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Please note that the recommended version of Scilab is 2025.0.0. This page might be outdated.
See the recommended documentation of this function
damp
Natural frequencies and damping factors.
Calling Sequence
[wn,z] = damp(sys) [wn,z] = damp(P [,dt]) [wn,z] = damp(R [,dt])
Parameters
- sys
A linear dynamical system (see syslin).
- P
An array of polynomials.
- P
An array of real or complex floating point numbers.
- dt
A non negative scalar, with default value 0.
- wn
vector of floating point numbers in increasing order: the natural pulsation in rd/s.
- z
vector of floating point numbers: the damping factors.
Description
The denominator second order continuous time transfer function
with complex poles can be written as s^2+2*z*wn*s+wn^2
wherez
is the damping factor and wn
the natural pulsation.
If sys
is a continuous time system,
[wn,z] = damp(sys)
returns in wn
the natural
pulsation (in rd/s) and in z
the damping factors
of the poles of the linear dynamical system
sys
. The wn
and
z
arrays are ordered according to the increasing
pulsation order.
If sys
is a discrete time system
[wn,z] = damp(sys)
returns in
wn
the natural pulsation
(in rd/s) and in z
the
damping factors of the continuous time
equivalent poles of sys
. The
wn
and z
arrays are
ordered according to the increasing pulsation order.
[wn,z] = damp(P)
returns in
wn
the natural pulsation
(in rd/s) and in z
the
damping factors of the set of roots of the polynomials
stored in the P
array. If
dt
is given and non 0, the roots are first
converted to their continuous time equivalents.
The wn
and z
arrays are ordered
according to the increasing pulsation order.
[wn,z] = damp(R)
returns in
wn
the natural pulsation
(in rd/s) and in z
the
damping factors of the set of roots stored in the
R
array.
If dt
is given and non 0, the roots are first
converted to their continuous time equivalents.
wn(i)
and z(i)
are the the
natural pulsation and damping factor of R(i)
.
Examples
s=%s; num=22801+4406.18*s+382.37*s^2+21.02*s^3+s^4; den=22952.25+4117.77*s+490.63*s^2+33.06*s^3+s^4 h=syslin('c',num/den); [wn,z] = damp(h)
The following example illustrates the effect of the damping factor on the frequency response of a second order system.
s=%s; wn=1; clf(); Z=[0.95 0.7 0.5 0.3 0.13 0.0001]; for k=1:size(Z,'*') z=Z(k) H=syslin('c',1+5*s+10*s^2,s^2+2*z*wn*s+wn^2); gainplot(H,0.01,1) p=gce();p=p.children; p.foreground=k; end title("$\frac{1+5 s+10 s^2}{\omega_n^2+2\omega_n\xi s+s^2}, \quad \omega_n=1$") legend('$\xi='+string(Z)+'$') plot(wn/(2*%pi)*[1 1],[0 70],'r') //natural pulsation
Computing the natural pulsations and daping ratio for a set of roots:
[wn,z] = damp((1:5)+%i)
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