There is just one cross (Shannon) entropy defined as:

```
H(P||Q) = - SUM_i P(X=i) log Q(X=i)
```

In machine learning usage, `P`

is the actual (ground truth) distribution, and `Q`

is the predicted distribution. All the functions you listed are just **helper functions** which accepts different ways to represent `P`

and `Q`

.

There are basically 3 main things to consider:

there are either 2 possibles outcomes (binary classification) or more. If there are just two outcomes, then `Q(X=1) = 1 - Q(X=0)`

so a single float in (0,1) identifies the whole distribution, this is why neural network in binary classification has a single output (and so does logistic regresssion). If there are K>2 possible outcomes one has to define K outputs (one per each `Q(X=...)`

)

one either produces proper probabilities (meaning that `Q(X=i)>=0`

and `SUM_i Q(X=i) =1`

or one just produces a "score" and has some fixed method of transforming score to probability. For example a single real number can be "transformed to probability" by taking sigmoid, and a set of real numbers can be transformed by taking their softmax and so on.

there is `j`

such that `P(X=j)=1`

(there is one "true class", targets are "hard", like "this image represent a cat") or there are "soft targets" (like "we are 60% sure this is a cat, but for 40% it is actually a dog").

Depending on these three aspects, different helper function should be used:

```
outcomes what is in Q targets in P
-------------------------------------------------------------------------------
binary CE 2 probability any
categorical CE >2 probability soft
sparse categorical CE >2 probability hard
sigmoid CE with logits 2 score any
softmax CE with logits >2 score soft
sparse softmax CE with logits >2 score hard
```

In the end one could just use "categorical cross entropy", as this is how it is mathematically defined, however since things like hard targets or binary classification are very popular - modern ML libraries do provide these additional helper functions to make things simpler. In particular "stacking" sigmoid and cross entropy might be numerically unstable, but if one knows these two operations are applied together - there is a numerically stable version of them combined (which is implemented in TF).

It is important to notice that if you apply wrong helper function the code will usually still execute, but results will be wrong. For example if you apply softmax_* helper for binary classification with one output your network will be considered to always produce "True" at the output.

As a final note - this answer considers **classification**, it is slightly different when you consider **multi label** case (when a single point can have multiple labels), as then Ps do not sum to 1, and one should use sigmoid_cross_entropy_with_logits despite having multiple output units.