13.1 FOURIER TRANSFORMS
The derivative of the delta function,δ′(t), is defined by∫∞−∞f(t)δ′(t)dt=[
f(t)δ(t)]∞−∞−∫∞−∞f′(t)δ(t)dt=−f′(0), (13.19)and similarly for higher derivatives.
For many practical purposes, effects that are not strictly described by aδ-function may be analysed as such, if they take place in an interval much shorter
than the response interval of the system on which they act. For example, the
idealised notion of an impulse of magnitudeJapplied at timet 0 can be represented
by
j(t)=Jδ(t−t 0 ). (13.20)Many physical situations are described by aδ-function in space rather than intime. Moreover, we often require theδ-function to be defined in more than one
dimension. For example, the charge density of a point chargeqat a pointr 0 may
be expressed as a three-dimensionalδ-function
ρ(r)=qδ(r−r 0 )=qδ(x−x 0 )δ(y−y 0 )δ(z−z 0 ), (13.21)so that a discrete ‘quantum’ is expressed as if it were a continuous distribution.
From (13.21) we see that (as expected) the total charge enclosed in a volumeV
is given by
∫Vρ(r)dV=∫Vqδ(r−r 0 )dV={
q ifr 0 lies inV,0otherwise.Closely related to the Diracδ-function is theHeavisideorunit step functionH(t), for which
H(t)={
1fort> 0 ,
0fort< 0.(13.22)This function is clearly discontinuous att= 0 and it is usual to takeH(0) = 1/2.
The Heaviside function is related to the delta function by
H′(t)=δ(t). (13.23)