250 mH Vi Given: The circuit shown above operates in steady state over a range of...
FrqRsp07 80 pF + Given: A series-resonant filter with a resonant frequency of 200 kHz has a quality factor of 15. Vi is the input voltage and V is the output voltage. Required: a. Determine the inductance value, L, in mH for the filter. b. Determine the resistance value, R, in k for the filter c. Determine the filter's gain in decibels, Gdb, at a frequency of 120 kiIz. d. Determine what type of filter this is. Solution: L= C...
FrqRsp11 30.3k2 150 pF 12.1k2 Ideal Vg V. Vo Given: The circuit shown above opcrates in stcady state over a rangc of frequencics. Vg is the input voltage and vo is the output voltage. The OpAmp may be assumed as idcal and docs not saturatc. Required a. Determine the gain in decibels at a frequency of 70 kHz h. Is this a High-pass or a Low-pass filter? Solution: db, and the filer is High-pass, Low-pass or Neither. ib
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...
x=1435 1) In the circuit you have a 250 mH inductor, a X 2 resistor and a 10 nF capacitor. Please find: a. Calculate roots of characteristic equation of the voltage response b. Is it over, under, or critically damped? c. What value of R would you add in series with X to yield a damped frequency of 12 krad/sec? d. What value of R would you add in series with X to yield a critically damped response? 1) In...
For the circuit shown in the figure above: Obtain an expression for H() Vo/Vi in standard form Generate spectral plots for the magnitude and phase of H (w), given that R-100Ω, L-0.1 mH, and C-1 μF Determine the cutoff frequency we and the slope of the magnitude (in dB) when wwc >1 For the circuit shown in the figure above: Obtain an expression for H() Vo/Vi in standard form Generate spectral plots for the magnitude and phase of H (w),...
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...
Simulation 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...
VO D IO 2. In the above circuit, the initial conditions are A. Determine the transfer function, H(s) VI(S) k, b and c are constants. B. Determine the type of filter impleme C. Determine the values for R.C, R, and R. that Cons are all zero and the op-amp is ideal. (1.6 pts) in the form of H(s) = k zubte, where W, = 25000 rad/s, a bandwidth of R - 50000 requirement that ALL resistors must have a res...
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...
Electronic Devices and Circuits ENGI27907 01 Q2. For the circuit shown in Figure 2, Vi=15V, R-2000, the zener diode is 1N4741A with the characteristics obtained from data sheets given below: a Find the minimum value for the rheostat resistance R., for which the zener diode will still maintain regulated voltage Vin across the load R. b. Discuss the current pass through the zener diode and the voltage across it, if the rheostat is turned to 1200 c. If the no-load...