's not possible, *unless* (maybe) you start using some rather strange, unusual activation functions.

Let's first ignore neuron 2, and pretend that neuron 1 is the output node. Let `x0`

denote the bias value (always `x0 = 1`

), and `x1`

and `x2`

denote the input values of an example, let `y`

denote the desired output, and let `w1, w2, w3`

denote the weights from the `x's`

to neuron 1. With the XOR problem, we have the following four examples:

`x0 = 1, x1 = 0, x2 = 0, y = 0`

`x0 = 1, x1 = 1, x2 = 0, y = 1`

`x0 = 1, x1 = 0, x2 = 1, y = 1`

`x0 = 1, x1 = 1, x2 = 1, y = 0`

Let `f(.)`

denote the activation function of neuron 1. Then, assuming we can somehow train our weights to solve the XOR problem, we have the following four equations:

`f(w0 + x1*w1 + x2*w2) = f(w0) = 0`

`f(w0 + x1*w1 + x2*w2) = f(w0 + w1) = 1`

`f(w0 + x1*w1 + x2*w2) = f(w0 + w2) = 1`

`f(w0 + x1*w1 + x2*w2) = f(w0 + w1 + w2) = 0`

Now, the main problem is that activation functions that are typically used (ReLUs, sigmoid, tanh, idendity function... maybe others) are nondecreasing. That means that if you give it a larger input, you also get a larger output: `f(a + b) >= f(a)`

if `b >= 0`

. If you look at the above four equations, you'll see this is a problem. Comparing the second and third equations to the first tell us that `w1`

and `w2`

need to be positive because they need to increase the output in comparison to `f(w0)`

. But, then the fourth equation won't work out because it will give an even greater output, instead of `0`

.

I think (but didn't actually try to verify, maybe I'm missing something) that it would be possible if you use an activation function that goes up first and then down again. Think of something like `f(x) = -(x^2)`

with some extra term to shift it away from the origin. I don't think such activation functions are commonly used in neural networks. I suspect they'll behave less nicely when training, and are not plausible from a biological point of view (remember than neural networks are at least inspired by biology).

Now, in your question you also added an extra link from neuron 1 to neuron 2, which I ignored in the discussion above. The problem here is still the same though. The activation level in neuron 1 is always going to be higher than (or at least as high as) the second and third cases. Neuron 2 would typically again have a nondecreasing activation function, so would not be able to change this (unless you put a negative weight between the hidden neuron 1 and output neuron 2, in which case you flip the problem around and will predict too high a value for the first case)

EDIT: Note that this is related to Aaron's answer, which is essentially also about the problem of nondecreasing activation functions, just using more formal language. Give him an upvote too!

`I know that an artificial neural network (ANN) of 3 neurons in 2 layers can solve XOR`

Could you provide a sketch of (or reference for) that solution?`But to minify this ANN, can just 2 neurons solve XOR?`

(minimise?) layered or non-layered? – greybeard Jan 18 '17 at 6:51