Introductory Circuit Analysis (13th Edition)
13th Edition
ISBN: 9780133923605
Author: Robert L. Boylestad
Publisher: PEARSON
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Textbook Question
Chapter 22, Problem 21P
Design an R-Clow-pass filter to have a cutoff frequency of
Then sketch the resulting magnitude and phase plot for a frequency range of
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2. A bandpass filter has an upper cutoff frequency of 84.7 kHz and a bandwidth of 12.3 kHz. What is the lower cutoff frequency. Design the ideal waveform using the given frequencies.
The circuit shown in the given figure is an active filter. Assume C=120 pF. Ro-184 kohm. R₁33 kohm, and R2 = 60
kohm.
NOTE: This is a multi-part question. Once an answer is submitted, you will be unable to return to this part.
4-5
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14
www
R₂
2
ww
644
Determine the cutoff frequencies.
The cutoff frequencies w₁ and 2 are
896 106 rad/s and 5.55-105 red/s, respectively.
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Identify the reason for a nonsinusoidal signal being distorted when it passes through a filter.
-The distortion occurs because harmonics are removed or rejected, leaving a different waveshape.
-The distortion occurs because harmonics are synchronized, leaving a different waveshape.
-The distortion occurs because the signal is modulated, leaving a different waveshape.
-The distortion occurs because harmonics are added in the filter, leaving a different waveshape.
Chapter 22 Solutions
Introductory Circuit Analysis (13th Edition)
Ch. 22 - Determine the frequencies (in kHz) at the points...Ch. 22 - Determine log10 for each value of X. 100,000...Ch. 22 - Given N=log10 , determine for each value of N. 3...Ch. 22 - Determine loge for each value of X. a. 100,000 b....Ch. 22 - Determine log1048=log10(8)(6), and compare to...Ch. 22 - Determine log100.2=log1018/90, and compare to...Ch. 22 - Verify that log100.5 is equal to...Ch. 22 - Prob. 8PCh. 22 - Determine the number of bels that relate power...Ch. 22 - Prob. 10P
Ch. 22 - Prob. 11PCh. 22 - Determine the dBm level for an output power of...Ch. 22 - Find the dBu gain of an amplifier that raises the...Ch. 22 - Prob. 14PCh. 22 - If the sound pressure level is increased from...Ch. 22 - What is the required increase in acoustical power...Ch. 22 - Using semilog paper, plot XL versus frequency for...Ch. 22 - For the meter of Fig. 22.8, find the power...Ch. 22 - For the R-C low-pass filter in Fig. 22.105: Sketch...Ch. 22 - Prob. 20PCh. 22 - Design an R-Clow-pass filter to have a cutoff...Ch. 22 - For the low-pass filter in Fig. 22.107: Fig....Ch. 22 - For the R-C high-pass filter in Fig. 22.108:...Ch. 22 - For the network in Fig. 22.109: Determine...Ch. 22 - Design a high-pass R-C filter to have a cutoff or...Ch. 22 - For the high-pass filter in Fig. 22.110: Determine...Ch. 22 - For the band-pass filter in Fig. 22.111: Sketch...Ch. 22 - Design a band-pass filter such as the one...Ch. 22 - For the band-pass filter in Fig. 22.112...Ch. 22 - Prob. 30PCh. 22 - For the band-stop filter in Fig. 22.114: Determine...Ch. 22 - For the band-pass filter in Fig. 22.115: Determine...Ch. 22 - For the network in Fig. 22.45(a), if...Ch. 22 - Prob. 34PCh. 22 - For the low-pass T filter of Fig. 22.116: In...Ch. 22 - Prob. 36PCh. 22 - For the Butterworth filter of Fig. 22.118: Fig....Ch. 22 - Sketch the idealized Bode plot for Av=Vo/Vi for...Ch. 22 - Sketch the response of the magnitude of...Ch. 22 - Sketch the idealized Bode plot for Av=Vo/Vi for...Ch. 22 - Sketch the response of the magnitude of...Ch. 22 - Prob. 42PCh. 22 - Prob. 43PCh. 22 - For the filter in Fig. 22.125: Sketch the curve of...Ch. 22 - Prob. 45PCh. 22 - Prob. 46PCh. 22 - Prob. 47PCh. 22 - A bipolar transistor amplifier has the following...Ch. 22 - A transistor amplifier has a midband gain of 120,...Ch. 22 - Sketch the Bode plot of the following function:...Ch. 22 - Sketch the Bode plot of the following function:...Ch. 22 - Sketch the Bode plot of the following function:...Ch. 22 - Sketch the Bode plot of the following function:...Ch. 22 - Sketch the Bode plot of the following function...Ch. 22 - Prob. 56PCh. 22 - Using schematics, obtain the magnitude and phase...Ch. 22 - Using schematics, obtain the magnitude and phase...Ch. 22 - Prob. 59PCh. 22 - Prob. 60P
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- What is the cut-off frequency of the filter below, if the resistance is 0.33 kOhm and the inductance is 100 nH? L1 my INPUT OUTPUT R1 Figure 2. RL-filter 125 MHz a. 2.5 MHz b. 525 MHz C. 25 MHz d.arrow_forwardThe below 4 figures are the angle of the transfer function of passive filters. Phase (deg) -45- Phase (deg) (Cep) sid 45 10 10 Frequency (radisec) 10² Frequency (rad/sec) Figure-1 shows the frequency response of Figure-2 shows the frequency response of Figure-3 shows the frequency response of Figure-4 shows the frequency response of 4) ( + 4 10 10" 10arrow_forwardFind the cutoff frequency of the following filter 1500 www Select one: O a Ob 10 mH 5000 Hz 15000 Hz 2387.32 Hz O d. 4658.2 Hz 12+ 4arrow_forward
- H.W: A resistor of resistance R=1000 2 is maintained at 17 °C and it shunted by 100 µH inductor. Determine the rms noise voltage across the inductor over a frequency bandwidth of: Ans: 182 x10-9 volt i) ii) iii) 15.9 kHz Ans: 9.22 x10-8 volt Ans: 2.34 x10-6 volt 159 kHz 1590 kHzarrow_forward30. Realize the imego phase fiteo with tue impulse desponse - hon) = son) + Scn-+) - son2) + scna)+SCny) %3Darrow_forward2. Determine the resonance frequency and bandwidth from the graph. Find the Q-factor also. A resonance curve for the parallel LC circuit 1- 09- 08- 0.7 06- 0.5 04 03 01 10 Frequency Frequency: KHz Bandwidth KHz Q-Factor:arrow_forward
- A filter in the form of a series L–R–C circuit is designed to operate at a resonant frequency of 5 kHz. Included within the filter is a 20 mH inductance and 10 ohm resistance. Determine the bandwidth of the filter.arrow_forwardH.W: A resistor of resistance R-1000 2 is maintained at 17 °C and it shunted by 100 uH inductor. Determine the rms noise voltage across the inductor over a frequency bandwidth of: i) 15.9 kHz Ans: 182 x109 volt ii) iii) Ans: 9.22 x10-8 volt Ans: 2.34 x10-6 volt 159 kHz 1590 kHzarrow_forward[Q5] Choose appropriate values for this Sallen-Key high-pass filter circuit to give it a cutoff frequency of 7 kHz with a “Butterworth" response Draw the complete circuit diagramarrow_forward
- Im + Re -100 -1 Figure 1: We want to sketch the bode plot for this filter! 1) Rewrite H(s) in the "standard form" for Bode plots 2) Using paper + pencil, sketch the Bode magnitude and phase shift plots. 3) What kind of filter is this: Low-pass Bandpass High-pass Notcharrow_forwardDesign a series RLC bandpass filter as shown in the figure with lower cut-off frequency f = 400 Hz and bandwidth B = 9600 Hz %3D a) Determine the higher cut-off frequency f# b) Determine the center or resonant frequency fo in Hz and wo in rad/s and calculate the quality factor Q c) Choose C = 2 nF and find the values of R and L to meet the design specifications C No V: Oarrow_forwardQuestion #9: Think about what would happen if you were to measure the voltage across the resistor instead (see figure to the right). What would the plot of resistor vs. log(frequency) V generator look like? This is called a RC High Pass filter. Come up with a good qualitative description and explanation. V gen 2. HH V resistorarrow_forward
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What is Filter & Classification of Filters | Four Types of Filters | Electronic Devices & Circuits; Author: SimplyInfo;https://www.youtube.com/watch?v=9x1Sjz-VPSg;License: Standard Youtube License