Passive Filter Transformations

1. Passive Filter Transformations • For every passive filter design, there are two ways of laying out the LC network. • In many cases, one of these may be more appropriate for component simulation than the other. Eg. Three pole low-pass filter p network, best passive layout (fewest inductors) T network, best for component simulation (fewest FDNRs)

2. Layout Transformation • Meshes become nodes • Impedances between meshes become their reciprocal impedance between nodes. • Resistors, RW® Resistors, 1/R W • Inductors, L H ® Capacitors, L F • Capacitors, L F ® Inductors, L H • Voltage sources become current sources

3. Example Three pole Butterworth low pass filter

4. Example 2 Five pole elliptic low pass filter. Pass band ripple = 1 dB Stop band attenuation = 60 dB

5. Component Simulation Summary • Component simulation can be used to simulate relatively complex passive networks. • Either inductances or FDNRs are simulated using GICs. • Passive networks are proven to be robust against component tolerances (unlike cascade synthesis). • But… • The op-amp output voltages required within the GIC can be larger than the input signal. • The maximum input range is restricted.

6. Operational Simulation • Operational simulation proceeds as follows: • A passive LC network is designed. • A set of differential equations relating voltages and currents in the network is written. • An analogue computer that solves these equations is designed. • The analogue computer solves the set of differential equations is real time and hence simulates the LC network.

7. Two-Pole Passive Filter

8. Block Diagram Equivalent

9. Analogue Computer Elements (I) Inverting Summing Integrator Applying Kirchoff’s current law at the inverting input node:

10. Analogue Computer Elements (II) Inverting Amplifier Required to convert the inverting integrator into a non-inverting integrator.

11. Analogue Computer Design • The voltage levels at the outputs of the op-amps are numerically related to variables in the equations • These variables can be either voltages or currents • To simplify matters: • Signals representing voltages will be kept equal to the real voltage • Signals representing currents will be kept numerically equal to the current in Amps (i.e. a scale factor of 1 Volt per Amp) • In general, any scale factors can be used for voltages and currents

12. Building the Filter • The passive filter analysis boils down to just two equations: • Two integrators will, therefore, be required to simulate this circuit

13. Design 1

14. Design 2

15. Design 3 The ‘Ring of Three’ or ‘Two Integrator Loop’

16. Higher Order Filters • The ring of three could be used as the second order sections in a cascaded filter. • A more robust method is to simply extend the concepts of operational simulation to higher order passive networks. • Such filters are sometimes called Leapfrog Filters. • Leapfrog filters are built up stage by stage, simulating the V-I characteristics of each passive component. • 3N/2 op-amps required.

17. Summary • Operational simulation can be thought of as real-time circuit analysis performed by an analogue computer. • All passive networks can be represented using summing integrators and invertors. • The ring of three is one of the simplest examples, simulating a second order passive network. • Next time: Design example for ring of three and module summary