(Click on image to enlarge)

Now, we’ve not made a pure D-element, but one with a capacitor in parallel. When we use these in our ladder filter circuits instead of pure D-elements, we get a filter circuit that’s not covered by the standard design methods. The equivalent LCR passive filter (before we apply the Bruton transform) contains capacitors that each have a resistor in parallel. How do we take this into account? Well, you’ll remember my attachment to the Million Monkeys Method – using a spreadsheet solver to manhandle a filter circuit to have the right response. We’ll see again next time how those monkeys can indeed do a good job, and create useful filter designs.

What’s more, you can see that we’ve only had to use one amplifier for each branch in the filter. Figure 5 is a seventh order filter and it uses only three amplifiers instead of the six required by the regular singly-terminated D-element design in Figure 1.

This might all seem rather theoretical and lacking in “how do I use this?” information.  Next time I’ll describe a worked example of a higher order filter for a high bias voltage that’s well outside available DC power supplies, using this approach to meet tight component size and settling time constraints that simply can’t be met by just “slapping a capacitor on”. This will also involve a deeper look at how cutoff frequency, stopband rejection ands settling time interact, and how we can optimize the values in these nonstandard circuits for best performance. Meanwhile, why not look sideways at some of your other circuits?

Happy (DC-free) filtering! / Kendall.

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