Also, \$w_n=w_p\$, causes an infinite response (undamped system - oscillator). The meaning of \$w_n\$ for the Butterworth response is the same as for the first-order case, that is, \$w_n\$ represents the -3 dB frequency, also called cuttoff frequency. The magnitude curve is sais to be maximally flat (no peak). In filter theory, that special value for \$\zeta=0.707\$ corresponds to a Butterworth response. Note on figure below: When varying the damping ratio \$\zeta\$, the peak follows a specific curve. Where \$\omega_n\$ is the natural frequency (also called corner frequency when considering assymptotes), the peak Frequency Response basically means how our system will change with respect to a given input frequency. This system could be any system (not just a circuit) which experiences change in behavior due to a change in frequency (cycles/second). Peaks in the frequency response can only exist in systems with conjugate complex poles.įor an underdamped (\$\zeta 0.5\$) second-order system, the peak appears specifically for \$\zeta<1/\sqrt$$ A: Bode plots are a actually a set of graphs which show the frequency response of a system.
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