Question

100 pF 300 kn 220 pF 100 kn W in SR 100 kn IGURE 17.53

17. Calculate the values of foc, bandwidth, geometric center frequency, and Q for the band-pass filter in Figure 17.53.

0 0
Add a comment Improve this question Transcribed image text
Answer #1

given circuit is 2 = 100 pF 8 -20oto R2=1000r/ 0,=22085 voul Vin &R,= 1000 here to 21 C, Rf 21 (220x10^12) (800x103) = 4.1468fcg = 2T R₂C2 - 21 (100x103) (100x10-12) = 6.283x10-5 0.0628m H₂ fer = fH = o.u166 m₂ , fcz = fx = 0.0628mH Bandwidth a th -fr = 0. 1613 m Hz Q- factor for Band paus filler Qop = fr BIJ = 0.1613x10-3 0.3618x10-3 0. 507 GBP = 0.507

Add a comment
Know the answer?
Add Answer to:
100 pF 300 kn 220 pF 100 kn W in SR 100 kn IGURE 17.53 17....
Your Answer:

Post as a guest

Your Name:

What's your source?

Earn Coins

Coins can be redeemed for fabulous gifts.

Not the answer you're looking for? Ask your own homework help question. Our experts will answer your question WITHIN MINUTES for Free.
Similar Homework Help Questions
  • R 1800 с 220 pF 220 pF VIN VOUT R 1800 kn R1 12 ko R2...

    R 1800 с 220 pF 220 pF VIN VOUT R 1800 kn R1 12 ko R2 10 k Figure A-6. 14. Look at the circuit that's shown in Figure A-6. This circuit is a A. two-pole high-pass filter. B. two pole low-pass filter. C. two-pole passive filter. D. three-pole active filter.

  • For the Multi Feedback Topology Band-pass Filter circuit shown in Figure 1 below, confirm the transfer...

    For the Multi Feedback Topology Band-pass Filter circuit shown in Figure 1 below, confirm the transfer function H(s) given below 0 Figure 1: Multiple Feedback Topology Band-pass Filter (MFT BPF) Vo SR で 1 Ri R3 2R TR2C where the filter's parameters are o f: middle (center) frequency in Hz o Am: gain at middle frequency, fm, in V/V o B: bandwidth between half power frequencies in Hz o Q: quality factor. One of the nice features of this circuit...

  • pls i want as fast as possible Q4 (20 pts) Design a series RLC band pass...

    pls i want as fast as possible Q4 (20 pts) Design a series RLC band pass filter as shown below, with low frequency cut-off at W = 100 rad/sec and high frequency cut-off at WH=10 krad /sec. (4 pts) a) Determine the center frequency wo and the bandwidth B (10 pts) b) Choose L-100 mH and calculate the values of R and C (6 pts) c) Find the magnitude of H(jw)= Vo / V, and evaluate it at www с...

  • Consider additive white Gaussian noise with a double-sided noise power spectral density (PSD) 12-90 dBm/Hz 1E-12 W/Hz....

    Consider additive white Gaussian noise with a double-sided noise power spectral density (PSD) 12-90 dBm/Hz 1E-12 W/Hz. This noise corrupts a baseband polar NRZ signal with rectangular pulses, like that 1 mV and the pulse duration is Tb such that the symbol rate is Rb 1/Tb. Since this is binary signaling, the symbol rate equals the bit rate of the incoming baseband pulse train: B Rt. The signal is then sampled at the center of the noisy shown in the...

  • Find the answers under criteria (oae 20 log10( )D Problem 1: R Low Pass and High...

    Find the answers under criteria (oae 20 log10( )D Problem 1: R Low Pass and High Pass filters. Consider the RC series circuit in Figure 1 Refer to your clas:s activities for help with this exercise. 6. Calculate the reference magnitude f the trunsfer functionsDetemine t frequency ak where the magnitude is 0.707Mo (lll (%)-0707Mo). e expression for culolf Part 1,2,7Corect filter characterization Criteria Full Marks Figure 1. Serles R fier 1. By inspection, determine if the transter fuction ow...

  • 21 Vi Z2 Vo Figure 1 1. Ref: Figure 1. Let Z1 L (an inductor), Z2 - R (a resistor). Vi Calculate the magnitude and phase of the transfer function H(w) Figure 1 T 2. Repeat #1 with L = 100 mH, R 1kΩ....

    21 Vi Z2 Vo Figure 1 1. Ref: Figure 1. Let Z1 L (an inductor), Z2 - R (a resistor). Vi Calculate the magnitude and phase of the transfer function H(w) Figure 1 T 2. Repeat #1 with L = 100 mH, R 1kΩ. a) Plot the frequency response in dB* on a both on a linear scale and then a log scale from ω-1 to 100,000,000 rad/sec with points every decade (1 b) 1,000 etc). 10 100 Plot the...

  • Resistors 2700 3300 3900 4700 56002 Capacitors 1.OnF 1.5nF 2.2nF Inductors 2.7mH 1500 1800 2200 6800...

    Resistors 2700 3300 3900 4700 56002 Capacitors 1.OnF 1.5nF 2.2nF Inductors 2.7mH 1500 1800 2200 6800 8200 1.0kn 1.2k2 1.5k 1.8k 22.2k02 2.7k 2 3.3nF 4.7nF 6.8nF 3.3k 3.9k 4.7kn 5.6k 26.8k0 8.2k210k 2 12kΩ 10nF 15F 22nF 15kΩ 18kQ2 22kΩ 27kg 33kg 39k 47kg 56kΩ 33nF 47nF 68nF 68k 82kg 100k 120ko 150k 150k 180k 220ko 100nF 150nF 270kn 330kn 390kW 470kn 560kn 680k0 820ko 1.0M Table 1 In this lab, you will design and build Passive & Active...

  • Solve each practice problem. TYPE solutions in engineering notation TYPE solutions in engineering notation. Calcula...

    Solve each practice problem. TYPE solutions in engineering notation TYPE solutions in engineering notation. Calculate the component voltages and branch currents for the circuit shown in Figure 6.40, along with the values of I, and Rr. 3. R3 2 kn R4 4.7 k R1 10 k Vs 26 V R5 3.3 k R2 3 kn FIGURE 6.40 Calculate the component currents and loop voltages for the circuit shown in Figure 6.42, along with the values of I and Rr 5....

  • 3.2 Simple Bandpass Filter Design The L-point averaging filter is a lowpass filter. Its passband width...

    3.2 Simple Bandpass Filter Design The L-point averaging filter is a lowpass filter. Its passband width is controlled by L, being inversely proportional to L. In fact, you can use the GUI altidemo to view the frequency response for different averagers and measure the passband widths. It is also possible to create a filter whose passband is centered around some frequency other than zero. One simple way to do this is to define the impulse response of an L-point FIR...

  • The circuit shown in Figure Q4-1 includes an audio source and the equivalent circuit of a...

    The circuit shown in Figure Q4-1 includes an audio source and the equivalent circuit of a loudspeaker that you have been asked to analyse. 4. a) Assuming the speaker is to operate at a single frequency of 200 Hz and is5 driven by a cosinusoidal signal with peak amplitude of 20 V; determine the equivalent impedance of the speaker When connected to the audio source, calculate the current flow i() When testing the loudspeaker detailed in Q4a) i), you can...

ADVERTISEMENT
Free Homework Help App
Download From Google Play
Scan Your Homework
to Get Instant Free Answers
Need Online Homework Help?
Ask a Question
Get Answers For Free
Most questions answered within 3 hours.
ADVERTISEMENT
ADVERTISEMENT