Intuitively, it's not hard to see that `P(X)`

depends on `P(Y)`

. For example, if `P(Y=blue) = 1`

, then

```
P(X) = P(X | Y=blue)
```

(In words, if you know Y is blue, then the probability density plot for `X`

is given by the blue plot you posted).
And similarly, if `P(Y=red) = 1`

, then

```
P(X) = P(X | Y=red)
```

Since `Y`

is a binary class variable, its distribution can be specified by a single probability, `P(Y=blue) = p`

, since that would imply `P(Y=red) = q = 1-p`

.

Given the result above, it's not hard to believe that if `P(Y=blue)`

were something other than 1, that `P(X)`

should be some mixture of `P(X | Y=blue)`

and `P(X | Y=red)`

. In fact,
it makes sense that it should be a linear mixture:

```
P(X) = p * P(X | Y=blue) + q * P(X | Y=red)
```

You can prove that using Bayes' Theorem:

```
P(X) * P(Y=blue | X) = P(Y=blue) * P(X | Y=blue)
P(X) * P(Y=red | X) = P(Y=red) * P(X | Y=red)
```

Adding the two lines together,

```
P(X) * [P(Y=blue | X) + P(Y=red | X)] = P(Y=blue) * P(X | Y=blue) + P(Y=red) * P(X | Y=red)
```

Since `Y`

must be either red or blue, `P(Y=blue | X) + P(Y=red | X)`

must equal 1, so the bracketed expression drops out and you get:

```
P(X) = P(Y=blue) * P(X | Y=blue) + P(Y=red) * P(X | Y=red)
P(X) = p * P(X | Y=blue) + q * P(X | Y=red)
```

don't ask the same question twice. – Anony-Mousse Apr 15 '14 at 7:20