In the rest of this chapter we’ll use the Laplace transform to solve initial value problems for constant coefficient second order equations. To do this, we must know how the Laplace transform of \(f'\) is related to the Laplace transform of \(f\). The next theorem answers this question.
Theorem 8.3.1
Suppose \(f\) is continuous on \([0,\infty)\) and of exponential order \(s_0\), and \(f'\) is piecewise continuous on \([0,\infty).\) Then \(f\) and \(f'\) have Laplace transforms for \(s > s_0,\) and
We know from Theorem 8.1.6 that \({\cal L}(f)\) is defined for \(s>s_0\). We first consider the case where \(f'\) is continuous on \([0,\infty)\). Integration by parts yields
for any \(T>0\). Since \(f\) is of exponential order \(s_0\), \(\displaystyle \lim_{T\to \infty}e^{-sT}f(T)=0\) and the integral in on the right side of Equation \ref{eq:8.3.2} converges as \(T\to\infty\) if \(s> s_0\). Therefore
Suppose \(T>0\) and \(f'\) is only piecewise continuous on \([0,T]\), with discontinuities at \(t_1 < t_2 <\cdots < t_{n-1}\). For convenience, let \(t_0=0\) and \(t_n=T\). Integrating by parts yields
which agrees with the corresponding result obtained in 8.1.4.
In Section 2.1 we showed that the solution of the initial value problem
\[\label{eq:8.3.3} y'=ay, \quad y(0)=y_0, \]
is \(y=y_0e^{at}\). We’ll now obtain this result by using the Laplace transform.
Let \(Y(s)={\cal L}(y)\) be the Laplace transform of the unknown solution of Equation \ref{eq:8.3.3}. Taking Laplace transforms of both sides of Equation \ref{eq:8.3.3} yields
We need the next theorem to solve second order differential equations using the Laplace transform.
Theorem 8.3.2
Suppose \(f\) and \(f'\) are continuous on \([0,\infty)\) and of exponential order \(s_0,\) and that \(f''\) is piecewise continuous on \([0,\infty).\) Then \(f\), \(f'\), and \(f''\) have Laplace transforms for \(s > s_0\),
Theorem 8.3.1
implies that \({\cal L}(f')\) exists and satisfies Equation \ref{eq:8.3.4} for \(s>s_0\). To prove that \({\cal L}(f'')\) exists and satisfies Equation \ref{eq:8.3.5} for \(s>s_0\), we first apply Theorem 8.3.1
to \(g=f'\). Since \(g\) satisfies the hypotheses of Theorem 8.3.1
, we conclude that \({\cal L}(g')\) is defined and satisfies
\[{\cal L}(g')=s{\cal L}(g)-g(0)\nonumber \]
for \(s>s_0\). However, since \(g'=f''\), this can be rewritten as
\[{\cal L}(f'')=s{\cal L}(f')-f'(0).\nonumber \]
Substituting Equation \ref{eq:8.3.4} into this yields Equation \ref{eq:8.3.5}.
Solving Second Order Equations with the Laplace Transform
We’ll now use the Laplace transform to solve initial value problems for second order equations.
Example 8.3.2
Use the Laplace transform to solve the initial value problem
It isn’t necessary to write all the steps that we used to obtain Equation \ref{eq:8.3.8}. To see how to avoid this, let’s apply the method of Example 8.3.2
to the general initial value problem
The coefficient of \(Y(s)\) on the left is the characteristic polynomial
\[p(s)=as^2+bs+c\nonumber \]
of the complementary equation for Equation \ref{eq:8.3.9}. Using this and moving the terms involving \(k_0\) and \(k_1\) to the right side of Equation \ref{eq:8.3.11} yields
This equation corresponds to Equation \ref{eq:8.3.8} of Example 8.3.2
. Having established the form of this equation in the general case, it is preferable to go directly from the initial value problem to this equation. You may find it easier to remember Equation \ref{eq:8.3.12} rewritten as
In Example 8.2.8 we found the inverse transform of this function to be
\[y={1\over2}-{7\over2}e^{-t}\cos t-{5\over2}e^{-t}\sin t \nonumber \]
(Figure 8.3.2
), which is therefore the solution of Equation \ref{eq:8.3.15}.
Note
In our examples we applied Theorems 8.3.1
and 8.3.2
without verifying that the unknown function \(y\) satisfies their hypotheses. This is characteristic of the formal manipulative way in which the Laplace transform is used to solve differential equations. Any doubts about the validity of the method for solving a given equation can be resolved by verifying that the resulting function \(y\) is the solution of the given problem.