8.1: Introduction to the Laplace Transform (2024)

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    Definition of the Laplace Transform

    This is Paul Seeburger's version of this Section.

    This is my favorite function: \( f(x) =\dfrac{1}{\sqrt{x^2 + 9}} \)

    \[ f(x) = x^3 - \sin x\]

    To define the Laplace transform, we first recall the definition of an improper integral. If \(g\) is integrable over the interval \([a,T]\) for every \(T>a\), then the improper integral of \(g\) over \([a,\infty)\) is defined as

    \[\label{eq:8.1.1} \int^\infty_a g(t)\,dt=\lim_{T\to\infty}\int^T_a g(t)\,dt.\]

    We say that the improper integral converges if the limit in Equation \ref{eq:8.1.1} exists; otherwise, we say that the improper integral diverges or does not exist. Here’s the definition of the Laplace transform of a function \(f\).

    Definition 8.1.1: Laplace Transform

    Let \(f\) be defined for \(t\ge0\) and let \(s\) be a real number. Then the Laplace transform of \(f\) is the function \(F\) defined by

    \[\label{eq:8.1.2} F(s)=\int_0^\infty e^{-st} f(t)\,dt,\]

    for those values of \(s\) for which the improper integral converges.

    It is important to keep in mind that the variable of integration in Equation \ref{eq:8.1.2} is \(t\), while \(s\) is a parameter independent of \(t\). We use \(t\) as the independent variable for \(f\) because in applications the Laplace transform is usually applied to functions of time.

    The Laplace transform can be viewed as an operator \({\mathscr L}\) that transforms the function \(f=f(t)\) into the function \(F=F(s)\). Thus, Equation \ref{eq:8.1.2} can be expressed as

    \[F={\mathscrL}(f).\nonumber \]

    The functions \(f\) and \(F\) form a transform pair, which we’ll sometimes denote by

    \[f(t)\leftrightarrow F(s).\nonumber\]

    It can be shown that if \(F(s)\) is defined for \(s=s_0\) then it is defined for all \(s>s_0\) (Exercise 8.1.14b).

    Computation of Some Simple Laplace Transforms

    Example 8.1.1

    Find the Laplace transform of \(f(t)=1\).

    Solution

    From Equation \ref{eq:8.1.2} with \(f(t)=1\),

    \[F(s)=\int_0^\infty e^{-st}\,dt=\lim_{T\to\infty}\int_0^T e^{-st}\, dt.\nonumber\]

    If \(s\ne 0\) then

    \[\label{eq:8.1.3} \int_0^T e^{-st}dt=-{1\over s}e^{-st}\Big|_0^T={1-e^{-sT}\over s}.\]

    Therefore

    \[\label{eq:8.1.4} \lim_{T\to\infty}\int_0^T e^{-st}dt=\lim_{T\to\infty} {1-e^{-sT}\over s}=\left\{\begin{array}{rr} {1\over s}, & \text{if }s>0,\\ \infty, & \text{if }s<0. \end{array}\right.\]

    If \(s=0\) the integrand reduces to the constant \(1\), and

    \[\lim_{T\to\infty}\int_0^T 1\,dt=\lim_{T\to\infty}\int_0^T 1\,dt= \lim_{T\to\infty}T=\infty.\nonumber\]

    Therefore \(F(0)\) is undefined, and

    \[F(s)=\int_0^\infty e^{-st}dt={1\over s},\quad s>0.\nonumber\]

    This result can be written in operator notation as

    \[{\mathscr L}(1)={1\over s},\quad s>0,\nonumber\]

    or as the transform pair

    \[1\leftrightarrow{1\over s},\quad s>0.\nonumber\]

    Example 8.1.2

    Find the Laplace transform of \(f(t)=t\).

    From Equation \ref{eq:8.1.2} with \(f(t)=t\),

    \[\label{eq:8.1.5} F(s)=\int_0^\infty e^{-st}t\,dt = \lim_{T\to\infty}\int_0^T e^{-st}t\, dt.\]

    If \(s\ne0\), integrating by parts with

    \[\begin{array}{ll} u = t & dv = e^{-st}\,dt \\ du = dt & v = {-1 \over s} e^{-st}\end{array} \nonumber\]

    yields

    \[\begin{align*} \int_0^Te^{-st}t\,dt&=-{te^{-st}\over s}\bigg|_0^T+{1\over s}\int_0^Te^{-st}\,dt \\[5pt]
    &=-\left[{t\over s}+{1\over s^2}\right]e^{-st}\bigg|_0^T\\[5pt]
    &=-\left[{T\over s}+{1\over s^2}\right]e^{-sT} +\left[{0\over s}+{1\over s^2}\right]e^{0}\\[5pt]
    &={1\over s^2} -\left[{T\over s}+{1\over s^2}\right]e^{-sT}\end{align*}\nonumber\]

    Then if \(s>0,\) we have

    \[\begin{align*} F(s)&=\int_0^\infty e^{-st}t\,dt = \lim_{T\to\infty}\int_0^T e^{-st}t\, dt\\[4pt]
    &= \lim_{T\to\infty} \bigg({1\over s^2} -\left[{T\over s}+{1\over s^2}\right]e^{-sT} \bigg)\\[4pt]
    &=\lim_{T\to\infty} \bigg({1\over s^2} -\frac{T}{s e^{sT}}-{1\over s^2}e^{-sT} \bigg)\\[4pt]
    &=\lim_{T\to\infty}{1\over s^2} -\lim_{T\to\infty}\frac{T}{s e^{sT}}-\lim_{T\to\infty}\frac{1}{s^2}e^{-sT} \\[4pt]
    &={1\over s^2} -\lim_{T\to\infty}\cancelto{\infty/\infty}{\frac{T}{s e^{sT}}}-\quad\lim_{T\to\infty}{\cancelto{0}{\frac{1}{s^2e^{sT}}}} \end{align*}\]

    Since the middle term is in theindeterminate form \(\infty/\infty,\) we useL'Hôpital's rule to determine this limit:

    \[\begin{align*} F(s) &={1\over s^2} -\lim_{T\to\infty}\frac{T}{s e^{sT}}\\[4pt]
    &= {1\over s^2} -\lim_{T\to\infty}\cancelto{0}{\frac{1}{s^2 e^{sT}}} & & \text{We applyL'Hôpital's rule in this step.}\\[4pt]
    &={1\over s^2} \end{align*}\]

    If instead we assume that \(s<0,\) we have

    \[\begin{align*} F(s)&=\int_0^\infty e^{-st}t\,dt = \lim_{T\to\infty}\int_0^T e^{-st}t\, dt\\[4pt]
    &= \lim_{T\to\infty} \bigg({1\over s^2} -\left[{T\over s}+{1\over s^2}\right]e^{-sT} \bigg)\\[4pt]
    &= \lim_{T\to\infty}{1\over s^2} -\lim_{T\to\infty} \left[\frac{Ts+1}{s^2}\right]e^{-sT} \\[4pt]
    &={1\over s^2} -\lim_{T\to\infty} \cancelto{-\infty\cdot\infty}{\left[\frac{Ts+1}{s^2}\right]e^{-sT}} & & \text{Note that}e^{-sT}\to\infty\text{ as }T\to\infty,\text{ since }s<0.\\[4pt]
    &={1\over s^2} - (-\infty) \; =\; \infty\end{align*}\]

    Thus we can conclude that \[ F(s)=\left\{\begin{array}{rr} \dfrac{1}{s^2},&\text{if }s>0,\\ \infty,&\text{if }s<0.\end{array}\right.\nonumber\]

    If \(s=0\),Equation \ref{eq:8.1.5} becomes

    \[\begin{align*} F(0)&=\int_0^\infty e^{-st}t\,dt =\int_0^\infty t\,dt \\[4pt]
    &=\lim_{T\to\infty}\int_0^T t\, dt= \lim_{T\to\infty} \left(\,{t^2\over2}\bigg|_0^T \,\right)\\[4pt]
    &= \frac{1}{2}\lim_{T\to\infty} \left(T^2 - 0\right) = \infty. \end{align*}\]

    Therefore \(F(0)\) is undefined and

    \[F(s)={1\over s^2},\quad s>0.\nonumber\]

    This result can also be written as

    \[{\mathscr L}(t)={1\over s^2},\quad s>0,\nonumber\]

    or as the transform pair

    \[t\leftrightarrow{1\over s^2},\quad s>0.\nonumber\]

    Example 8.1.3

    Find the Laplace transform of \(f(t)=e^{at}\), where \(a\) is a constant.

    From Equation \ref{eq:8.1.2} with \(f(t)=e^{at}\),

    \[F(s)=\int_0^\infty e^{-st}e^{at}\,dt.\nonumber\]

    Combining the exponentials yields

    \[F(s)=\int_0^\infty e^{-(s-a)t}\,dt.\nonumber\]

    However, we know from Example 8.1.1 that

    \[\int_0^\infty e^{-st}\,dt={1\over s},\quad s>0.\nonumber\]

    Replacing \(s\) by \(s-a\) here shows that

    \[F(s)={1\over s-a},\quad s>a.\nonumber\]

    This can also be written as

    \[{\mathscr L}(e^{at})={1\over s-a},\quad s>a, \text{ or } e^{at}\leftrightarrow{1\over s-a},\quad s>a.\nonumber\]

    Example 8.1.4

    Find the Laplace transforms of \(f(t)=\sin\omega t\) and \(g(t)=\cos\omega t\), where \(\omega\) is a constant.

    Define

    \[\label{eq:8.1.6} F(s)=\int_0^\infty e^{-st}\sin\omega t\,dt\]

    and

    \[\label{eq:8.1.7} G(s)=\int_0^\infty e^{-st}\cos\omega t\,dt.\]

    If \(s>0\), integrating Equation \ref{eq:8.1.6} by parts with

    \[\begin{array}{ll} u = \sin\omega t & dv = e^{-st}dt \\ du = \omega\cos\omega t & v = -\dfrac{e^{-st}}{s} \end{array} \nonumber\]

    yields

    \[\begin{align*} F(s) &= \int_0^\infty e^{-st}\sin\omega t\,dt = \lim_{T\to\infty}\int_0^T e^{-st}\sin\omega t\,dt \\[4pt]
    &=\lim_{T\to\infty} \bigg[ -{e^{-st}\over s}\sin\omega t\Big|_0^T+{\omega\over s} \int_0^T e^{-st}\cos\omega t\,dt \bigg] \\[4pt]
    &=\lim_{T\to\infty} \bigg[ -\cancelto{0}{{e^{-sT}\over s}\sin\omega T} + 0\bigg] +{\omega\over s} \int_0^\infty e^{-st}\cos\omega t\,dt & & \text{ The limit of the first term is }0\text{ since } |\sin\omega T| \le 1.\\[4pt]
    & ={\omega\over s}G(s),\end{align*}\]

    so

    \[\label{eq:8.1.8} F(s)={\omega\over s}G(s).\]

    Similarly, if \(s>0\), integrating Equation \ref{eq:8.1.7} by parts yields

    \[\begin{align*} G(s) &= \int_0^\infty e^{-st}\cos\omega t\,dt = \lim_{T\to\infty}\int_0^T e^{-st}\cos\omega t\,dt \\[4pt]
    &=\lim_{T\to\infty} \bigg[ -{e^{-st}\over s}\cos\omega t\Big|_0^T-{\omega\over s} \int_0^T e^{-st}\sin\omega t\,dt \bigg] \\[4pt]
    &=\lim_{T\to\infty} \bigg[ -\cancelto{0}{{e^{-sT}\over s}\cos\omega T} + {1 \over s}\bigg] -{\omega\over s} \int_0^\infty e^{-st}\sin\omega t\,dt & & \text{ The limit of the first term is }0\text{ since } |\cos\omega T| \le 1.\\[4pt]
    & = {1 \over s} - {\omega\over s}F(s),\end{align*}\]

    so

    \[G(s)={1\over s} - {\omega\over s} F(s).\nonumber\]

    Now substitute from Equation \ref{eq:8.1.8} into this to obtain

    \[G(s)={1\over s} - {\omega^2\over s^2} G(s).\nonumber\]

    Solving this for \(G(s)\) yields

    \[G(s)={s\over s^2+\omega^2},\quad s>0.\nonumber\]

    This and Equation \ref{eq:8.1.8} imply that

    \[F(s)={\omega\over s^2+\omega^2},\quad s>0.\nonumber\]

    Tables of Laplace Transforms

    Extensive tables of Laplace transforms have been compiled and are commonly used in applications. The brief table of Laplace transforms in the Appendix will be adequate for our purposes.

    Example 8.1.5

    Use the table of Laplace transforms to find \({\mathscr L}(t^3e^{4t})\).

    The table includes the transform pair

    \[t^ne^{at}\leftrightarrow {n!\over(s-a)^{n+1}}.\nonumber\]

    Setting \(n=3\) and \(a=4\) here yields

    \[{\mathscr L} (t^3e^{4t})={3!\over(s-4)^4}={6\over(s-4)^4}.\nonumber\]

    We’ll sometimes write Laplace transforms of specific functions without explicitly stating how they are obtained. In such cases you should refer to the table of Laplace transforms.

    Linearity of the Laplace Transform

    The next theorem presents an important property of the Laplace transform.

    Theorem 8.1.2 Linearity Property

    Suppose \({\mathscr L}(f_i)\) is defined for \(s>s_i,\) \(1\le i\le n).\) Let \(s_0\) be the largest of the numbers \(s_1\), \(s_{2},\) …,\(s_n,\) and let \(c_1\), \(c_2\),…, \(c_n\) be constants. Then

    \[{\mathscr L}(c_1f_1+c_2f_2+\cdots+c_nf_n)=c_1{\mathscr L}(f_1)+c_2{\mathscr L}(f_2) +\cdots+c_n{\mathscr L}(f_n)\mbox{ for } s>s_0.\nonumber\]

    Proof

    We give the proof for the case where \(n=2\). If \(s>s_0\) then

    \[\begin{aligned} {\mathscr L}(c_1f_1+c_2f_2)&= \int_0^\infty e^{-st}\left(c_1f_1(t)+c_2f_2(t))\right)\,dt\\ &= c_1\int_0^\infty e^{-st}f_1(t)\,dt+c_2\int_0^\infty e^{-st}f_2(t)\,dt\\ &= c_1{\mathscr L}(f_1)+c_2{\mathscr L}(f_2).\end{aligned}\nonumber\]

    Example 8.1.6

    Use Theorem 8.1.2 and the known Laplace transform

    \[{\mathscr L}(e^{at})={1\over s-a} \nonumber\]

    to find \({\mathscr L}(\cosh bt)\,(b\ne0)\).

    Solution

    By definition,

    \[\cosh bt={e^{bt}+e^{-bt}\over 2}. \nonumber\]

    Therefore

    \[\label{eq:8.1.9} \begin{array}{ccl} {\mathscr L}(\cosh bt)&=& {\mathscr L}\left( {1\over 2} e^{bt}+ {1\over 2}e^{-bt}\right)\\[4pt] &=& {1\over 2} {\mathscr L}(e^{bt}) + {1\over 2} {\mathscr L}(e^{-bt}) \qquad \hbox{(by the LinearityProperty)}\\[4pt] &=& \dfrac{1}{2}\cdot\dfrac{1}{s-b} + \dfrac{1}{2}\cdot\dfrac{1}{s+b}, \end{array}\]

    where the first transform on the right is defined for \(s>b\) and the second for \(s>-b\); hence, both are defined for \(s>|b|\). Simplifying the last expression in Equation \ref{eq:8.1.9} yields

    \[{\mathscr L}(\cosh bt)={s\over s^2-b^2},\quad s>|b|.\nonumber\]

    The next theorem enables us to start with known transform pairs and derive others. (For other results of this kind, see Exercises 8.1.6 and 8.1.13.)

    Theorem 8.1.3 First Shifting Theorem

    If \(\displaystyle F(s)=\int_0^\infty e^{-st} f(t)\,dt\) is the Laplace transform of \(f(t)\) for \(s>s_0\), then

    \[{\mathscr L}\big(e^{at}f(t)\big) = F(s - a), \quad \text{for }s >s_0+a. \nonumber\]

    That is, \(F(s-a)\) is the Laplace transform of \(e^{at}f(t)\) for \(s >s_0+a\).

    Proof

    Replacing \(s\) by \(s-a\) in Equation \ref{eq:8.1.10} yields

    \[\label{eq:8.1.11} F(s-a)=\int_0^\infty e^{-(s-a)t}f(t)\,dt\]

    if \(s-a>s_0\); that is, if \(s>s_0+a\). However, Equation \ref{eq:8.1.11} can be rewritten as

    \[F(s-a)=\int_0^\infty e^{-st}\left(e^{at}f(t)\right)\,dt,\nonumber\]

    which implies the conclusion.

    Example 8.1.7

    Use Theorem 8.1.3 and the known Laplace transforms of \(1\), \(t\), \(\cos\omega t\), and \(\sin\omega t\) to find

    \[{\mathscr L}(e^{at}),\quad {\mathscr L}(te^{at}),\quad {\mathscr L}(e^{\lambda t}\sin \omega t),\mbox{and } {\mathscr L}(e^{\lambda t}\cos\omega t).\nonumber\]

    Solution

    In the following table the known transform pairs are listed on the left and the required transform pairs listed on the right are obtained by applying Theorem 8.1.3.

    Table 8.1.1
    \(f(t)\leftrightarrow F(s)\) \(e^{at}f(t)\leftrightarrow F(s-a)\)
    \(1\leftrightarrow\dfrac{1}{s},\quad s>0\) \(e^{at}\leftrightarrow\dfrac{1}{s-a},\quad s>a\)
    \(t\leftrightarrow \dfrac{1}{s^{2}},\quad s>0\) \(te^{at}\leftrightarrow \dfrac{1}{(s-a)^{2}},\quad s>a\)
    \(\sin\omega t\leftrightarrow \dfrac{\omega }{s^{2}+\omega ^{2}},\quad s>0\) \(e^{\lambda t}\sin\omega t\leftrightarrow \dfrac{\omega}{(s-\lambda)^{2}+\omega ^{2}},\quad s>\lambda\)
    \(\cos\omega t\leftrightarrow \dfrac{s}{s^{2}+\omega ^{2}},\quad s>0\) \(e^{\lambda t}\sin\omega t\leftrightarrow \dfrac{s-\lambda }{(s-\lambda )^{2}+\omega ^{2}},\quad s>\lambda\)

    Existence of Laplace Transforms

    Not every function has a Laplace transform. For example, it can be shown (Exercise 8.1.3) that

    \[\int_0^\infty e^{-st}e^{t^2} dt=\infty\nonumber\]

    for every real number \(s\). Hence, the function \(f(t)=e^{t^2}\) does not have a Laplace transform.

    Our next objective is to establish conditions that ensure the existence of the Laplace transform of a function. We first review some relevant definitions from calculus.

    Recall that a limit

    \[\lim_{t\to t_0} f(t)\nonumber\]

    exists if and only if the one-sided limits

    \[\lim_{t\to t_0-}f(t)\quad \text{and} \quad \lim_{t\to t_0+}f(t)\nonumber\]

    both exist and are equal; in this case,

    \[\lim_{t\to t_0}f(t)=\lim_{t\to t_0-}f(t)=\lim_{t\to t_0+}f(t) .\nonumber\]

    Recall also that \(f\) is continuous at a point \(t_0\) in an open interval \((a,b)\) if and only if

    \[\lim_{t\to t_0}f(t)=f(t_0),\nonumber\]

    which is equivalent to

    \[\label{eq:8.1.12} \lim_{t\to t_0+}f(t)=\lim_{t\to t_0-}f(t)=f(t_0).\]

    For simplicity, we define

    \[f(t_0+)=\lim_{t\to t_0+}f(t)\quad\hbox{and }\quad f(t_0-)=\lim_{t\to t_0-}f(t),\nonumber\]

    so Equation \ref{eq:8.1.12} can be expressed as

    \[f(t_0+)=f(t_0-)=f(t_0).\nonumber\]

    If \(f(t_0+)\) and \(f(t_0-)\) have finite but distinct values, we say that \(f\) has a jump discontinuity at \(t_0\), and

    \[f(t_0+)-f(t_0-)\nonumber\]

    is called the jump in \(f\) at \(t_0\) (Figure 8.1.1).

    8.1: Introduction to the Laplace Transform (2)

    If \(f(t_0+)\) and \(f(t_0-)\) are finite and equal, but either \(f\) isn’t defined at \(t_0\) or it is defined but

    \[f(t_0)\ne f(t_0+)=f(t_0-),\nonumber\]

    we say that \(f\) has a removable discontinuity at \(t_0\) (Figure 8.1.2). This terminolgy is appropriate since a function \(f\) with a removable discontinuity at \(t_0\) can be made continuous at \(t_0\) by defining (or redefining)

    \[f(t_0)=f(t_0+)=f(t_0-).\nonumber\]

    Note

    We know from calculus that a definite integral isn’t affected by changing the values of its integrand at isolated points. Therefore, redefining a function f to make it continuous at removable discontinuities does not change \(\cal{L}(f)\).

    Definition 8.1.4: Piecewise Continuous
    • A function \(f\) is said to be piecewise continuous on a finite closed interval \([0,T]\) if \(f(0+)\) and \(f(T-)\) are finite and \(f\) is continuous on the open interval \((0,T)\) except possibly at finitely many points, where \(f\) may have jump discontinuities or removable discontinuities.
    • A function \(f\) is said to be piecewise continuous on the infinite interval \([0,\infty)\) if it is piecewise continuous on \([0,T]\) for every \(T>0\).

    Figure 8.1.3 shows the graph of a typical piecewise continuous function.

    It is shown in calculus that if a function is piecewise continuous on a finite closed interval then it is integrable on that interval. But if \(f\) is piecewise continuous on \([0,\infty)\), then so is \(e^{-st}f (t)\), and therefore

    \[\int_0^T e^{-st}f(t)\,dt \nonumber\]

    8.1: Introduction to the Laplace Transform (3)
    8.1: Introduction to the Laplace Transform (4)

    exists for every \(T>0\). However, piecewise continuity alone does not guarantee that the improper integral

    \[\label{eq:8.1.13} \int_0^\infty e^{-st}f(t)\,dt=\lim_{T\to\infty}\int_0^T e^{-st}f(t)\, dt\]

    converges for \(s\) in some interval \((s_0,\infty)\). For example, we noted earlier that Equation \ref{eq:8.1.13} diverges for all \(s\) if \(f(t)=e^{t^2}\). Stated informally, this occurs because \(e^{t^2}\) increases too rapidly as \(t\to\infty\). The next definition provides a constraint on the growth of a function that guarantees convergence of its Laplace transform for \(s\) in some interval \((s_0,\infty)\).

    Definition 8.1.5: of exponential order

    A function \(f\) is said to be of exponential order \(s_0\) if there are constants \(M\) and \(t_0\) such that

    \[\label{eq:8.1.14} |f(t)|\le Me^{s_0t},\quad t\ge t_0.\]

    In situations where the specific value of \(s_0\) is irrelevant we say simply that \(f\) is of exponential order.

    The next theorem gives useful sufficient conditions for a function \(f\) to have a Laplace transform. The proof is sketched in Exercise 8.1.10.

    Theorem 8.1.6

    If \(f\) is piecewise continuous on \([0,\infty)\) and of exponential order \(s_0,\) then \({\mathscr L}(f)\) is defined for \(s>s_0\).

    Note

    We emphasize that the conditions of Theorem 8.1.6 are sufficient, but not necessary, for \(f\) to have a Laplace transform. For example, Exercise 8.1.14(c) shows that \(f\) may have a Laplace transform even though \(f\) isn’t of exponential order

    Example 8.1.8

    If \(f\) is bounded on some interval \([t_0,\infty)\), say

    \[|f(t)|\le M,\quad t\ge t_0,\nonumber\]

    then Equation \ref{eq:8.1.14} holds with \(s_0=0\), so \(f\) is of exponential order zero. Thus, for example, \(\sin\omega t\) and \(\cos \omega t\) are of exponential order zero, and Theorem 8.1.6 implies that \({\mathscr L}(\sin\omega t)\) and \({\mathscr L}(\cos \omega t)\) exist for \(s>0\). This is consistent with the conclusion of Example 8.1.4.

    Example 8.1.9

    It can be shown that if \(\lim_{t\to\infty}e^{-s_0t}f(t)\) exists and is finite then \(f\) is of exponential order \(s_0\) (Exercise 8.1.9). If \(\alpha\) is any real number and \(s_0>0\) then \(f(t)=t^\alpha\) is of exponential order \(s_0\), since

    \[\lim_{t\to\infty}e^{-s_0t}t^\alpha=0,\nonumber\]

    by L’Hôpital’s rule. If \(\alpha\ge 0\), \(f\) is also continuous on \([0,\infty)\). Therefore Exercise 8.1.9 and Theorem 8.1.6 imply that \({\mathscr L}(t^\alpha)\) exists for \(s\ge s_0\). However, since \(s_0\) is an arbitrary positive number, this really implies that \({\mathscr L}(t^\alpha)\) exists for all \(s>0\). This is consistent with the results of Example 8.1.2 and Exercises 8.1.6 and 8.1.8.

    Example 8.1.10

    Find the Laplace transform of the piecewise continuous function

    \[f(t)=\left\{\begin{array}{cl} 1,& \text{if }0\le t<1,\\ -3e^{-t},&\text{if }t\ge 1.\end{array}\right.\nonumber\]

    Solution

    Since \(f\) is defined by different formulas on \([0,1)\) and \([1,\infty)\), we write

    \[F(s)=\int_0^\infty e^{-st} f(t)\,dt =\int_0^1e^{-st}(1)\,dt+\int_1^\infty e^{-st}(-3e^{-t})\,dt.\nonumber\]

    Since

    \[\int_{0}^{1}e^{-st}dt = \left\{\begin{array}{cl} {\dfrac{1-e^{-s}}{s},}&{\text{if }s\neq 0} \\ {1,}&{\text{if }s=0} \end{array} \right. \nonumber \]

    and

    \[\int_1^\infty e^{-st}(-3e^{-t})\,dt=-3\int_1^\infty e^{-(s+1)t}\,dt\; =\; -{3e^{-(s+1)}\over s+1},\quad s>-1,\nonumber\]

    it follows that

    \[F(s) = \left\{\begin{array}{cl}{\dfrac{1-e^{-s}}{s}-3\dfrac{e^{-(s+1)}}{s+1},}&{\text{if }s>-1, s\neq 0} \\ {1-\dfrac{3}{e},}&{\text{if }s=0} \end{array} \right. \nonumber \]

    This is consistent with Theorem 8.1.6, since

    \[|f(t)|\le 3e^{-t},\quad t\ge 1,\nonumber\]

    and therefore \(f\) is of exponential order \(s_0=-1\).

    Note

    In Section 8.4 we’ll develop a more efficient method for finding Laplace transforms of piecewise continuous functions.

    Example 8.1.11

    We stated earlier that

    \[\int_0^\infty e^{-st} e^{t^2} dt=\infty \nonumber\]

    for all \(s\), so Theorem 8.1.6 implies that \(f(t)=e^{t^2}\) is not of exponential order, since

    \[\lim_{t\to\infty} {e^{t^2}\over Me^{s_0t}}=\lim_{t\to\infty} {1\over M} e^{t^2-s_0t}=\infty, \nonumber\]

    so

    \[e^{t^2}>Me^{s_0t} \nonumber\]

    for sufficiently large values of \(t\), for any choice of \(M\) and \(s_{0}\) (Exercise 8.1.3).

    Contributors:

    • Paul Seeburgeredited this section extensively to improve all examples using the limit definition of the Laplace transform. In particular, he added significant content to Examples \(\PageIndex{2}\)and\(\PageIndex{4}\).
    8.1: Introduction to the Laplace Transform (2024)

    FAQs

    How to learn Laplace transform easily? ›

    1. Take the Laplace transform of all the terms. You're allowed to do this because an inner product is a linear function of its arguments.
    2. Replace T(f') with sT(f).
    3. Solve for T(f) in terms of s.
    4. Undo the transformation. In other words, try to recognize what function f could be so that T(f) equals the terms of s in step 3.
    Dec 7, 2022

    How do you introduce Laplace transform? ›

    It transforms ONE variable at a time. The Laplace transform of a function f(t) is designated as L[f(t)], with the variable t covers a spectrum of (0,∞). where s is the parameter of the Laplace transform, and F(s) is the expression of the Laplace transform of function f(t) with 0 ≤ t < ∞.

    What is the existence of Laplace transformation? ›

    If f(t) is defined and piecewise continuous on every finite interval on the semi-axis t≥ 0 and satisfies (2) for all t ≥ 0 and some constants M and k, then the Laplace transform L(f) exists for all s > k.

    What is a Laplace transform for dummies? ›

    Used extensively in engineering, the Laplace Transform takes a function of a positive real variable (x or t), often represented as “time,” and transforms it into a function of a complex variable, commonly called “frequency.”

    What type of math is Laplace transform? ›

    The Laplace transform is a mathematical technique that changes a function of time into a function in the frequency domain. If we transform both sides of a differential equation, the resulting equation is often something we can solve with algebraic methods.

    What is the formula for the Laplace step function? ›

    The Laplace transform of a unit step function is L(s) = 1/s. A shifted unit step function u(t-a) is, 0, when t has values less than a. 1, when t has values greater than a.

    What is the Laplace transform in layman's terms? ›

    Basically, Laplace transform takes a function in time domain and converts it into a function in frequency domain. The frequency here is taken as a complex quantity. The benefit of doing this is that differential equations in time domain becomes simple algebraic ones in frequency domain.

    What does the Laplace transform really tell us? ›

    If you think of a function as the impulse response of a linear time invariant system, then the laplace transform of that function tells you the result of an experiment where you drive the system with an exponentially damped sinusoid.

    What is the Laplace transform method? ›

    The Laplace transform reduces a linear differential equation to an algebraic equation, which can then be solved by the formal rules of algebra. The original differential equation can then be solved by applying the inverse Laplace transform.

    Can you multiply Laplace transforms? ›

    One of the disappointments of the Laplace transform is that the Laplace transform of the product of two functions is not the product of their Laplace transforms. In fact, the Laplace transform of the convolution of two functions is the product of their Laplace transforms.

    Why do we study Laplace transform? ›

    What is the use of Laplace Transform? The Laplace transform is used to solve differential equations. It is accepted widely in many fields. We know that the Laplace transform simplifies a given LDE (linear differential equation) to an algebraic equation, which can later be solved using the standard algebraic identities.

    Who came first, Laplace or Fourier? ›

    Fourier Transformation was invented in 1822, but it went through several researches in the next 70-80 years or so. Laplace Transformation was invented somewhere between 1782-85, but was the refinement of concepts originally started by Leonhard Euler in 1744.

    Who invented Laplace transform? ›

    Laplace transform, in mathematics, a particular integral transform invented by the French mathematician Pierre-Simon Laplace (1749–1827), and systematically developed by the British physicist Oliver Heaviside (1850–1925), to simplify the solution of many differential equations that describe physical processes.

    What is the formula for the Laplace transform of a step function? ›

    The Laplace transform of a unit step function is L(s) = 1/s. A shifted unit step function u(t-a) is, 0, when t has values less than a. 1, when t has values greater than a.

    How do you solve a system of equations using the Laplace transform? ›

    The idea is simple; the Laplace transform of each term in the differential equation is taken. If the unknown function is y(t) then, on taking the transform, an algebraic equation involving Y (s) = L{y(t)} is obtained.

    How to convert into Laplace transform? ›

    Laplace transform of derivatives: {f'(t)}= S* L{f(t)}-f(0). This property converts derivatives into just function of f(S),that can be seen from eq. above. Next inverse laplace transform converts again function F(S) into f(t).

    What is simple Laplace equation? ›

    As a final example, Laplace's equation appears in two-dimensional fluid flow. For an incompressible flow, ∇·v=0. If the flow is irrotational, then ∇×v=0. We can introduce a velocity potential, v=∇ϕ.

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