288 Chapter 6 / Control Systems Analysis and Design by the Root-Locus MethodR(s) C(s)(a)1
sK
(s+ 1) (s+ 2)R(s) C(s)(c)1
s+ 1K
s(s+ 1) (s+ 2)K
s(s+ 2)s+ 1H(s)R(s) C(s)(b)+++–G(s)+–Figure 6–14
(a) Control system
with velocity
feedback; (b) and
(c) modified block
diagrams.Cancellation of Poles of G(s) with Zeros of H(s). It is important to note that
if the denominator of G(s)and the numerator of H(s)involve common factors, then the
corresponding open-loop poles and zeros will cancel each other, reducing the degree of
the characteristic equation by one or more. For example, consider the system shown in
Figure 6–14(a). (This system has velocity feedback.) By modifying the block diagram of
Figure 6–14(a) to that shown in Figure 6–14(b), it is clearly seen that G(s)andH(s)
have a common factor s+1.The closed-loop transfer function C(s)/R(s)is
The characteristic equation is
Because of the cancellation of the terms (s+1)appearing in G(s)andH(s),however,
we have
The reduced characteristic equation is
The root-locus plot of G(s)H(s)does not show all the roots of the characteristic equa-
tion, only the roots of the reduced equation.
To obtain the complete set of closed-loop poles, we must add the canceled pole of
G(s)H(s)to those closed-loop poles obtained from the root-locus plot of G(s)H(s).
The important thing to remember is that the canceled pole of G(s)H(s)is a closed-loop
pole of the system, as seen from Figure 6–14(c).
s(s+2)+K= 0
=
s(s+2)+K
s(s+2)
1 +G(s)H(s)= 1 +
K(s+1)
s(s+1)(s+2)
Cs(s+2)+KD(s+1)= 0
C(s)
R(s)
=
K
s(s+1)(s+2)+K(s+1)
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