I Show that the integral of the Dirac delta function is equal to 1

[Doitright]

Hi,

I am reading the Quantum Mechanics, 2nd edition by Bransden and Joachain. On page 777, the book gives an example of Dirac delta function.
$\delta_\epsilon (x) = \frac{\epsilon}{\pi(x^2 + \epsilon^2)}$

I am wondering how I can show $\lim_{x\to 0+} \int_{a}^{b} \delta_\epsilon (x) dx$ equals to 1. I've thought about using L'Hospital's rule, but there are two variables, $x$ and $\epsilon$, so seems I cannot use the rule directly. I've been stuck in this for some time. Will be grateful if some one can point the direction for me. Thanks.

 

[PeroK]

Have you tried integrating that function?

 

[Doitright]

I've tried integration, and get $\frac{\arctan(\frac{x}{\epsilon})}{\pi}$. However, seems there is still no way out.

 

[lightarrow]

I've tried integration, and get $\frac{\arctan(\frac{x}{\epsilon})}{\pi}$. However, seems there is still no way out.

I think you shouldn' t make the limit for x-->0+ but for epsilon-->0+.

--
lightarrow

 

[stevendaryl]

I've tried integration, and get $\frac{\arctan(\frac{x}{\epsilon})}{\pi}$. However, seems there is still no way out.

You need to put two dollar-signs around an equation to render it in LaTex:

\$\$\frac{\arctan(\frac{x}{\epsilon})}{\pi}\$\$

renders as:

$$\frac{\arctan(\frac{x}{\epsilon})}{\pi}$$

You basically have the answer there:

\int_{a}^{b} \frac{\epsilon dx}{\pi (\epsilon^2 + x^2)} = \frac{1}{\pi} arctan(\frac{x}{\epsilon})|_a^b = \frac{1}{\pi} (arctan(\frac{a}{\epsilon}) - arctan(\frac{b}{\epsilon}))

In the limit as \epsilon \rightarrow 0, \frac{a}{\epsilon} \rightarrow \pm \infty and \frac{b}{\epsilon} \rightarrow \pm \infty

arctan(+\infty) = \frac{\pi}{2}
arctan(-\infty) = -\frac{\pi}{2}

So if a > 0, you get arctan(\frac{a}{\epsilon}) \rightarrow +\frac{\pi}{2}
If a > 0, you get arctan(\frac{a}{\epsilon}) \rightarrow -\frac{\pi}{2}
So if b > 0, you get arctan(\frac{b}{\epsilon}) \rightarrow +\frac{\pi}{2}
If b > 0, you get arctan(\frac{b}{\epsilon}) \rightarrow -\frac{\pi}{2}

 

[PeroK]

Note also that for any $\epsilon$ you have $\int_{-\infty}^{+\infty} \delta_{\epsilon}(x)dx =1$.

 

[Doitright]

I know how to prove it now. Thanks for the help.