Questions tagged [dirac-delta]

This tag is for questions involving the Dirac delta function, either in the informal sense, or in the distribution sense. The Dirac delta function is a mathematical construct which is called a generalized function or a distribution and was originally introduced by the British theoretical physicist Paul Dirac.

Mathematically, the delta function is not a function, because it is too singular. Instead, it is said to be a “distribution.” It is a generalized idea of functions, but can be used only inside integrals.

In fact, $~\int \delta~(x)~dx~$ can be regarded as an “operator” which pulls the value of a function at zero. Put it this way, it sounds perfectly legitimate and well-defined. But as long as it is understood that the delta function is eventually integrated, we can use it as if it is a function.

Definition: The Dirac delta function or, delta function $~(~\delta~(x)~)~$ is defined by the properties $$\delta~(x) = \begin{cases} 0 \quad \text{if} \ x\not=0\\ \infty \quad \text{if} \ x=x\end{cases}\qquad \text{and}\qquad \int_0^1 \delta~(x)~dx=1$$

This function is very useful as an approximation for a tall narrow spike function, namely an impulse. For example, to calculate the dynamics of a baseball being hit by a bat, approximating the force of the bat hitting the baseball by a delta function is a useful device. The delta function not only enables the equations to be simplified, but it also allows the motion of the baseball to be calculated by only considering the total impulse of the bat against the ball, rather than requiring the details of how the bat transferred energy to the ball.

There are three main properties of the Dirac Delta function that we need to be aware of. These are,

$1.\quad$ $$~\delta \left( {t - a} \right) = 0~~~~~~~t \ne a~$$ $2.\quad$ $$~\displaystyle \int_{{a - \varepsilon }}^{{ a + \varepsilon }}{{\delta \left( {t - a} \right)~dt}} = 1,\hspace{0.25in}\varepsilon > 0~$$ $3.\quad$ $$~\displaystyle \int_{{ a - \varepsilon }}^{{ a + \varepsilon }}{{f\left( t \right)\delta \left( {t - a} \right)~dt}} = f\left( a \right),\hspace{0.25in}~~~~~~~~~~\varepsilon > 0~$$

References:

https://en.wikipedia.org/wiki/Dirac_delta_function

http://mathworld.wolfram.com/DeltaFunction.html

2057 questions
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derivative of a step function to produce a dirac delta

Let $\theta\left(x\right)$be the step function $\theta\left(x\right)\equiv\begin{cases}1 & if \ x>0\\0 & if\ x<0 \end{cases}$ In the rare case where it actually matters, we define $\theta\left(0\right)=\frac{1}{2}$ Show that…
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What is the proof of the formula for $\delta(g(x))$?

Consider a function $g(x)$ such that the delta-function is given by $\delta(g(x))$, with $g(x)=0$ at $x_i$. Then we have that $$\sum_i=\frac{\delta(x-x_i)}{|g(x_i)|}.$$ Can someone suggest me a page with a good proof or show me the proof themselves?…
ODP
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Intuition behind area of the Dirac delta function

Background to my question: I'm taking a signals and systems course where we are using the Dirac delta function, but since it's an engineering course the explanation of what it actually is has been very hand-wavy with just enough for us to be able to…
Austin
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How to solve integral of formula consisting of derivative of the delta function.

The question is $$ \int ^4 _{-4} (t-2)^2\delta'\left(-\frac13t+\frac12\right)dt $$ The solution of the text book is \begin{align} \int ^4 _{-4} (t-2)^2\delta'\left(-\frac13t+\frac12\right)dt &=\int ^4 _{-4} 3(t-2)^2\delta'\left(t-\frac32\right)dt…
Danny_Kim
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Could someone explain derivatives of delta function?

I am studying Signals and Systems. The textbook told me $\delta'(t)$ has the following properties. $1$. $x(t)\delta'(t-t_0)=x(t_0)\delta'(t-t_0)-x'(t_0)\delta(t-t_0)$ $2$. $\displaystyle\int_{-\infty}^t\delta'(\tau-t_0)d\tau=\delta(t-t_0)$ $3$.…
Danny_Kim
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Product of 2 dirac delta functions

Solve for a parabolic diff. eq: $$ \frac{\partial{}G(x,t)}{\partial{}t}=a\frac{\partial{}^2G(x,t)}{\partial{}x^2}+\delta(t)\delta(x)$$ Using the result, write the general solution…
Jackson Hart
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Delta function with different variables

How can I deal with something like that: $\int\int\int dx dydz \delta(E-E_0+x^2+y^2+z^2)$ I could substitue $x^2\rightarrow a$ and do the first integral, but the the delta function vanishes? Best
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Dividing multivariable Dirac delta function by single variable delta

How can I divide $\frac{\frac{1}{8}\delta (x-0,y-0) + \frac{1}{4}\delta (x-2,y-0) + \frac{3}{8}\delta(x-0, y-4) + \frac{1}{4}\delta (x-2,y-4)}{\frac{1}{2}\delta(x-0) + \frac{1}{2}\delta (x-2)}$?
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How does one approximate a real function as a sum of delta functions?

As a physicist, I have frequently encountered the argument that a function may be approximated as a sum of delta functions. However, the exact correspondence is never given. What is it? My attempt yields the following equation: $$f(x) \approx…
DanielSank
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dirac delta definition equivalent

in below link, (formula (34)-(40)) there are some definition of Dirac delta function in terms of other functions such as Airy function, Bessel function of the first kind, Laguerre polynomial,.... http://mathworld.wolfram.com/DeltaFunction.html Is…
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How to show these functions visualize dirac delta function?

I'm having trouble understanding what this question is trying to ask me. I understand the "limiting case of the rectangular function" but I don't see how I can show that the following functions satisfy the same requirement. Here is the problem: The…
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How to express the concentrated Force at the center of a circular domain into a distributed pressure with the help of Dirac Delta?

Background: the beam case (1D) For a beam bearing concentrated froce $P$ at the middle, the concentrated force $P$ can be expressed in a distributed manner, i.e., $$ q=P\delta(r) $$ such that the line integration $$ \int_{-L}^Lqdx=P $$ The…
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Rewriting the multi-dimensional Dirac delta function

Consider the $d$-dimensional delta function $\delta^{(d)}(x)\equiv\prod_{i=1}^d\delta(x^i)$. Since $$ x^i=0,~\forall i\iff \sum_i(x^i)^2=0 $$ it should be possible to write $$ \delta^{(d)}(x)=f(x)\delta(r) $$ where $r=\sqrt{\sum_i(x^i)^2}$. My…
dennis
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Approximating Delta distribution with an Exponential

Is it alright to approximate a Delta distribution with an exponential like this: $$\delta(x-1) = \omega\,e^{-\omega (x-1)}, \hspace{1cm} x \geq 1,$$ where, $\omega \gg 1 $, and, $$\int_1^{\infty} f(x)\,\delta(x-1) = f(1).$$ Also, what are the…
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Squarable but not differentiable delta function

How much the Fourier analysis and the theory of Laplace transforms would be different if we assumed Dirac Delta to be a function $\overline{\delta}(x)$ rather than distribution $\delta(x)$, in other words, a function such that at zero it takes some…
Anixx
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