Filter Design (2)

1. Filter Design (2) Jack Ou ES590

2. Last Time Outline • Butterworth LPF Design • LPF to HPF Conversion • LPF to BPF Conversion • LPF to BRF Conversion • General Cases • Dual Networks • RL≠RS • Other Filters • Chebyshev filter • Bandpass Design Example • Bessel filter • Bandpass Design Example • Filter Synthesis via Genesis

3. Low Pass Filter Design Requirement • fc=1 MHz • Attenuation of 9 dB at 2 MHz. • RS=50 Ohms • RL=25 Ohms

4. Determine the number of elements in the filter (Same as before) 9 dB of attenuation at f/fc of 2.

5. Use a Low Pass Prototype Value for RS≠RL

6. Comparison: RS=RL

7. Frequency and Impedance Scaling

8. Matlab Calculation

9. Low Frequency Response

10. Comments about Butterworth Filter • A medium –Q filter that is used in designs that require the amplitude response of the filter to be as flat as possible. • The Butterworth response is the flattest passband response available and contains no ripples.

11. Chebyshev Response • Chebyshev filter is a high-Q filter that is used when : • (1) a steeper initial descent into the passband is required • (2) the passband response is no longer required to be flat

12. Comparison of a third order Passband Filter 3 dB of passband ripples and 10 dB improvement in attenuation

13. Design Methodology • Even though attenuation can be calculated analytically, we will use the graphical method. • Even order Chebyshev filters can not have equal termination (RS≠RL)

14. Low Pass Filter Design Requirement • fc=1 MHz • Attenuation of 9 dB at 2 MHz. • RS=50 Ohms • RL=25 Ohms • Less than 0.1 dB of Ripple • Design it with a Chebychev Filter

15. 0.1 dB Attenuation Chart

16. 0.1 dB, n=2, Chebyshev

17. Matlab Calculation

18. Chbysehv, 0.1 dB Ripple, LPF ripple

19. Typical Bandpass Specifications When a low-pass design is transformed into a bandpass design, the attenuation bandwidth ratios remain the same.

20. Butterworth Vs. Chebyshev Butterworth: n=4, 40 dB Chebyshev: n=4, 48 dB, but RS≠RL We have to settle for n=5, 62 dB.

21. Chebyshev, 5th Order, 0.1 dB Ripple

23. Effect of Limited Inductor Quality Factor Assume each inductor has a quality factor of 10.

24. Minimum Required Q

25. Phase of ChebyshevBandpass Filter Phase is not very linear during the passband! You can get a lot of distortion!

26. Bessel Filter • Bessel Filter is designed to achieve linear phase at the expense of limited selectivity!

27. Low Pass Filter Design Requirement • fc=1 MHz • Attenuation of 9 dB at 2 MHz. • RS=50 Ohms • RL=25 Ohms

28. Attenuation Possible to achieve 9dB

29. Bessel LPF Prototype Elementary Value

30. Matlab Calculation

31. Bessel LPF 6.8 dB of attenuation at f/fc=2

32. Phase of Bessel LPF (n=2)

33. Genesys • BPF Design Example

34. Typical Bandpass Specifications When a low-pass design is transformed into a bandpass design, the attenuation bandwidth ratios remain the same.

35. Butterworth Vs. Chebyshev Butterworth: n=4, 40 dB Chebyshev: n=4, 48 dB, but RS≠RL We have to settle for n=5, 62 dB.

36. Start Geneysis Select Passive Filter Start Genesys

37. Filter Properties

38. Comparison Synthesized Via Genesis Synthesized using Charts

39. Change Settings

40. QL=50, QC=100

41. QL=10, QC=100

42. Export Schematic to ADS (Not sure. ADS project is open)

43. Tune • You can also fine-tune the value of a component and see how it changes the filter response