A function, eh?

Not a proper function, in the strict sense, but very useful all the same. It is defined by its properties when integrated.

Definition: The Dirac delta function δ(x) satisfies (integral) δ(x) dx = 1 if the range of integration includes zero, =0 if not.

Take a moment to convince yourself that no R->R function satisfies this. Note that for any function continious at zero, (integral) f(x)δ(x) dx = f(0).

What use is it?

The neatest way to convince yourself of its necessity is to think of it as a continuum generalisation of the Kronecker delta symbol:

(sum) f_iδ_ij = f_j
(integral) f(x)δ(x) dx = f(0)

As such, the notion of orthonormal eigenstates in Dirac's own formalism can be gerneralise from the discrete eigenvalue case to the continious case:

<i|j> = δ_ij becomes
<x|y> = δ(x-y)

...which you need for such continious eigenvalues such as position and momentum. This, and the above stated property, make the sum-over-all-intermediate-states rule work out as it should:

|x> = (integral) |y><y|x> dy

Generalisation to Rⁿ:

Definition: δ⁽ⁿ⁾(x) = δ(x₁)δ(x₂)...δ(x_n)

...and then if you integrated this over some (n)volume, the result is 1 if zero is in the volume, 0 otherwise.