Cascaded Bandpass Filter
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\(\begin{align}
H=-\frac{j\omega C_NR_F}{(1+j\omega C_FR_F)(1+j\omega C_NR_N)}
\end{align}\)
\(\begin{align}
H=\frac{K2\zeta\omega_n j\omega}{(j\omega)^2+2\zeta\omega_n j\omega+\omega_n^2}=
-\frac{\left(\frac{C_NR_F}{C_NR_N+C_FR_F}\right)\left(\frac{1}{C_FR_F}+\frac{1}{C_NR_N}\right)}{(j\omega)^2+\left(\frac{1}{C_FR_F}+\frac{1}{C_NR_N}\right)j\omega+\frac{1}{C_FR_FC_NR_N}}
\end{align}\)
\(\begin{align}
\omega_1&=\frac{1}{C_FR_F} & \omega_2&=\frac{1}{C_NR_N}
\end{align}\)
\(\begin{align}
H=-\frac{\left(\frac{C_NR_F}{C_NR_N+C_FR_F}\right)\left(\omega_1+\omega_2\right)}{(j\omega)^2+\left(\omega_1+\omega_2\right)j\omega+\omega_1\omega_2}
\end{align}\)
\(\begin{align}
BW&=\omega_1+\omega_2 \\ \omega_n^2&=\omega_1\omega_2
\end{align}\)
This page analyzes a cascaded bandpass filter - specifically the one proposed in Alexander & Sadiku Fig. 14.45.
Analysis
Without inductors, the most likely candidate for such a filter would be the filter on p. 439 of the Rizzoni text[1] which uses a series combination of a resistor and capacitor as \(Z_N\) and a parallel combination as \(Z_F\). This leads to an overall transfer function of:
or, as re-cast in class,
To make life a little easier, let's call
which means
This means the bandwidth and natural frequency squared are, respectively,
Good so far...
- ↑ Rizzoni, Giorgio. Principles and applications of electrical engineering / Giorgio Rizzoni, Tom Hartley. - 5th ed. McGraw-Hill, 2007.
