The delta function is a generalized function that can be defined as the limit of a class of delta sequences. The delta function is sometimes called "Dirac's delta function" or the "impulse symbol" (Bracewell 1999). It is implemented in Mathematica as DiracDelta[x].
Formally, 
is a linear
functional from a space (commonly taken as a Schwartz space
S or the space of all smooth functions of compact support D)
of test functions f. The action of on f, commonly denoted 
or 
,
The delta function can be viewed as the derivative of the Heaviside step function,
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(1) |
(Bracewell 1999, p. 94).
The delta function has the fundamental property that
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(2) |
and, in fact,
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(3) |
for 
.
Additional identities include
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(4) |
for 
,
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(5) |
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(6) |
More generally, the delta function of a function of x is given by
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(7) |
where the 
s are the roots of g. For
example, examine
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(8) |
Then 
,
and 
,
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(9) |
The fundamental equation that defines derivatives of the delta function
is
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(10) |
Letting 
in this definition, it follows that
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(11) |
where the second term can be dropped since
, |
(12) |
In general, the same procedure gives
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(13) |
but since any power of x times integrates to 0, it follows that only the constant
term contributes. Therefore, all terms multiplied by derivatives of
f(x) vanish, leaving 
,
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(14) |
which implies
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(15) |
Other identities involving the derivative of the delta function include
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(16) |
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(17) |
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(18) |
where 
denotes convolution,
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(19) |
and
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(20) |
An integral identity involving 
is given by
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(21) |
The delta function also obeys the so-called sifting property
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(22) |
(Bracewell 1999, pp. 74-75).
A Fourier
series expansion of 
gives
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(23) |
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(24) |
so
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(25) |
The delta function is given as a Fourier transform as
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(26) |
Similarly,
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(27) |
(Bracewell 1999, p. 95). More generally, the Fourier transform of the delta function is
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(28) |
The delta function can be defined as as the following limits as
,
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(29) |
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(30) | |
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(31) | |
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(32) | |
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(33) | |
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(34) | |
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(35) |
where
is an Airy function,
is a Bessel
function of the first kind, and 
is a Laguerre
polynomial of arbitrary positive integer order.
The delta function can also be defined by the limit as 
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(36) |
Delta functions can also be defined in two dimensions, so that in two-dimensional Cartesian coordinates
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(37) |
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(38) |
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(39) |
and
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(40) |
Similarly, in polar coordinates,
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(41) |
(Bracewell 1999, p. 85).
In three-dimensional Cartesian coordinates
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(42) |
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(43) |
and
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(44) |
, |
(45) |
, |
(46) |
(Bracewell 1999, p. 85).
A series expansion in cylindrical coordinates gives
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(47) |
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(48) |
Delta
Sequence, Doublet
Function, Fourier
Transform--Delta Function, Generalized
Function, Impulse Symbol,
Poincaré-Bertrand
Theorem, Shah
Function, Sokhotsky's
Formula
http://functions.wolfram.com/GeneralizedFunctions/DiracDelta/,
http://functions.wolfram.com/GeneralizedFunctions/DiracDelta2/
Arfken, G. Mathematical Methods for Physicists, 3rd ed. Orlando, FL: Academic Press, pp. 481-485, 1985.
Bracewell, R. "The Impulse Symbol." Ch. 5 in The Fourier Transform and Its Applications, 3rd ed. New York: McGraw-Hill, pp. 69-97, 1999.
Dirac, P. A. M. Quantum Mechanics, 4th ed. London: Oxford University Press, 1958.
Gasiorowicz, S. Quantum Physics. New York: Wiley, pp. 491-494, 1974.
Papoulis, A. Probability, Random Variables, and Stochastic Processes, 2nd ed. New York: McGraw-Hill, pp. 97-98, 1984.
Spanier, J. and Oldham, K. B. "The Dirac Delta Function
.
van der Pol, B. and Bremmer, H. Operational Calculus Based on the Two-Sided Laplace Integral. Cambridge, England: Cambridge University Press, 1955.
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