What are the mathematical properties of natural exponential function that lead to its usefulness in artificial intelligence?

Question

In mathematics, there is a proof that the following infinite series converges to a constant irrational number, denoted by $e$, called as Euler's number or Euler's constant or Napier's constant. The value of $e$ lies between 2 and 3.

$$1 + \dfrac{1}{1!} + \dfrac{1}{2!} + \dfrac{1}{3!} + \cdots$$

The natural exponential function, defined as follows, has some interesting properties

$$f: \mathbb{R} \rightarrow \mathbb{R}$$ $$f(x) = e^x$$

It is used in several algorithms and in the definitions of functions like SoftMax. I am interested in knowing the possible mathematical characteristics that lead this function useful in artificial intelligence.

The following are the properties I am aware of. But, I am not sure about how some of them will be useful

1. Non-linearlity: Activation functions are intended to provide non-linearity. So, it is a candidate for activation functions due to this property. You can check its graph here.

2. Differentiability: Loss functions used for in back-propagation algorithm need to be differentiable. So, it can be a candidate for usage in loss functions too.

$$\dfrac{d}{dx} e^x = e^x \text{ for all } x \in \mathbb{R}$$

3. Continuity: I am not sure how this property is useful in algorithms. Intuitively, you can check from graph provided above that it is continuous.

4. Smoothness: I am not sure how this property is useful in algorithms. But seems useful. The natural exponential function has the smoothness property.

$$\dfrac{d^n}{d^nx} e^x = e^x \text{ for all } x \in \mathbb{R} \text{ and } n \in \mathbb{N}$$.

Are there any other properties like non-linearily, differentiability, smoothness etc., for the natural exponential function that make it superior to use in AI algorithms?

Answer 1

The question must be split in two:

Use in softmax: softmax is based in the concept of cross entropy, logistic regression, logistic function ... . All these concepts includes exponential or logarithmic in its formulation.

Use in activation functions:

• monotonic: a non-monotonic function will give same output to different inputs, disturbing the concept of distance/error.
• non-linear: a linear activation function collapses the layer with the next one, thus, it is useless.
• differentiable: necessary to use back-propagation.

Answer 2

While all the properties you list are true, the essential parts are the Differentiability and the fact that you build a nice probability distribution from it.

The unnormalized scores the neural network puts out before we apply softmax to them may very well contain negative values. Applying the exponential function is a great way to build a probability distribution from a given vector, disregarding the sign of the values.