Integral Transforms and Applications - Nita H. Shah, Monika K. Naik

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Integral Transforms and Applications (eBook)

Nita H. Shah, Monika K. Naik (Autoren)

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2022
282 Seiten
De Gruyter (Verlag)
978-3-11-079292-8 (ISBN)

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This work presents the guiding principles of Integral Transforms needed for many applications when solving engineering and science problems. As a modern approach to Laplace Transform, Fourier series and Z-Transforms it is a valuable reference for professionals and students alike.

Prof. Dr. Nita H. Shah, Department of Mathematics, School of Sciences, Gujarat University, Ahmedabad, Gujarat-380009, India.

1 Laplace transforms

1.1 Introduction

The Laplace transform, named after its inventor Pierre-Simon Laplace, is an integral transform. Laplace transform converts a function of a real variable (often time) to a function of a complex variable (complex frequency).

Laplace transforms are useful to solve linear ordinary differential equations and analyze frequency response and stability analysis. Process control feedback loops and their response properties and stability can thus be conveniently analyzed in the Laplace domain.

Also, depending on the boundary conditions of your problem, it can be judicious to use a Laplace transform to solve the diffusion equation, heat transfer equation, and Navier–Stokes. So, Laplace transforms will show up in many core engineering curricula, for example, mass transport, heat transport, fluid transport, and process controls. For the basic concepts of Laplace transform and its applications, one can refer to [2–6, 8, 9, 13, 14].

1.2 Definition of Laplace transforms

As we have explained in Introduction, the integral transform of function ft in the interval a≤x≤b is given by,

(1.1)ℓft=∫abKt,sftdt=∘ˆs,

where −∞≤a<b≤∞

Let ft be a function defined for t≥0 0≤t≤∞ and kernel Kt,s=e−st and then eq. (1.1) will be called Laplace transform under certain conditions to be explained later.

Thus, the Laplace transform of function ft which is defined for t≥0 (t is real variable), is formally defined as follows:

Lft=∫0∞e−stftdt=Fs, Res>0

where s is the transform variable, which is a complex number.

Figure 1.1: The Laplace transforms as a mapping.

Therefore, the Laplace transform converts time domain functions and operations into frequency domain ft→Fs t∈R, s∈CasshowninFigure1.1.

1.3 Laplace transform of some elementary functions using definition

Example 1.1

Find the Laplace transform ft=1 for t≥0.

Solution

We know that Lft=∫0∞e−stftdt

Here, ft=1:

∴ Lft=1=∫0∞e−st1dt

⇒L1= e−st−st=0t=∞

⇒L1=1−slimt→∞e−st−1

⇒L1=1−s0−1=1s=Fs Thus, L1=1s, s>0.

Example 1.2

Find the Laplace transform of f(t)=eat for t≥0, where “a” is a constant.

Solution

We know that Lft=∫0∞e−stftdt

Here f(t)=eat

∴Lft=eat=∫0∞e−steatdt

⇒ Leat= ∫0∞e−s−at dt

⇒ Leat= e−s−at−s−at=0t=∞

⇒Leat=1−s−alimt→∞e−s−at−1

⇒Leat=1−s−a0−1=1s−a=Fs

Thus, Leat=1s−a, s>a.

Note: Similarly, Le−at=1s+a, s>−a.

Example 1.3

Find the Laplace transform of ft=sinat, where “a” is a real constant.

Solution

We know that

sinat=eiat−e−iat2i

Now, ft=sinat and Lft= ∫0∞e−stft dt

∴Lft=sinat=∫0∞e−stsinatdt

⇒ Lsinat= ∫0∞e−st eiat−e−iat2i dt

=12i∫0∞e−steiat−e−ste−iatdt=12i∫0∞e−s−iat−e−s+iatdt=12ie−s−iat−s−ia+e−s+iats+iat=0t=∞=12i1s−ia−1s+ia=12is+ia−s+ias−ias+ia=as2−ia2∵i2=−1=as2+a2

Thus, Lsinat=as2+a2.

Example 1.4

Find the Laplace transform of ft=cosat, where “a” is a real constant.

Solution

We know that

cosat=eiat+e−iat2

Now, ft=cosat and Lft=∫0∞e−stft dt ,

∴Lft=cosat=∫0∞e−stcosatdt

Lft=cosat=∫0∞e−stcosatdt⇒Lcosat=∫0∞e−steiat+e−iat2dt=12∫0∞e−steiat+e−ste−iatdt=12∫0∞e−s−iat+e−s+iatdt=12e−s−iat−s−ia−e−s+iats+iat=0t=∞=121s−ia+1s+ia=12s−ia+s+ias−ias+ia=ss2−ia2i2=−1=ss2+a2

Thus, Lcosat=ss2+a2.

1.3.1 Linearity of Laplace transforms

Functions f1t and f2t have Laplace transforms F1s and F2s, respectively.

Also, if c1 and c2 are any constants, then,

Lc1f1t+c2f2t=c1L[f1t+c2Lf2t]=c1F1s+c2F2s

Proof. We know that

{Lft= ∫0∞e−stft dt=Fs

∴Lf1t=∫0∞e−stf1tdt=F1s

Lf2t= ∫0∞e−stf2t) dt=F2s

Now,

Lc1f1t+c2f2t=∫0∞e−stc1f1t+c2f2tdt=∫0∞e−stc1f1t+e−stc2f2tdt=∫0∞e−stc1f1t+e−stc2f2tdt=c1∫0∞e−stf1tdt+c2∫0∞e−stf2tdt=c1L[f1t+c2Lf2t]=c1F1s+c2F2s

Example 1.5

Find the Laplace transform of ft=sinhat, where “a” is a real constant.

Solution

We know that

sinhat=eat−e−at2

Now,

Lsinhat= Leat−e−at2=12Leat−Le−at=12 1s−a−1s+a=12 s+a−s+as−as+a= as2−a2

(by linearity property)

Thus, Lsinhat=as2−a2

Example 1.6

Find the Laplace transform of ft=coshat, where “a” is a real constant.

Solution

We know that

coshat=eat+e−at2

Now,

Lcoshat= Leat+e−at2

=12Leat+Le−at =12 1s−a+1s+a=12 s+a+s−as−as+a=ss2−a2

(by linearity property)

Thus, Lcoshat=ss2−a2.

Note

The gamma function is defined by the improper integral ∫0∞e−xxn−1 dx=|n‾ for n>0
If n is a positive integer, then |n+1‾=n!
|n+1‾=n|n‾
...

Erscheint lt. Verlag	3.10.2022
Reihe/Serie	De Gruyter Series on the Applications of Mathematics in Engineering and Information Sciences
	De Gruyter Series on the Applications of Mathematics in Engineering and Information Sciences
	ISSN
	ISSN
Zusatzinfo	18 b/w and 11 col. ill., 7 b/w tbl.
Sprache	englisch
Themenwelt	Mathematik / Informatik ► Mathematik
	Naturwissenschaften ► Physik / Astronomie
	Technik
Schlagworte	Anwendungen Integrale Transformation • Applications of Integral Transform • Fourier transform • Fourier Transformation • integrale Transformation • integral transform • Laplace-Transform • Laplace-Transformation • Z-Transform • Z-Transformation
ISBN-10	3-11-079292-3 / 3110792923
ISBN-13	978-3-11-079292-8 / 9783110792928

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