Design a parallel RLC band-pass filter to have the nominal center frequency f0 = 280 kHz and the 3dB bandwidth B = 7.9 kHz. Use only single, standard-valued components: 5% resistors, 10% capacitors and 10% IMS-5WD-40 inductors. Assume that inductor's Q is constant in the frequency range [0.1 - 1.0]ft, where ft is the 'TEST FREQUENCY Q' given in the IMS-5WD-40 data sheet.
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Design a parallel RLC band-pass filter to have the nominal center frequency f0 = 280 kHz and the 3dB bandwidth B = 7.9 k...
Design an active band-pass filter such that the center frequency is Fo-2.5 kHz, bandwidth is BW 400 Hz and gain is K-3 for Figure 10.5. Find the values for the capacitors, and resistors. Compute the theoretical values of Vout and |Av Vout / V l and record the results in Table 10.5-A. VEE -15V C1 R3 C2 R1 R2 Vout +VCC +15V Figure 10.5
answer fast 2- Design an RLC Band Reject filter with a lower cutoff frequency of 2 kHz and an upper cutoff frequency of 2.1 kHz. Consider a capacitor C = 3.7nF and calculate L, C, and Q. a) Give the Transfer function of this filter. b) Find the central frequency f., the bandwidth (BW) in Hz, and the quality factor (Q). c) Sketch the frequency response of this filter only magnitude.
13.60 A second-order band-pass filter is required with a center frequency of fo 54 kHz and a passband gain of +50 dB. If the filter is implemented using the circuit of Fig. 13.15 with C1-C2, choose appropriate values for Ri and R2. What is the resulting value of for the filter? What is its bandwidth? Ci Figure 13.15 Second-order active bandpass filter of the Sallen-Key type. R2 C2 Ri UIN OUT 13.60 A second-order band-pass filter is required with a...
a) Design a low-pass filter using the given circuitry with a cut-off value of 1 kHz and plot the frequency response curve on the given axes 1.0 0.7 0.5 in out 0.0 101 102 103 104 10s Hz b) Design a band-pass filter using the given circuitry with a bandwidth of 500 Hz and a lower cut-off value of 100 Hz, and draw the frequency response curve. Keep all resistors at the same value (i.e. Ri-R-R3-R4). 1.0 0.7 0.5 0.0...
1. Design a parallel RLC bandpass filter, derive the transfer function H(s). Compute the center frequency, Wo. Calculate the cutoff frequencies Wej and Wc2, the bandwidth ß, and quality factor, Q. Compute values for R and L to yield a bandpass filter with a center frequency of 5kHz and a bandwidth of 200Hz, using a 10nF capacitor. (25 points) 1. Design a parallel RLC bandpass filter, derive the transfer function H(s). Compute the center frequency, Wo. Calculate the cutoff frequencies...
A. Design a low-pass filter (op-amp based cascade design) that meets the following (30) requirements: 1. Cutoff frequency: 3.4 KHz Passband gain: 20 dB 2. 3. Stopband gain: -40 dB/decade 4. All resistors must be 1.0 kS2 or higher. You have completed the design and implementation of the LP filter and are ready to deliver the filter for production. However, you are informed that the customer made a mistake and actually needed a stopband gain of -60 dB/decade (not-40 dB/decade...
A. Design a low-pass filter (op-amp based cascade design) that meets the following (30) requirements 1. Cutoff frequency: 3.4 KHz 2. Passband gain: 20 dB 3. Stopband gain: -40 dB/decade 4. All resistors must be 1.0 k2 or higher. You have completed the design and implementation of the LP filter and are ready to deliver the filter for production. However, you are informed that the customer made a mistake and actually needed a stopb you have used in your design)....