You are given a 40kΩ resistor in order to design a filter that only pass all...

You are given a 40kΩ resistor in order to design a filter that only pass all...

You are given a 40kΩ resistor in order to design a filter that only pass all frequencies which are lower than 188.5k rad/s and upper than 188.8k rad/s. By using your own value of resistance (in kiloOhms), based on your estimation, what are the suitable inductor and capacitor values that will you choose to support the filter operation. (Assume that : Q>10)

Design and draw a simple electrical circuit (a combination of a low-pass and a high-pass filter...

Design and draw a simple electrical circuit (a combination of a low-pass and a high-pass filter circuits) that will act as a bandpass filter for frequencies between 0.1 and 100 rad/s. Generate the magnitude Bode plot on matlab!!! Please do the matlab! thank you!

Design a second-order band-pass filter to select the frequency range of 36khz +/- 20kHz. With the...

Design a second-order band-pass filter to select the frequency range of 36khz +/- 20kHz. With the aid of a gain and phase plot, explain how an unwanted oscillation can be avoided to attain stability. Provide a statement on what condition an oscillation occurs. Provide values of all components to the nearest standard (E24) resistor values (+/-5% tolerance) and capacitor values (+/-10% tolerance).

Design an active-RC low pass second order Butterworth filter for a cutoff frequency of 1 kHz,...

Design an active-RC low pass second order Butterworth filter for a cutoff frequency of 1 kHz, and a pass band gain of 2 V/V. Use a 741 Op Amp. If using Table I, use a capacitor value of 0.1 μF for C and C1, otherwise you may use any capacitors available in the lab. If applicable, make an excel worksheet showing the calculations required for the above design.  Choose appropriate real resistor values for the designed circuit and simulate this circuit...

Design a passive RC high pass filter with a cutoff frequency of 470 Hz using a...

Design a passive RC high pass filter with a cutoff frequency of 470 Hz using a 270 pF capacitor. What is the value of the resistor? Express your answer with the appropriate units. What is the transfer function of the filter? Express your answer in terms of the variables R, C, and s. If the filter is loaded with a resistor whose value is the same as the resistor in part B, what is the transfer function of this loaded...

Design a second-order all pass filter with a phase shift of 180 degrees at 5.24 kHz...

Design a second-order all pass filter with a phase shift of 180 degrees at 5.24 kHz and a quality factor of 3. (include circuit design w/ component values)

To analyze and design a passive, second-order bandreject filter using a series RLC circuit. A bandreject...

To analyze and design a passive, second-order bandreject filter using a series RLC circuit. A bandreject filter is needed for an equalizer, a device that allows one to select the level of amplification of sounds within a specific frequency band while not affecting the sounds outside that band. The filter should pass frequencies lower than 1.4 kHz and have a resonant frequency of 3.8 kHz. A 5.0 μF capacitor and any needed resistors and inductors are available to be used...

A common use of capacitors as a reactive component is in a low-pass or high-pass filter,...

A common use of capacitors as a reactive component is in a low-pass or high-pass filter, both of which contain a resistor and a capacitor. A low-pass filter is one that passes through signals with frequencies lower than a particular cutoff frequency and causes attenuation in signals of higher frequency. A high-pass filter is one that passes through signals with frequencies higher than a certain cutoff and causes lower frequencies to attenuate, giving the two configurations their names. The cutoff...

Design a second order (two pole) low-pass filter for the following specifications Cut-off frequency, fo or...

Design a second order (two pole) low-pass filter for the following specifications Cut-off frequency, fo or fH = 8kHz   Maximally Flat, i.e. Q=1/√2 > Justify any assumption you make. > Draw circuit with all designed values. > Draw the frequency response (Gain magnitude only)

You have a resistor of resistance 210 ΩΩ , an inductor of inductance 0.370 HH ,...

You have a resistor of resistance 210 ΩΩ , an inductor of inductance 0.370 HH , a capacitor of capacitance 6.40 μFμF and a voltage source that has a voltage amplitude of 30.0 VV and an angular frequency of 230 rad/srad/s . The resistor, inductor, capacitor, and voltage source are connected to form an L-R-C series circuit. What is the impedance of the circuit? What is the current amplitude? What is the phase angle of the source voltage with respect...