Introductory Circuit Analysis (13th Edition)
13th Edition
ISBN: 9780133923605
Author: Robert L. Boylestad
Publisher: PEARSON
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Chapter 22, Problem 25P
Design a high-pass R-C filter to have a cutoff or comer frequency of
Choose the closest commercial value for R, and then recalculate the resulting corner frequency. Sketch the normalized gain
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Students have asked these similar questions
Design a series RLC bandpass filter as shown in the figure with
lower cut-off frequency f = 400 Hz and bandwidth B = 9600 Hz
a) Determine the higher cut-off frequency fH
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
R
No
I need some help. I am designing a bandpass filter with fl=3400 Hz and fh= 7500 Hz. Based on that I need the values for the RCL circuit, assuming that the capacitor is 1 microfarat. So, I need some help in calculate the center frequency, bandwith, Q, center frequency as well. I need clear steps and calculations. Any help will be appretiated.
1.
A)
B)
Write the transfer function for the RC high-pass filter of Figure 2. First write it in terms of jw
(or s) and then write it as its magnitude and phase angle. Determine and record below the
cutoff frequencies of the circuit.
Sketch the straight line approximations of the frequency responses for the RC high-pass filter
on Graph
Avla 0.1
0
-20
-10
90°
60°
30°
0'
-30°
-60*
-90*
e=2 sin (cot)
0
0.2
(a) Voltage gain response
0.5
0.1 0.2
b.²
(b) Phase shift response
1
1
R = 75 ohms
2
L=2.4 mH
5
Vout
10 20
10
20
50
50
100 f
(kHz)
100
(kHz)
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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- (c) Design a series RLC bandpass filter with cutoff frequencies fc₁ = 1 KHz, fcz = 20 KHz, using a 100 resistor. Draw the circuit and label all the components, including circuit values, including input and output. Also draw the magnitude and phase plots for the filter. Amplitude [dB] 50 40 30- Phase [°] 10 of- -10... -20... -30- -40- -50 0.1 180 135 90 C 45 of -45- -90 -135- -180 0.1 1 1 10 10 100 100 1000 1000 10,000 Freq. (Hz) 10,000 Freq. (Hz)arrow_forwardDesign a basic wide-band, RC band stop filter with a lower cut-off frequency of 200Hz and a higher cut-off frequency of 800HZ. Fa Pau tand Pan Bard Fregarey Lon Pan High Pam Raspon Raspone Figure 1: Band Stop Filter Characteristics Assuming a capacitor, C value for both filter sections (CLP, CHP) of 0.2ur, calculate the values of the two resistors, RuP and Rup using the formula: 1. From the Low pass filter formula, Find RLp: 1 fi = 2. From the High pass filter iormula, Find Rup: 1 fu = 2nRupCuP 3. Calculate the center frequency (fe) and Bandwidth (BW): a. fc = VfL x fu b. BW = fu - fLarrow_forward1. A) B) Write the transfer function for the RC high-pass filter of Figure 2. First write it in terms of jw (or s) and then write it as its magnitude and phase angle. Determine and record below the cutoff frequencies of the circuit. wwwwww Sketch the straight line approximations of the frequency responses for the RC high-pass filter on Graph Av0.1 0 -10 -20 90° 60* 30° 0⁰ -30° -60° -90° e-2 sin (et) 0.1 0.2 (a) Voltage gain response 0,5 0.2 (b) Phase shift response 0.5 1 C = 0.47 uF R-330 ohms 2 ww 5 10 10 Vout 20 20 50 50 100 f (kHz) 100 (kHz)arrow_forward
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