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Active Filter Design Using PSpice

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Tsuyoshi Horigome
Tsuyoshi Horigome

Active Filter Design Using PSpice

Design
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Active Filter Design All Rights Reserved Copyright (C) Bee Technologies Corporation 2010 1 Design Services
Contents Slide # 1. Filter Design Category.............................................................................. 2. Active Filter Design Flow-Chart............................................................. 3. Passive Low Pass Filter Design............................................................... 3.1 Specifications : .................................................................................. 3.2 Calculation : ...................................................................................... . 3.3 Verification : ...................................................................................... . 3.4 Optimization : .................................................................................... 3.5 Elements test : ................................................................................... 3 4 5 5 6 7 8-9 10-11 12 2All Rights Reserved Copyright (C) Bee Technologies Corporation 2009
1.Filter Design Category Available Filter Types • Low Pass Filter • High Pass Filter • Band Pass Filter • Band Reject Filter Approximation • Butterworth - No ripple - Smooth roll-off (rate of 20dB/decade for every pole) • Chebyshev - Pass-band ripple specification would be required. - Steeper roll-of Topology • Passive - High frequency range (> 1 MHz) - Source and load impedance specifications would be required • Active - Low frequency range (1 Hz to 1 MHz) - Unity-Gain Sallen-Key configuration (see Figure 1.0) Number of Order • 2nd -10th All Rights Reserved Copyright (C) Bee Technologies Corporation 2010 3 R 1 R 2 C 2 0 C 1 in + - U 1 A M P S I M P o u t Fig.1.0 Unity-Gain Sallen-Key Active Filter (2nd -Order Active LPF)
2.Active Filter Design Flow Chart All Rights Reserved Copyright (C) Bee Technologies Corporation 2010 4 2. Circuit design and calculation2. Circuit design and calculation 3. Verification3. Verification 4. Optimize with standard capacitor value4. Optimize with standard capacitor value 5. Elements test (± 5%)5. Elements test (± 5%) Meet the spec?Meet the spec? No Yes Satisfy?Satisfy? Yes YESYES Result : Filter circuit with all element values Result : Filter circuit with all element values Use 1% CapacitorUse 1% Capacitor 1.Customer’s specification 1.Customer’s specification No
Fr equenc y 100Hz 1. 0KHz 10KHz db( v ( out ) ) - 40 - 30 - 20 - 10 0 3.Active Low Pass Filter Design (1/5) 3.1 Specifications : All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 5 Figure 2 Low-pass filter response and specification Pass-band Region Stop-band Region Pass-band edge frequency = 1 MHz Pass-band gain = -3 dB Stop-band edge frequency = 2.5 MHz Stop-band gain = -30 dB •Pass-band edge frequency : 1 kHz (fCutoff) - Pass-band gain : -3 dB •Stop-band edge frequency : 2.5 kHz - Stop-band gain : -30 dB •Load and Source Condition : - Source Type : Voltage - Filter Load Impedance : 50 Ω - Resistance in the filter : 5 kΩ STEP1.Customer’s specification STEP1.Customer’s specification
R 1 5 k R 2 5 k R 5 5 0 0 C 1 2 9 . 4 2 n F 0 C 2 3 4 . 4 4 n F R 3 5 k R 4 5 k C 3 1 2 . 1 8 n F 0 C 4 8 3 . 1 7 n F + - U 2 A M P S I M P o u tV s o u r c e 0 in + - U 1 A M P S I M P 3. Active Low Pass Filter Design (2/5) 3.2 Calculation : All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 6 Figure 3.1 Low-pass filter circuit with calculated element-values (Butterworth approximation). Figure 3.2 Low-pass filter circuit with calculated element-values (Chebyshev approximation). •R1 = R2 = R3 = R4 = 5kΩ •C1 = 29.42nF •C2 = 34.44nF •C3 = 83.17nF •C4 = 12.18nF STEP2. Circuit design and calculation STEP2. Circuit design and calculation •R1 = R2 = R3 = R4 = 5kΩ •C1 = 47nF •C2 = 82nF •C3 = 5.1nF •C4 = 220nF R 1 5 k R 2 5 k R 5 5 0 0 C 1 4 7 n F 0 C 2 8 2 n F R 3 5 k R 4 5 k 0 C 3 5 . 1 n F C 4 2 2 0 n F + - U 3 A M P S I M P o u t 2 + - U 4 A M P S I M P
Fr equenc y 100Hz 1. 0KHz 10KHz db( v ( out ) ) db ( v ( out 2) ) - 60 - 40 - 20 - 0 3. Active Low Pass Filter Design (3/5) All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 7 Figure 4 Response and specification of the calculated circuits. Butterworth (1MHz,-3.013dB) Chebyshev : (1MHz,-2.818dB) (2.5MHz,-44dB) (2.5MHz,-31.858dB) 3.3 Verification : • Frequency Response Simulation Pass-band Ripple (-1.23dB) •Pass-band edge frequencies : 1 MHz •Pass-band gains : -3 dB  •Stop-band edge frequencies : 2.5 MHz •Stop-band gains : < -30 dB  •Butterworth Approximation - No ripple  - Roll-off rate is 80dB/decade  •Chebyshev Approximation - Pass-band ripple : -1.23dB  - Steeper roll-of  — Butterworth Approximation — Butterworth Approximation STEP3. Verification STEP3. Verification
3.4 Optimization : - Use standard capacitor values (E-24 Capacitor Values) - Optimize inductor values R 1 5 k R 2 5 k R 5 5 0 0 C 1 3 0 n F 0 C 2 3 3 n F R 3 5 k R 4 5 k C 3 1 2 n F 0 C 4 8 2 n F + - U 2 A M P S I M P o u tV s o u r c e 0 in + - U 1 A M P S I M P 3.Passive Low Pass Filter Design (4/5) All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 8 Figure 5.1 Low-pass filter circuit with optimized element-values (Butterworth approximation). Figure 5.2 Low-pass filter circuit with calculated element-values (Chebyshev approximation). STEP4. Optimize with standard capacitor value (then verify) STEP4. Optimize with standard capacitor value (then verify) •R1 = R2 = R3 = R4 = 5kΩ •C1 = 47nF •C2 = 82nF •C3 = 5.1nF •C4 = 220nF R 1 5 k R 2 5 k R 5 5 0 0 C 1 4 7 n F 0 C 2 8 2 n F R 3 5 k R 4 5 k 0 C 3 5 . 1 n F C 4 2 2 0 n F + - U 3 A M P S I M P o u t 2 + - U 4 A M P S I M P •R1 = R2 = R3 = R4 = 5kΩ •C1 = 30nF •C2 = 33nF •C3 = 12nF •C4 = 82nF
Fr equenc y 100Hz 1. 0KHz 10KHz db( v ( out ) ) db ( v ( out 2) ) - 60 - 40 - 20 - 0 3.Passive Low Pass Filter Design (4/5) All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 9 Figure 6 Response and specification of the optimized circuits. 3.4 Optimization : • Frequency Response Simulation •Pass-band edge frequencies : 1 MHz •Pass-band gains : -3 dB  •Stop-band edge frequencies : 2.5 MHz •Stop-band gains : < -30 dB  •Butterworth Approximation - No ripple  - Roll-off rate is 80dB/decade  •Chebyshev Approximation - Pass-band ripple : -1.23dB  - Steeper roll-of  Butterworth (1MHz,-3.06dB) Chebyshev : (1MHz,-2.818dB) (2.5MHz,-44dB) (2.5MHz,-31.521dB) Pass-band Ripple (-1.23dB) — Butterworth Approximation — Butterworth Approximation
3.5 Elements test : - ± 5% test for each capacitor value. R 1 5 k R 2 5 k R 5 5 0 0 C 1 4 7 n F 0 C 2 8 2 n F R 3 5 k R 4 5 k 0 C 3 5 . 1 n F C 4 2 2 0 n F + - U 3 A M P S I M P o u t 2 + - U 4 A M P S I M P R 1 5 k R 2 5 k R 5 5 0 0 C 1 3 0 n F 0 C 2 3 3 n F R 3 5 k R 4 5 k C 3 1 2 n F 0 C 4 8 2 n F + - U 2 A M P S I M P o u tV s o u r c e 0 in + - U 1 A M P S I M P 3. Active Low Pass Filter Design (5/5) All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 10 Figure 7.1 Low-pass filter circuit with ± 5% of the capacitance-values (Butterworth approximation). Figure 7.1 Low-pass filter circuit with ± 5% of the capacitance-values (Chebyshev approximation). STEP5. Elements test (± 5%) STEP5. Elements test (± 5%) •R1 = R2 = R3 = R4 = 5kΩ •C1 = 47nF (± 5%) •C2 = 82nF (± 5%) •C3 = 5.1nF (± 5%) •C4 = 220nF (± 5%) •R1 = R2 = R3 = R4 = 5kΩ •C1 = 30nF (± 5%) •C2 = 33nF (± 5%) •C3 = 12nF (± 5%) •C4 = 82nF (± 5%)
Fr eque nc y 1 00Hz 1. 0KHz 1 0KHz db( v ( o ut 2 ) ) - 6 0 - 4 0 - 2 0 - 0 Fr eq ue nc y 1 00 Hz 1. 0KHz 10 KHz db ( v ( ou t ) ) - 60 - 40 - 20 - 0 3.Passive Low Pass Filter Design (5/5) All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 11 Figure 8 Response and specification when the element values are error with ±5%. 3.5 Elements test : • Frequency Response Simulation, compare to -5% and +5% of all element values. Butterworth — +5% — standard values — -5% Pass-band gain (-3 dB) Cutoff frequency : 0.9486M, 1M, 1.0485M Chebyshev — +5% — standard values — -5% Cutoff frequency : 0.9564M, 1M, 1.0567M Pass-band gain (-3 dB)
R 1 5 k R 2 5 k R 5 5 0 0 C 1 4 7 n F 0 C 2 8 2 n F R 3 5 k R 4 5 k 0 C 3 5 . 1 n F C 4 2 2 0 n F + - U 3 A M P S I M P o u t 2 + - U 4 A M P S I M P R 1 5 k R 2 5 k R 5 5 0 0 C 1 3 0 n F 0 C 2 3 3 n F R 3 5 k R 4 5 k C 3 1 2 n F 0 C 4 8 2 n F + - U 2 A M P S I M P o u tV s o u r c e 0 in + - U 1 A M P S I M P •R1 = R2 = R3 = R4 = 5kΩ •C1 = 47nF (± 5%) •C2 = 82nF (± 5%) •C3 = 5.1nF (± 5%) •C4 = 220nF (± 5%) •R1 = R2 = R3 = R4 = 5kΩ •C1 = 30nF (± 5%) •C2 = 33nF (± 5%) •C3 = 12nF (± 5%) •C4 = 82nF (± 5%) 3.Passive Low Pass Filter Design 3.6 Result : • Low-pass filter circuit with all element values. All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 12 Figure 8.1 Low-pass filter circuit with all element-values (Butterworth approximation). Figure 8.1 Low-pass filter circuit all element-values (Chebyshev approximation). ± 5% ± 5% ± 5% ± 5% ± 5% ± 5% ± 5% Result : Filter circuit with all element values Result : Filter circuit with all element values ± 5%

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Active Filter Design Using PSpice

  • 1. Active Filter Design All Rights Reserved Copyright (C) Bee Technologies Corporation 2010 1 Design Services
  • 2. Contents Slide # 1. Filter Design Category.............................................................................. 2. Active Filter Design Flow-Chart............................................................. 3. Passive Low Pass Filter Design............................................................... 3.1 Specifications : .................................................................................. 3.2 Calculation : ...................................................................................... . 3.3 Verification : ...................................................................................... . 3.4 Optimization : .................................................................................... 3.5 Elements test : ................................................................................... 3 4 5 5 6 7 8-9 10-11 12 2All Rights Reserved Copyright (C) Bee Technologies Corporation 2009
  • 3. 1.Filter Design Category Available Filter Types • Low Pass Filter • High Pass Filter • Band Pass Filter • Band Reject Filter Approximation • Butterworth - No ripple - Smooth roll-off (rate of 20dB/decade for every pole) • Chebyshev - Pass-band ripple specification would be required. - Steeper roll-of Topology • Passive - High frequency range (> 1 MHz) - Source and load impedance specifications would be required • Active - Low frequency range (1 Hz to 1 MHz) - Unity-Gain Sallen-Key configuration (see Figure 1.0) Number of Order • 2nd -10th All Rights Reserved Copyright (C) Bee Technologies Corporation 2010 3 R 1 R 2 C 2 0 C 1 in + - U 1 A M P S I M P o u t Fig.1.0 Unity-Gain Sallen-Key Active Filter (2nd -Order Active LPF)
  • 4. 2.Active Filter Design Flow Chart All Rights Reserved Copyright (C) Bee Technologies Corporation 2010 4 2. Circuit design and calculation2. Circuit design and calculation 3. Verification3. Verification 4. Optimize with standard capacitor value4. Optimize with standard capacitor value 5. Elements test (± 5%)5. Elements test (± 5%) Meet the spec?Meet the spec? No Yes Satisfy?Satisfy? Yes YESYES Result : Filter circuit with all element values Result : Filter circuit with all element values Use 1% CapacitorUse 1% Capacitor 1.Customer’s specification 1.Customer’s specification No
  • 5. Fr equenc y 100Hz 1. 0KHz 10KHz db( v ( out ) ) - 40 - 30 - 20 - 10 0 3.Active Low Pass Filter Design (1/5) 3.1 Specifications : All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 5 Figure 2 Low-pass filter response and specification Pass-band Region Stop-band Region Pass-band edge frequency = 1 MHz Pass-band gain = -3 dB Stop-band edge frequency = 2.5 MHz Stop-band gain = -30 dB •Pass-band edge frequency : 1 kHz (fCutoff) - Pass-band gain : -3 dB •Stop-band edge frequency : 2.5 kHz - Stop-band gain : -30 dB •Load and Source Condition : - Source Type : Voltage - Filter Load Impedance : 50 Ω - Resistance in the filter : 5 kΩ STEP1.Customer’s specification STEP1.Customer’s specification
  • 6. R 1 5 k R 2 5 k R 5 5 0 0 C 1 2 9 . 4 2 n F 0 C 2 3 4 . 4 4 n F R 3 5 k R 4 5 k C 3 1 2 . 1 8 n F 0 C 4 8 3 . 1 7 n F + - U 2 A M P S I M P o u tV s o u r c e 0 in + - U 1 A M P S I M P 3. Active Low Pass Filter Design (2/5) 3.2 Calculation : All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 6 Figure 3.1 Low-pass filter circuit with calculated element-values (Butterworth approximation). Figure 3.2 Low-pass filter circuit with calculated element-values (Chebyshev approximation). •R1 = R2 = R3 = R4 = 5kΩ •C1 = 29.42nF •C2 = 34.44nF •C3 = 83.17nF •C4 = 12.18nF STEP2. Circuit design and calculation STEP2. Circuit design and calculation •R1 = R2 = R3 = R4 = 5kΩ •C1 = 47nF •C2 = 82nF •C3 = 5.1nF •C4 = 220nF R 1 5 k R 2 5 k R 5 5 0 0 C 1 4 7 n F 0 C 2 8 2 n F R 3 5 k R 4 5 k 0 C 3 5 . 1 n F C 4 2 2 0 n F + - U 3 A M P S I M P o u t 2 + - U 4 A M P S I M P
  • 7. Fr equenc y 100Hz 1. 0KHz 10KHz db( v ( out ) ) db ( v ( out 2) ) - 60 - 40 - 20 - 0 3. Active Low Pass Filter Design (3/5) All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 7 Figure 4 Response and specification of the calculated circuits. Butterworth (1MHz,-3.013dB) Chebyshev : (1MHz,-2.818dB) (2.5MHz,-44dB) (2.5MHz,-31.858dB) 3.3 Verification : • Frequency Response Simulation Pass-band Ripple (-1.23dB) •Pass-band edge frequencies : 1 MHz •Pass-band gains : -3 dB  •Stop-band edge frequencies : 2.5 MHz •Stop-band gains : < -30 dB  •Butterworth Approximation - No ripple  - Roll-off rate is 80dB/decade  •Chebyshev Approximation - Pass-band ripple : -1.23dB  - Steeper roll-of  — Butterworth Approximation — Butterworth Approximation STEP3. Verification STEP3. Verification
  • 8. 3.4 Optimization : - Use standard capacitor values (E-24 Capacitor Values) - Optimize inductor values R 1 5 k R 2 5 k R 5 5 0 0 C 1 3 0 n F 0 C 2 3 3 n F R 3 5 k R 4 5 k C 3 1 2 n F 0 C 4 8 2 n F + - U 2 A M P S I M P o u tV s o u r c e 0 in + - U 1 A M P S I M P 3.Passive Low Pass Filter Design (4/5) All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 8 Figure 5.1 Low-pass filter circuit with optimized element-values (Butterworth approximation). Figure 5.2 Low-pass filter circuit with calculated element-values (Chebyshev approximation). STEP4. Optimize with standard capacitor value (then verify) STEP4. Optimize with standard capacitor value (then verify) •R1 = R2 = R3 = R4 = 5kΩ •C1 = 47nF •C2 = 82nF •C3 = 5.1nF •C4 = 220nF R 1 5 k R 2 5 k R 5 5 0 0 C 1 4 7 n F 0 C 2 8 2 n F R 3 5 k R 4 5 k 0 C 3 5 . 1 n F C 4 2 2 0 n F + - U 3 A M P S I M P o u t 2 + - U 4 A M P S I M P •R1 = R2 = R3 = R4 = 5kΩ •C1 = 30nF •C2 = 33nF •C3 = 12nF •C4 = 82nF
  • 9. Fr equenc y 100Hz 1. 0KHz 10KHz db( v ( out ) ) db ( v ( out 2) ) - 60 - 40 - 20 - 0 3.Passive Low Pass Filter Design (4/5) All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 9 Figure 6 Response and specification of the optimized circuits. 3.4 Optimization : • Frequency Response Simulation •Pass-band edge frequencies : 1 MHz •Pass-band gains : -3 dB  •Stop-band edge frequencies : 2.5 MHz •Stop-band gains : < -30 dB  •Butterworth Approximation - No ripple  - Roll-off rate is 80dB/decade  •Chebyshev Approximation - Pass-band ripple : -1.23dB  - Steeper roll-of  Butterworth (1MHz,-3.06dB) Chebyshev : (1MHz,-2.818dB) (2.5MHz,-44dB) (2.5MHz,-31.521dB) Pass-band Ripple (-1.23dB) — Butterworth Approximation — Butterworth Approximation
  • 10. 3.5 Elements test : - ± 5% test for each capacitor value. R 1 5 k R 2 5 k R 5 5 0 0 C 1 4 7 n F 0 C 2 8 2 n F R 3 5 k R 4 5 k 0 C 3 5 . 1 n F C 4 2 2 0 n F + - U 3 A M P S I M P o u t 2 + - U 4 A M P S I M P R 1 5 k R 2 5 k R 5 5 0 0 C 1 3 0 n F 0 C 2 3 3 n F R 3 5 k R 4 5 k C 3 1 2 n F 0 C 4 8 2 n F + - U 2 A M P S I M P o u tV s o u r c e 0 in + - U 1 A M P S I M P 3. Active Low Pass Filter Design (5/5) All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 10 Figure 7.1 Low-pass filter circuit with ± 5% of the capacitance-values (Butterworth approximation). Figure 7.1 Low-pass filter circuit with ± 5% of the capacitance-values (Chebyshev approximation). STEP5. Elements test (± 5%) STEP5. Elements test (± 5%) •R1 = R2 = R3 = R4 = 5kΩ •C1 = 47nF (± 5%) •C2 = 82nF (± 5%) •C3 = 5.1nF (± 5%) •C4 = 220nF (± 5%) •R1 = R2 = R3 = R4 = 5kΩ •C1 = 30nF (± 5%) •C2 = 33nF (± 5%) •C3 = 12nF (± 5%) •C4 = 82nF (± 5%)
  • 11. Fr eque nc y 1 00Hz 1. 0KHz 1 0KHz db( v ( o ut 2 ) ) - 6 0 - 4 0 - 2 0 - 0 Fr eq ue nc y 1 00 Hz 1. 0KHz 10 KHz db ( v ( ou t ) ) - 60 - 40 - 20 - 0 3.Passive Low Pass Filter Design (5/5) All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 11 Figure 8 Response and specification when the element values are error with ±5%. 3.5 Elements test : • Frequency Response Simulation, compare to -5% and +5% of all element values. Butterworth — +5% — standard values — -5% Pass-band gain (-3 dB) Cutoff frequency : 0.9486M, 1M, 1.0485M Chebyshev — +5% — standard values — -5% Cutoff frequency : 0.9564M, 1M, 1.0567M Pass-band gain (-3 dB)
  • 12. R 1 5 k R 2 5 k R 5 5 0 0 C 1 4 7 n F 0 C 2 8 2 n F R 3 5 k R 4 5 k 0 C 3 5 . 1 n F C 4 2 2 0 n F + - U 3 A M P S I M P o u t 2 + - U 4 A M P S I M P R 1 5 k R 2 5 k R 5 5 0 0 C 1 3 0 n F 0 C 2 3 3 n F R 3 5 k R 4 5 k C 3 1 2 n F 0 C 4 8 2 n F + - U 2 A M P S I M P o u tV s o u r c e 0 in + - U 1 A M P S I M P •R1 = R2 = R3 = R4 = 5kΩ •C1 = 47nF (± 5%) •C2 = 82nF (± 5%) •C3 = 5.1nF (± 5%) •C4 = 220nF (± 5%) •R1 = R2 = R3 = R4 = 5kΩ •C1 = 30nF (± 5%) •C2 = 33nF (± 5%) •C3 = 12nF (± 5%) •C4 = 82nF (± 5%) 3.Passive Low Pass Filter Design 3.6 Result : • Low-pass filter circuit with all element values. All Rights Reserved Copyright (C) Bee Technologies Corporation 2009 12 Figure 8.1 Low-pass filter circuit with all element-values (Butterworth approximation). Figure 8.1 Low-pass filter circuit all element-values (Chebyshev approximation). ± 5% ± 5% ± 5% ± 5% ± 5% ± 5% ± 5% Result : Filter circuit with all element values Result : Filter circuit with all element values ± 5%