Using only LF411 op amps, design a circuit with an upper break frequency of 500 kHz...

Using 5 nF capacitors and ideal op amps, design a high-pass unitygain Butterworth filter with a...

Using 5 nF capacitors and ideal op amps, design a high-pass unitygain Butterworth filter with a cutoff frequency of 4 kHz and a gain of at least -32 dB at 800 Hz. 30 points a) Draw a circuit diagram of the filter and label all the component values.

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...

Use an ideal op amp to design a differentiator circuit having a time constant of 10-5s...

Use an ideal op amp to design a differentiator circuit having a time constant of 10-5s using a 1-nF capacitor. Sketch the magnitude and phase response of the circuit, indicating the frequency at which the magnitude response equals 0 dB. A series input resistor is added to limit the gain magnitude at high frequencies to 100 V/V. Sketch the magnitude and phase responses of this modified circuit on the same axes as the ideal differentiator. How does the phase response...

Using a 741 op-amp for every stage, design this circuit: The input stage has a voltage...

Using a 741 op-amp for every stage, design this circuit: The input stage has a voltage gain of 10 and input impedance of 50 K?. The low pass filter stage has a Sallen-Key (VCVS) third order butterworth response and a cutoff frequency of 5KHz. The output buffer stage has a voltage gain of 10.

Design an RLC series circuit with the following data: Z0 = 100 Ω (Characteristic impedance) Frequency...

Design an RLC series circuit with the following data: Z0 = 100 Ω (Characteristic impedance) Frequency = 1 kHz (Frequency where reactance is zero) R = Z0. a. Sketch the impedance on a log-log scale. What do you expect the phase to do? b. Simulate the circuit in QUCS and compare the result with your prediction/expectation. Also elaborate on your interpretation of the response. c. Can you identify Zo and Frequency features? How well does your design meet the requirements?...

I need to design a circuit using only resistors and capacitors that will filter out a...

I need to design a circuit using only resistors and capacitors that will filter out a signal above a specific frequency. In order to deemed a success, the peak voltage across your capacitor must be equal to 20% of the peak voltage provided by the function generator at the frequency ftheory. Available values of resistance are 5, 10, 30, and 39 Available values of capacitance are 100, 150, 220 and 470 uF ftheory=1699Hz I need to draw the circuit and...

Part 1: I need to design a circuit using only resistors and capacitors that will filter...

Part 1: I need to design a circuit using only resistors and capacitors that will filter out a signal above a specific frequency. In order to be deemed a success, the peak voltage across your capacitor must be equal to 20% of the peak voltage provided by the function generator at the frequency f_theory. Full credit on this lab requires that your percent error in Part 2 is less than 5%. f theory = 1699Hz Available values of resistance are...

In your design, please explicitly describe the transfer function, the bode plot, and the value of...

In your design, please explicitly describe the transfer function, the bode plot, and the value of passive components obtained while designing the filter according to the given specification. Use Multisim for the circuit design as well as frequency response analysis, and compare the output (Bode plots) with the simulation that can be obtained from MATLAB. Validate your answer using MATLAB. Design a highpass active filter with a high-frequency gain of 20 and a corner frequency of 500 Hz.

Design, simulate, and implement a multistage discrete amplifier using small-signal BJT transistors. Amplifier Specifications: – Midband...

Design, simulate, and implement a multistage discrete amplifier using small-signal BJT transistors. Amplifier Specifications: – Midband voltage gain: Av = 100. – Lower 3-dB frequency: fc = 100 Hz. – Input Impedance: Zin ≥ 250 kΩ. – Output Impedance: Zo ≤ 100 Ω. – Power Supply: Vcc = 15 V. – The load resistance is 1 kΩ – Output capability with a 1–kHz sinusoidal test signal must be at least 2 V peak without severe distortion (i.e. clipping). – Transistor...

In the final project, students will design a motor controller based on the light level on...

In the final project, students will design a motor controller based on the light level on a phototransistor. When illumination is very high, the motor will be stopped while 6 volts will be applied to the motor under low light conditions. You will need to measure (characterize) the properties of a phototransistor under both light and dark conditions in order to design the circuit and calculate component values. An op amp is be used in the project along with a...