218 C H A P T E R 3: The Laplace Transform
Assume the above equation represents a system with inputx(t)and outputy(t). Find the impulse
responseh(t)and the unit-step responses(t)of the system.SolutionIf the initial conditions are zero, computing the two- or one-sided Laplace transform of the two
sides of this equation, after lettingY(s)=L[y(t)] andX(s)=L[x(t)], and using the derivative
property of Laplace, we getY(s)[s^2 + 3 s+2]=X(s)To find the impulse response of this system (i.e., the system responsey(t)=h(t)), we letx(t)=δ(t)
and the initial condition be zero. SinceX(s)=1, thenY(s)=H(s)=L[h(t)] isH(s)=1
s^2 + 3 s+ 2=
1
(s+ 1 )(s+ 2 )=
A
s+ 1+
B
s+ 2We obtain valuesA=1 andB=−1, and the inverse Laplace transform is thenh(t)=[
e−t−e−^2 t]
u(t)which is completely transient.In a similar form we obtain the unit-step responses(t), by lettingx(t)=u(t)and the initial
conditions be zero. CallingY(s)=S(s)=L[s(t)], sinceX(s)= 1 /s, we obtainS(s)=H(s)
s=
1
s(s^2 + 3 s+ 2 )=
A
s+
B
s+ 1+
C
s+ 2It is found thatA= 1 /2,B=−1, andC= 1 /2, so thats(t)=0.5u(t)−e−tu(t)+0.5e−^2 tu(t)The steady state ofs(t)is 0.5 as the two exponentials go to zero. Interestingly, the relationsS(s)=
H(s)indicates that by computing the derivative ofs(t)we obtainh(t). Indeed,ds(t)
dt=0.5δ(t)+e−tu(t)−e−tδ(t)−e−^2 tu(t)+0.5e−^2 tδ(t)=[0.5− 1 +0.5]δ(t)+[e−t−e−^2 t]u(t)
=[e−t−e−^2 t]u(t)=h(t) nRemarksn Because the existence of the steady-state response depends on the poles of Y(s)it is possible for an unstable
causal system (recall that for such a system BIBO stability requires all the poles of the system transfer
function be in the open, left-hand s-plane) to have a steady-state response. It all depends on the input.
Consider, for instance, an unstable system with H(s)= 1 /(s(s+ 1 )), being unstable due to the pole at