Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

INTEGRAL TRANSFORMS


13.18 The equivalent duration and bandwidth,TeandBe, of a signalx(t) are defined
in terms of the latter and its Fourier transform ̃x(ω)by


Te=

1


x(0)

∫∞


−∞

x(t)dt,

Be=

1


̃x(0)

∫∞


−∞

x ̃(ω)dω,

where neitherx(0) nor ̃x(0) is zero. Show that the productTeBe=2π(this is a
form of uncertainty principle), and find the equivalent bandwidth of the signal
x(t)=exp(−|t|/T).
For this signal, determine the fraction of the total energy that lies in the frequency
range|ω|<Be/4. You will need the indefinite integral with respect toxof
(a^2 +x^2 )−^2 ,whichis
x
2 a^2 (a^2 +x^2 )

+


1


2 a^3

tan−^1

x
a

.


13.19 Calculate directly theauto-correlation functiona(z) for the productf(t)ofthe
exponential decay distribution and the Heaviside step function,


f(t)=

1


λ

e−λtH(t).

Use the Fourier transform and energy spectrum off(t) to deduce that
∫∞

−∞

eiωz
λ^2 +ω^2

dω=

π
λ

e−λ|z|.

13.20 Prove that the cross-correlationC(z) of the Gaussian and Lorentzian distributions


f(t)=

1


τ


2 π

exp

(



t^2
2 τ^2

)


,g(t)=

(a

π

) 1


t^2 +a^2

,


has as its Fourier transform the function
1

2 π

exp

(



τ^2 ω^2
2

)


exp(−a|ω|).

Hence show that

C(z)=

1


τ


2 π

exp

(


a^2 −z^2
2 τ^2

)


cos

(az

τ^2

)


.


13.21 Prove the expressions given in table 13.1 for the Laplace transforms oft−^1 /^2 and
t^1 /^2 , by settingx^2 =tsin the result
∫∞


0

exp(−x^2 )dx=^12


π.

13.22 Find the functionsy(t) whose Laplace transforms are the following:


(a) 1/(s^2 −s−2);
(b) 2s/[(s+1)(s^2 + 4)];
(c) e−(γ+s)t^0 /[(s+γ)^2 +b^2 ].

13.23 Use the properties of Laplace transforms to prove the following without evaluat-
ing any Laplace integrals explicitly:
(a) L


[


t^5 /^2

]


=^158



πs−^7 /^2 ;
(b)L

[


(sinhat)/t

]


=^12 ln

[


(s+a)/(s−a)

]


,s>|a|;
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