There is a strict link between linear regression and logistic regression.

With linear regression you're looking for the k_{i} parameters:

h = k_{0} + Σ k_{i} ˙ X_{i} = K^{t} ˙ X

With logistic regression you've the same aim but the equation is:

h = g(K^{t} ˙ X)

Where `g`

is the sigmoid function:

g(w) = 1 / (1 + e^{-w})

So:

h = 1 / (1 + e^{-Kt ˙ X})

and you need to fit K to your data.

Assuming a binary classification problem, the output `h`

is the estimated probability that the example `x`

is a positive match in the classification task:

P(Y = 1) = 1 / (1 + e^{-Kt ˙ X})

When the probability is greater than 0.5 then we can predict "a match".

The probability is greater than 0.5 when:

g(w) > 0.5

and this is true when:

w = K^{t} ˙ X ≥ 0

The hyperplane:

K^{t} ˙ X = 0

is the decision boundary.

In summary:

- logistic regression is a generalized linear model using the same basic formula of linear regression but it is regressing for the probability of a categorical outcome.

This is a very abridged version. You can find a simple explanation in these videos (third week of *Machine Learning* by Andrew Ng).

You can also take a look at http://www.holehouse.org/mlclass/06_Logistic_Regression.html for some notes on the lessons.

`logistic regression`

is in fact a classification strategy. So its name can be confusing. Why is it called logistic "regression"? Good question - maybe because from the statistics view it's just a generalized linear model that predicts continuous values between`0`

and`1`

, which can be interpreted as`probabilities`

. – cel May 28 '15 at 8:29