Difference between revisions of "Active Filters"

Revision as of 15:29, 24 March 2021

Passive RLC filters are simple and easy to design and use. However, can we implement them on-chip? Let us look at a simple example to give us a bit more insight regarding this question.

Example: A passive band-pass filter

Consider the filter shown in Fig. 1.

We can write the transfer function as:

{\begin{aligned}H\left(s\right)&={\frac {v_{o}}{v_{i}}}={\frac {sL\|{\frac {1}{sC}}}{R+sL\|{\frac {1}{sC}}}}={\frac {sL\cdot {\frac {1}{sC}}}{R\cdot \left(sL+{\frac {1}{sC}}\right)+sL\cdot {\frac {1}{sC}}}}\\&={\frac {sL}{s^{2}RLC+R+sL}}={\frac {s\cdot {\frac {1}{RC}}}{s^{2}+s\cdot {\frac {1}{RC}}+{\frac {1}{LC}}}}\\\end{aligned}}

(1)

@@ Line 1: / Line 1: @@
-== Active Filters ==
+Passive RLC filters are simple and easy to design and use. However, can we implement them on-chip? Let us look at a simple example to give us a bit more insight regarding this question.
+== Example: A passive band-pass filter ==
+Consider the filter shown in Fig. 1.
+We can write the transfer function as:
+{{NumBlk|::|<math>
+\begin{align}
+H\left(s\right) & = \frac{v_o}{v_i} = \frac{sL \| \frac{1}{sC}}{R + sL \| \frac{1}{sC}} = \frac{sL \cdot \frac{1}{sC}}{R \cdot \left( sL + \frac{1}{sC}\right) + sL\cdot\frac{1}{sC}} \\
+& = \frac{sL}{s^2 RLC + R + sL} = \frac{s\cdot \frac{1}{RC}}{s^2 + s\cdot \frac{1}{RC} + \frac{1}{LC}} \\
+\end{align}
+</math>|{{EquationRef|1}}}}

Difference between revisions of "Active Filters"

Revision as of 15:29, 24 March 2021

Example: A passive band-pass filter

Navigation menu

Personal tools

Namespaces

Variants

Views

More

Search

Navigation

Tools