The first step in the design phase for this lab is to decide on appropriate pass and stop frequencies for each filter. The tweeter speaker can reproduce frequencies greater than 6kHz, and the woofer can reproduce frequencies less than 200Hz. For proper sound, the midrange should reproduce all frequencies not produced by the subwoofer or tweeter.
Design a low pass, band pass, and high pass filters with appropriate pass frequencies. The design will be simulated in Multisim using an AC analysis to ensure expected behavior.
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The first step in the design phase for this lab is to decide on appropriate pass...
Find The values, C1, C2, L1, L2, R1, R2, R3. The tweeter speaker can reproduce frequencies greater than 6kHz, and the woofer can reproduce frequencies less than 200Hz. For proper sound, the midrange should reproduce all frequencies not produced by the subwoofer or tweeter. C2 C1 L2 V1 L1 R1 R3 R2 Midrange Tweeter Woofer Fig. 2. Equivalent model. The values of Ri, R2, R3, L1, L2, G. and C, are selected so that the filters have the same cutoff...
Active Low-pass and High-pass Filters for Crossover Circuitry (PSPICE) Design a first order active high-pass filter with cut-off frequency of 1 kHz & gain 20dB. Design a first order active low-pass filter with cut-off frequency of 1 kHz & gain 20dB. Plot the magnitude and phase responses of the active high-pass and low-pass filters you have designed using PSpice (Use UA741 Op amp and ±12V dual supply). Connect your active low-pass and high-pass filters as shown in Fig. 1-b. Assume...
QUESTION 1 Design a second order passive low-pass filter that has a cutoff frequency of 6 KHz by: a. Choosing an appropriate R and C value. (HINT: R1=R2=10K and C1=C2=C) A= C/S V=J/C V=AN 1 H2 = 1/5 F = CN Final Solution: C1=
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
For the following design L1-2H C1-0.05F R1.4Ω R2-4Ω C2-0.05P L2-2H Va 4cos(10t+90°)V vb-4cos( 10t+90"N R4-4Ω R6:2Ω RS-4Ω Vc-4cos(20t+90jv vds4cos( 10t+60ον (Remember that i) w is given in rad/sec, ii) the above circuits have different Impedances for different frequencies, ii) we replace the shorted voltage power supplies with a short circuit, iV) with atjb the rectangular form and Ad the polar form we have a-Acos(8), b-Asin(θ), A-: va2+1,7 , θ= tan-l (4)if a > 0, θ= 180-tan-IL) if a <0) a)...
For each filter mentioned in the following cases, first simulate the circuit using Multisim. You can get a plot of the transfer function that is called the Bode plot. From the right toolbar, select "Bode Plotter". Change initial (I) and final (F frequencies to 1Hz and 200 KHz, respectively. Use a Voltage AC source as the input signal. You do not need to change any parameter from voltage AC source Connect "Bode Plotter" to input and output of your circuit...
Using the windowing functions discussed in class, design a low-pass FIR filter with a cutoff frequency of 2 kHz, a minimum stop band attenuation of 40 dB, and a transition width of 200Hz. The sampling frequency is 10kHz. 1. Using the windowing functions discussed in class, design a low-pass FIR filter with a cutoff frequency of 2 kHz, a minimum stop band attenuation of 40 dB, and a transition width of 200 Hz. The sampling frequency is 10 kHz 2....
I'm unsure how to work this problem. Please include all drawings where necessary. For the following design C1-0.05F L1-2H R2-40 R1 40 C2-0.05F L2-2H Va-4cos(10t+900)V Vb-4cos(10t+90°] R4-40 L3 0.1H C3-0.1F R3-40Q 1R6-20 vc=4cos( 20t+900)V vd:4cos( 10t+600)V (Remember that i) ω is given in rad/sec, i) the above circuits have different Impedances for different frequencies, ii) we replace the shorted voltage power supplies with a short circuit, İV) with a+jb the rectangular form and NO the polar form we have a-Acos(9),...
Learning Goal: To analyze and design a passive, first-order low- pass filter using a series RL circuit. The analysis and design will be repeated for a series RC circuit. An electrocardiogram needs to detect periodic signals of approximately 1 Hz (since the resting heart rate of a healthy adult is between 55 and 70 beats per minute). The instrument operates in an electrical environment that is very noisy with a frequency of 60 Hz. It is desirable to have a...
Learning Goal: To analyze and design a passive, first-order low-pass filter using a series RL circuit. The analysis and design will be repeated for a series RC circuit. An electrocardiogram needs to detect periodic signals of approximately 1 Hz (since the resting heart rate of a healthy adult is between 55 and 70 beats per minute). The instrument operates in an electrical environment that is very noisy with a frequency of 60 Hz. It is desirable to have a low-pass...