Continuous Control Systems: a review
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- Figure 1.7.
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Figure 1.6. Step response for a first-order system
Frequency Response The frequency response of a dynamic system is studied and characterized for periodic inputs of variable frequency but of constant magnitude. For continuous- time systems, the gain-frequency characteristic is represented on a double logarithmic scale and the phase frequency characteristic is represented on a logarithmic scale only for the frequency axis. - )
The gain G() = |H(j)| is expressed in dB (|H(j)| dB = 20 log |H(j)|) on the vertical axis and the frequency , expressed in rad/s ( = 2 f where f represents the frequency in Hz) is represented on the horizontal axis. Figure 1.7 gives some typical frequency response curves. The characteristic elements of the frequency response are: fB(B) (bandwidth): the frequency (radian frequency) from which the zero- frequency (steady-state) gain G(0) is attenuated more than 3 dB; G(B ) G(0) 3dB; (G(B ) 0.707 G(0)) . fC(C) (cut-off frequency): the frequency (rad/s) from which the attenuation introduced with respect to the zero frequency is greater than N dB; G( jC ) G(0) N dB . Q (resonance factor): the ratio between the gain corresponding to the maximum of the frequency response curve and the value G(0). Slope: it concerns the tangent to the gain frequency characteristic in a certain region. It depends on the number of poles and zeros and on their frequency distribution. Consider, as an example, the first-order system characterized by the transfer function given by Equation 1.1.9. For s = j the transfer function of Equation 1.1.9 is rewritten as H ( j ) G 1 jT H ( j ) e j () H ( j ) ( ) (1.1.16)
where |H(j represents the modulus (gain) of the transfer function and the phase deviation introduced by the transfer function. We then have G( ) H ( j ) G (1.1.17)
( ) tan1 ImG( j ) tan1 T (1.1.18) Re G( j ) From Equation 1.1.17 and from the definition of the bandwidth B, we obtain: B 1/ T B Using Equation 1.1.18, we deduce that for = B the system introduces a phase deviation ) = -45°. Also note that for = 0, G(0) = G, 0) = 0° and for , G( = 0, ) = -90°. Figure 1.8 gives the exact and asymptotic frequency characteristics for a first- order system (gain and phase). As a general rule, each stable pole introduces an asymptotic slope of -20 dB/dec (or 6 dB/octave) and an asymptotic phase lag of -90°. On the other hand, each stable zero introduces an asymptotic slope of +20 dB/dec and an asymptotic phase shift of +90°. It follows that the asymptotic slope of the gain-frequency characteristic in dB, for high frequencies, is given by G (n m) 20 dB / dec (1.1.19a) 0
BODE diagram 0 -22.5 [dB] [Deg] -20
-40 -2 -1 0 -45 -67.5 -90 1 2 10 10 10 10 10 [rad/s] |
