Experiment #10: Passive Filter Design

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SCHOOL OF ENGINEEING AND APPLIED SCIENCE DEPATMENT OF ELECTICAL AND COMPUTE ENGINEEING ECE 2110: CICUIT THEOY LABOATOY Experiment #10: Passive Filter Design EQUIPMENT Lab Equipment Equipment Description (1) Function Generator Agilent 33522A Function/Arbitrary Waveform Generator (1) Digital Multimeter (DMM) Keithley Model 175 Digital Multimeter (DMM) (1) Digital Oscilloscope Agilent DSO1024A Digital Oscilloscope (1) Breadboard Prototype Breadboard (1) BNC T-Connector One input to two output BNC connector (1) Test Leads Banana to Alligator Lead Set (2) Test Leads BNC to Mini-Grabber Lead Set (1) BNC Cable BNC to BNC Cable Table 1 Equipment List COMPONENTS Type Value Symbol Name Multisim Part Description esistor 3.3kΩ Basic/esistor --- esistor 510Ω 2 Basic/esistor --- Capacitor 820pF C Basic/Capacitor Ceramic Disk, 821J Inductor 4.7mH L Basic/Inductor --- Table 2 Component List OBJECTIVES Find the frequency response of a series C and L circuit Plot the magnitude and phase response of a series C and L circuit Design, build, and test a low-pass filter Design, build, and test a high-pass filter Find the frequency response of a series and parallel resonance circuit Plot the magnitude and phase response of a series and parallel resonance circuit Design, build, and test a band-pass filter 1

INTODUCTION This lab will focus on understanding the behavior of common filters and how we can create filters with simple passive components such as capacitors, inductors, and resistors. Filters An electric filter modifies the frequency content of a signal. Figure 1 shows the four main types of filters: high-pass (HPF), low-pass (LPF), band-pass (BPF), and band-stop (notch). A low-pass filter allows low frequencies to pass to the load while attenuating high frequencies. A high-pass filter allows high frequencies to pass while attenuating low frequencies. A band-pass filter allows a range of frequencies to pass while attenuating frequencies outside of that range. A band-stop filter attenuates a range of frequencies while passing frequencies outside of that range. In Figure 1, the x-axes represent frequency (ω) in radians per second. By convention, frequency is represented by the variable ω when its units are radians per second and f when its units are Hertz. The y-axes represent the gain of each filter. In this instance, gain is defined as the voltage across the load divided by the input voltage. As is shown in the figure, the gain of a filter is different at different frequencies. Figure 1 Gain esponses (Thomas et al., page 602) 2

Common Filter Terms The range of frequencies that are attenuated is called the stopband. The range of frequencies that pass to the load is called the passband. The cutoff frequency (ω c or f c ) is the frequency at the transition between the stopband and passband (band-pass and band-stop filters will have two cutoff frequencies). An ideal filter passes frequencies in the passband without modifying their magnitude (Gain = 1) and completely attenuates frequencies in the stopband (Gain = 0). However, ideal filters do not exist in practice. One convention is to define cutoff frequencies as the frequency at which the magnitude of the voltage at the load is decreased by 3dB from its maximum value V max, called the -3dB frequency. 2 There are other ways to define the cutoff frequency, so when reading or specifying ω c, make sure that you understand which definition is being used. With respect to a filter, a decibel (db) is defined as ten times the logarithm to base 10 of the ratio of the output power to the input power. When the input and output powers are delivered to an equal resistance, a decibel can be defined with respect to the voltage gain of the filter. This derivation is shown in Equation 1. Using this definition, it can be shown that a 3dB reduction in voltage is approximately equal to a reduction of 1 in voltage or a reduction of half the 2 power. # of db = 10 log 10 P out P in = 10 log 10 2 2 V in = 10 log 10 = 10 log V in V 10 10 log in V 10 = 20 log in V 10 in V in Equation 1 Decibel Derivation (Thomas et al., page 603) The center frequency (ω 0 or f 0 ) is the frequency where the voltage at the load is at its maximum value. The bandwidth (B) of a filter is the difference between the two cutoff frequencies. The quality factor (Q) is the ratio of the center frequency to the bandwidth (Q = ω 0 ). The gain function of a filter is the ratio of B the magnitude of the frequency response of the filter at the load to the magnitude of the frequency response of the source. Note: For passive circuits, the gain must be less than one. As an example, the magnitude and phase of the voltage at the load of a series L circuit, given a source voltage of 1 0 V, is shown in Figure P1. The red line illustrates the voltage across the inductor, and the blue line is the voltage across the resistor (load). The magnitude plot shows that the circuit has a cutoff frequency (-3dB frequency) of approximately 30kHz, a passband from 0 to 30kHz, and a stopband from 30kHz to Infinity. f c Figure P1: Low-Pass Filter - magnitude (top), phase (bottom) 3

PELAB eview the provided Excel spreadsheet (lab10example.xlsx). It demonstrates a partial solution to Part I of the prelab. Using this spreadsheet as an example, produce similar spreadsheets for Parts II-IV. Part I Series C Circuit C Figure P.1 Series C Circuit 1. Compute the equivalent impedance Z TH for the circuit in Figure P.1. 2. Establish the general equations for the phasor voltages V C and V associated with C and (leave in rectangular form). 3. Use Excel to calculate the amplitudes and phase differences of the phasor voltages (V C, V ) for frequencies from 1kHz to 10MHz. Use the following increments as shown in the sample Excel sheet: 1kHz, 2kHz,, 9kHz,10kHz, 20kHz,, 90kHz, 100kHz, 200kHz,..., 900kHz,1MHz, 2MHz,,10MHz. Verify that V C V = V in for all frequencies using Excel. Hint: eview the Excel help files for the commands COMPLEX, IMDIV, IMPODUCT, IMEAL, IMAGINAY, IMABS, IMTAN2, and PI. V in = 1 0 V C = 820pF = 3.3kΩ 4. Plot a graph of amplitudes versus frequency in Excel (use a legend to identify the different curves). Find the -3dB frequency for the curve ( ). 5. Plot a graph of phase differences versus frequency in Excel (include a legend). 4

Part II Series L Circuit L Figure P.2 Series L Circuit 1. Compute the equivalent impedance Z TH for the circuit in Figure P.1. 2. Establish the general equations for the phasor voltages V L and V associated with L and (leave in rectangular form). 3. Use Excel to calculate the amplitudes and phase differences of the phasor voltages (V L, V ) for frequencies from 1kHz to 10MHz. Use the following increments as shown in the sample Excel sheet: 1kHz, 2kHz,, 9kHz,10kHz, 20kHz,, 90kHz, 100kHz, 200kHz,..., 900kHz,1MHz, 2MHz,,10MHz. Verify that V L V = V in for all frequencies using Excel. Hint: eview the Excel help files for the commands COMPLEX, IMDIV, IMPODUCT, IMEAL, IMAGINAY, IMABS, IMTAN2, and PI. V in = 1 0 V L = 4.7mH = 3.3kΩ 4. Plot a graph of amplitudes versus frequency in Excel (use a legend to identify the different curves). Find the -3dB frequency for the curve ( ). 5. Plot a graph of phase differences versus frequency in Excel (include a legend). 5

Part III Series esonant Circuit L C Figure P.3 Series esonant Circuit 1. Compute the equivalent impedance Z TH for the circuit in Figure P.1. 2. Establish the general equations for the phasor voltages V L, V C, and V associated with L, C, and (leave in rectangular form). 3. Use Excel to calculate the amplitudes and phase differences of the phasor voltages (V L, V C, and V ) for frequencies from 1kHz to 10MHz. Use the following increments as shown in the sample Excel sheet: 1kHz, 2kHz,, 9kHz,10kHz, 20kHz,, 90kHz, 100kHz, 200kHz,..., 900kHz,1MHz, 2MHz,,10MHz. Verify that V L V C V = V in for all frequencies using Excel. Hint: eview the Excel help files for the commands COMPLEX, IMDIV, IMPODUCT, IMEAL, IMAGINAY, IMABS, IMTAN2, and PI. V in = 1 0 V L = 4.7mH C = 820pF = 3.3kΩ 4. Plot a graph of amplitudes versus frequency in Excel (use a legend to identify the different curves). Find the -3dB frequency for the curve ( ). 5. Plot a graph of phase differences versus frequency in Excel (include a legend). 6

Part IV Parallel esonant Circuit C L Figure P.4 Parallel esonant Circuit 1. Compute the equivalent impedance Z TH for the circuit in Figure P.1. 2. Establish the general equations for the phasor voltages V L, V C, and V associated with L, C, and (leave in rectangular form). 3. Use Excel to calculate the amplitudes and phase differences of the phasor voltages (V L, V C, and V ) for frequencies from 1kHz to 10MHz. Use the following increments as shown in the sample Excel sheet: 1kHz, 2kHz,, 9kHz,10kHz, 20kHz,, 90kHz, 100kHz, 200kHz,..., 900kHz,1MHz, 2MHz,,10MHz. Verify that (V L or V C ) V = V in for all frequencies using Excel. Hint: eview the Excel help files for the commands COMPLEX, IMDIV, IMPODUCT, IMEAL, IMAGINAY, IMABS, IMTAN2, and PI. V in = 1 0 V L = 4.7mH C = 820pF = 510Ω 4. Plot a graph of amplitudes versus frequency in Excel (use a legend to identify the different curves). Find the -3dB frequency for the curve ( ). 5. Plot a graph of phase differences versus frequency in Excel (include a legend). 7

LAB Part I Series C Circuit Measurement C Figure 1.1 Series C Circuit 1. Build the circuit in Figure 1.1 on a breadboard using the following components: V in = 1V pk C = 820pF = 3.3kΩ 2. Measure (magnitude and phase) for different frequencies from 1kHz to 10MHz. 3. Plot magnitude versus frequency in Excel using your collected data. Find the -3dB frequency. 4. Plot the phase difference versus frequency in Excel using your collected data. Frequency Magnitude Phase 1kHz 10kHz 20kHz 30kHz 40kHz 50kHz 60kHz 70kHz 80kHz 90kHz 100kHz 300kHz 1MHz 5MHz 10MHz Table 1.1 Series C Circuit Data 8

Part II Series L Circuit Measurement L Figure 2.1 Series L Circuit 1. Build the circuit in Figure 2.1 on a breadboard using the following components: V in = 1V pk L = 4.7mH = 3.3kΩ 2. Measure (magnitude and phase) for different frequencies from 1kHz to 10MHz. 3. Plot magnitude versus frequency in Excel using your collected data. Find the -3dB frequency. 4. Plot the phase difference versus frequency in Excel using your collected data. Frequency Magnitude Phase 1kHz 10kHz 20kHz 40kHz 60kHz 80kHz 100kHz 200kHz 300kHz 500kHz 600kHz 800kHz 1MHz 5MHz 10MHz Table 2.1 Series L Circuit Data 9

Part III Series esonant Circuit Measurement L C Figure 3.1 Series esonant Circuit 1. Build the circuit in Figure 3.1 on a breadboard using the following components: V in = 1V pk L = 4.7mH C = 820pF = 3.3kΩ 2. Measure (magnitude and phase) for different frequencies from 1kHz to 10MHz. 3. Plot magnitude versus frequency in Excel using your collected data. Find the -3dB frequency. 4. Plot the phase difference versus frequency in Excel using your collected data. 5. Find the cutoff frequencies (ω C1 and ω C2 ), Bandwidth (B), center frequency (ω 0 ) and Quality factor (Q). Frequency Magnitude Phase 1kHz 5kHz 10kHz 20kHz 40kHz 70kHz 80kHz 90kHz 100kHz 200kHz 400kHz 500kHz 1MHz 5MHz 10MHz Table 3.1 Series esonant Circuit Data 10

Part IV Series Parallel Circuit Measurement C L Figure 4.1 Parallel esonant Circuit 1. Build the circuit in Figure 4.1 on a breadboard using the following components: V in = 1V pk L = 4.7mH C = 820pF = 510Ω 2. Measure (magnitude and phase) for different frequencies from 1kHz to 10MHz. 3. Plot magnitude versus frequency in Excel using your collected data. Find the -3dB frequency. 4. Plot the phase difference versus frequency in Excel using your collected data. 5. Find the cutoff frequencies (ω C1 and ω C2 ), Bandwidth (B), center frequency (ω 0 ) and Quality factor (Q). Frequency Magnitude Phase 1kHz 5kHz 10kHz 30kHz 40kHz 60kHz 80kHz 90kHz 100kHz 200kHz 100kHz 500kHz 1MHz 5MHz 10MHz Table 4.1 Series Parallel Circuit Data 11

Part V Low-Pass Filter Design 1. Use Multisim to design and simulate a high-pass filter that meets the following specifications: Show all steps of your design. Applied Voltage: 1V rms -3dB Frequency: 500Hz Tolerances: 5% 2. Build, test, and demonstrate this circuit to the GTA. Part VI High-Pass Filter Design 1. Use Multisim to design and simulate a high-pass filter that meets the following specifications: Show all steps of your design. Applied Voltage: 1V rms -3dB Frequency: 20kHz Tolerances: 5% 2. Build, test, and demonstrate this circuit to the GTA. Part VII Band-Pass Filter Design 1. Use Multisim to design and simulate a band-pass filter that meets the following specifications: Show all steps of your design. Applied Voltage: 1V rms Quality Factor: 1 Bandwidth: 15kHz Tolerances: 5% 2. Build, test, and demonstrate this circuit to the GTA. 12

POST-LAB ANALYSIS 1. Compare the calculated results to the measured results and explain any and all differences. 2. Describe the motivation behind defining the cutoff frequency at the point where the gain is -3dB as opposed to -4dB or -5dB. 3. What type of filter would you want to implement if you observed high frequency noise in your voltage signal? 4. Describe a situation where a band-pass filter would be desired. 5. Does it make sense to define the bandwidth of a high-pass filter? Explain. 6. Describe the relationship between ω C and f C. Be sure to include the mathematical relationship. 7. Hum noise is a common phenomenon in electronic devices especially hi-fi equipment. The noise comes from the line (110 Vacrms @ 60 Hz). Using the information you have learned so far, how could you eliminate this noise? 8. Describe how the quality factor (Q) is used to distinguish between narrow-band and wide-band filters. EFEENCES [1] Thomas, oland E., Albert J. osa, and Gregory J. Toussaint. The Analysis and Design of Linear Circuits. 7 th ed. Hoboken, NJ: Wiley, 2012. 13

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