Just adding this clarification so that anyone who scrolls down this much can at least gets it right, since there are so many wrong answers upvoted.

Diansheng's answer and JakeJ's answer get it right.

A new answer posted by Shital Shah is an even better and more complete answer.

Yes, `logit`

as a mathematical function in statistics, **but the **`logit`

used in context of neural networks is different. Statistical `logit`

doesn't even make any sense here.

I couldn't find a formal definition anywhere, but `logit`

basically means:

The raw predictions which come out of the last layer of the neural network.

1. This is the very tensor on which you apply the `argmax`

function to get the predicted class.

2. This is the very tensor which you feed into the `softmax`

function to get the probabilities for the predicted classes.

Also, from a tutorial on official tensorflow website:

### Logits Layer

The final layer in our neural network is the logits layer, which will return the raw values for our predictions. We create a dense layer with 10 neurons (one for each target class 0–9), with linear activation (the default):

```
logits = tf.layers.dense(inputs=dropout, units=10)
```

If you are still confused, the situation is like this:

```
raw_predictions = neural_net(input_layer)
predicted_class_index_by_raw = argmax(raw_predictions)
probabilities = softmax(raw_predictions)
predicted_class_index_by_prob = argmax(probabilities)
```

where, `predicted_class_index_by_raw`

and `predicted_class_index_by_prob`

will be equal.

**Another name for **`raw_predictions`

in the above code is `logit`

.

~~As for the ~~**why** `logit`

... I have no idea. Sorry.

[Edit: See this answer for the historical motivations behind the term.]

## Trivia

Although, if you want to, you can apply statistical `logit`

to `probabilities`

that come out of the `softmax`

function.

If the probability of a certain class is `p`

,

Then the **log-odds** of that class is `L = logit(p)`

.

Also, the probability of that class can be recovered as `p = sigmoid(L)`

, using the `sigmoid`

function.

Not very useful to calculate log-odds though.