Heaviside step distribution: Difference between revisions

Latest revision as of 12:12, 5 July 2007

The Heaviside step distribution is defined by (Abramowitz and Stegun Eq. 29.1.3, p. 1020):

H(x)=\left\{{\begin{array}{ll}0&x<0\\{\frac {1}{2}}&x=0\\1&x>0\end{array}}\right.

Note that other definitions exist at $H(0)$ , for example $H(0)=1$ . In the famous Mathematica computer package $H(0)$ is unevaluated.

At first glance things are hopeless:

{\frac {{\rm {d}}H(x)}{{\rm {d}}x}}=0,~x\neq 0

{\frac {{\rm {d}}H(x)}{{\rm {d}}x}}=\infty ,~x=0

however, lets define a less brutal jump in the form of a linear slope such that

H_{\epsilon }(x-a)={\frac {1}{\epsilon }}\left(R(x-(a-{\frac {\epsilon }{2}}))-R(x-(a+{\frac {\epsilon }{2}}))\right)

in the limit $\epsilon \rightarrow 0$ this becomes the Heaviside function $H(x-a)$ . However, lets differentiate first:

{\frac {\rm {d}}{{\rm {d}}x}}H_{\epsilon }(x-a)={\frac {1}{\epsilon }}\left(H(x-(a-{\frac {\epsilon }{2}}))-H(x-(a+{\frac {\epsilon }{2}}))\right)

in the limit this is the Dirac delta distribution. Thus

{\frac {\rm {d}}{{\rm {d}}x}}[H(x)]=\delta (x)

.

@@ Line 4: / Line 4: @@
 H(x) = \left\{
 \begin{array}{ll}
+          &  x < 0 \\
+\frac{1}{2} &  x=0\\
+           &  x > 0
+\end{array} \right.
+</math>
+Note that other definitions exist at <math>H(0)</math>, for example <math>H(0)=1</math>.
+In the famous [http://www.wolfram.com/products/mathematica/index.html Mathematica] computer
+package   <math>H(0)</math> is unevaluated.
+==Applications==
+*[[Fourier analysis]]
+==Differentiating the Heaviside  distribution==
+At first glance things are hopeless:
+:<math>\frac{{\rm d}H(x)}{{\rm d}x}= 0, ~x \neq 0</math>
+:<math>\frac{{\rm d}H(x)}{{\rm d}x}= \infty, ~x = 0</math>
+however, lets define a less brutal jump in the form of a linear slope
+such that
+:<math>H_{\epsilon}(x-a)= \frac{1}{\epsilon}\left( R(x - (a-\frac{\epsilon}{2})) - R (x - (a+\frac{\epsilon}{2}))\right)</math>
+in the limit <math>\epsilon \rightarrow 0</math> this becomes the Heaviside function
+<math>H(x-a)</math>. However, lets differentiate first:
+:<math>\frac{{\rm d}}{{\rm d}x} H_{\epsilon}(x-a)= \frac{1}{\epsilon}\left( H(x - (a-\frac{\epsilon}{2})) - H (x - (a+\frac{\epsilon}{2}))\right)</math>
+in the limit this is the [[Dirac delta distribution]]. Thus
+:<math>\frac{{\rm d}}{{\rm d}x} [H(x)]= \delta(x)</math>.
+==References==
+#[http://store.doverpublications.com/0486612724.html  Milton Abramowitz and  Irene A. Stegun "Handbook of Mathematical Functions" Dover Publications ninth printing.]
+[[category:mathematics]]