Lab Guide - inst.eecs.berkeley.edu - University of California, Berkeley
... Electronic Techniques for Engineering Diodes Lab Guide Half-Wave Rectifier 1. Build the half-wave rectifier circuit drawn in the figure below. Use a potentiometer (as a rheostat) for the load and set it to about 1K ohm. Use a light emitting diode (LED). NOTE: To avoid damage to the diode, set the cu ...
... Electronic Techniques for Engineering Diodes Lab Guide Half-Wave Rectifier 1. Build the half-wave rectifier circuit drawn in the figure below. Use a potentiometer (as a rheostat) for the load and set it to about 1K ohm. Use a light emitting diode (LED). NOTE: To avoid damage to the diode, set the cu ...
IOSR Journal of Electronics and Communication Engineering (IOSR-JECE)
... mode input range is also infinite, while the differential signal between these two inputs is used to control an ideal current source (i.e. the output current does not depend on the output voltage) that functions as an output. The proportionality factor between output current and input differential v ...
... mode input range is also infinite, while the differential signal between these two inputs is used to control an ideal current source (i.e. the output current does not depend on the output voltage) that functions as an output. The proportionality factor between output current and input differential v ...
Analog Communication
... • Clipper circuit uses a comparator or high gain operational amplifier such that any input voltages greater or less than zero cause the output voltage to reach either positive or negative power supply rails. • Clipper circuit employing back to back Zener diode with break down voltage at the output o ...
... • Clipper circuit uses a comparator or high gain operational amplifier such that any input voltages greater or less than zero cause the output voltage to reach either positive or negative power supply rails. • Clipper circuit employing back to back Zener diode with break down voltage at the output o ...
Low-voltage pipelined ADC using OPAMP
... of the key analog limitations of the state-of-the-art and future submicron CMOS technologies remains the restricted power-supply voltage, limited primarily by the thin gate oxide that is prone to voltage stress reliability and breakdown. One circuit type directly affected by this low-voltage problem ...
... of the key analog limitations of the state-of-the-art and future submicron CMOS technologies remains the restricted power-supply voltage, limited primarily by the thin gate oxide that is prone to voltage stress reliability and breakdown. One circuit type directly affected by this low-voltage problem ...
Diodes
... the power supply to “ripple.” Verify that the frequency of the ripple is 120 Hz. (d) Alter the resistive load by making the resistor 47k instead of 10k. Observe that the ripple decreases. Once again you may need to AC-couple and to increase the magnification of the DPO. (e) Explain the advantage o ...
... the power supply to “ripple.” Verify that the frequency of the ripple is 120 Hz. (d) Alter the resistive load by making the resistor 47k instead of 10k. Observe that the ripple decreases. Once again you may need to AC-couple and to increase the magnification of the DPO. (e) Explain the advantage o ...
Working Paper on Digitizing Audio for the Nation
... noise" as possible. To achieve this goal, it seems to be sufficient to use the 44,100 Hz sampling rate and a 16-bit resolution. The former ascertains that we capture the entire audible frequency range of the original (see Nyquist theorem below), while the latter, gives us a fairly good, 96 db SNR (s ...
... noise" as possible. To achieve this goal, it seems to be sufficient to use the 44,100 Hz sampling rate and a 16-bit resolution. The former ascertains that we capture the entire audible frequency range of the original (see Nyquist theorem below), while the latter, gives us a fairly good, 96 db SNR (s ...
EE 233 Circuit Theory Lab 3: Simple Filters
... 2. Apply a sine wave input signal with an amplitude of 300 mV and a frequency of 300 Hz. Display the input signal on Channel 1 of the oscilloscope and the output signal on Channel 2. Adjust the time base to display 2-3 complete cycles of the signals. Question-2: Get a hardcopy of output from the sc ...
... 2. Apply a sine wave input signal with an amplitude of 300 mV and a frequency of 300 Hz. Display the input signal on Channel 1 of the oscilloscope and the output signal on Channel 2. Adjust the time base to display 2-3 complete cycles of the signals. Question-2: Get a hardcopy of output from the sc ...
97mc
... (1) capacitance times resistance (2) inductance divided by resistance (3) capacitance times inductance A. B. C. D. E. ...
... (1) capacitance times resistance (2) inductance divided by resistance (3) capacitance times inductance A. B. C. D. E. ...
EE101L Laboratory 4
... a) Modify your design such that you will be able to obtain an output signal with 1V amplitude for all frequencies between 1 KHz and 10 KHz. You will need to use a variable circuit element (potentiometer) in order to do this. Pick your capacitor such that the required resistor values at the lowest an ...
... a) Modify your design such that you will be able to obtain an output signal with 1V amplitude for all frequencies between 1 KHz and 10 KHz. You will need to use a variable circuit element (potentiometer) in order to do this. Pick your capacitor such that the required resistor values at the lowest an ...
Operational Amplifiers in Chemical Instrumentation
... class of integrated circuits known as operational amplifiers, which can be referred to as op amps. Operational amplifiers are everywhere. If you open any instrument or piece of electronic equipment, it would be likely to find one or more op amps. This fact, along with the ease of complex functions t ...
... class of integrated circuits known as operational amplifiers, which can be referred to as op amps. Operational amplifiers are everywhere. If you open any instrument or piece of electronic equipment, it would be likely to find one or more op amps. This fact, along with the ease of complex functions t ...
Electronic and Real Time Embedded System Lab
... “Diploma of Electrical Engineering (DEE) Level-7” for both domestic and international students. The available modern electrical and electronic equipment and components facilitate “hands on experience” to students. The aim of this lab is to enhance the knowledge and skills of the students and prepare ...
... “Diploma of Electrical Engineering (DEE) Level-7” for both domestic and international students. The available modern electrical and electronic equipment and components facilitate “hands on experience” to students. The aim of this lab is to enhance the knowledge and skills of the students and prepare ...
ppt - K.f.u.p.m. OCW
... Summing Amplifier Digital-to-Analog (D/A) Converter Difference Amplifier Instrumentation Amplifiers Audio Amplifier ...
... Summing Amplifier Digital-to-Analog (D/A) Converter Difference Amplifier Instrumentation Amplifiers Audio Amplifier ...
PHYS 2426 – Engineering Physics II
... 3. Use the spring clips to connect the components in the order shown in the circuit schematic. (The instructions in this lab will be written assuming you connected the components in the order shown.) 4. Place the BNC/T on the output of the function generator. 5. Use the BNC/Alligator cable to connec ...
... 3. Use the spring clips to connect the components in the order shown in the circuit schematic. (The instructions in this lab will be written assuming you connected the components in the order shown.) 4. Place the BNC/T on the output of the function generator. 5. Use the BNC/Alligator cable to connec ...
BDS-MF Generator
... BDS-MF 5/10kW @ 40kHz, High|Low Voltage AC plasma generator The BDS-MF is a 40 kHz plasma generator with max power delivery of 5kW or10 kW is specifically designed for plasma excitation on PECVD or plasma cleaning applications. The unit is capable of delivery up to 10kW at 7000V RMS output. The outp ...
... BDS-MF 5/10kW @ 40kHz, High|Low Voltage AC plasma generator The BDS-MF is a 40 kHz plasma generator with max power delivery of 5kW or10 kW is specifically designed for plasma excitation on PECVD or plasma cleaning applications. The unit is capable of delivery up to 10kW at 7000V RMS output. The outp ...
Homework #15 - cloudfront.net
... potential difference of 200.0 V is applied across the plates, and the electrons are deflected toward the top of the screen. Assume the electrons enter the plates with a speed of 6.0 x 107 m/s and the fringing at the edges of the plates and gravity are negligible. (b) Which plate in the pair must be ...
... potential difference of 200.0 V is applied across the plates, and the electrons are deflected toward the top of the screen. Assume the electrons enter the plates with a speed of 6.0 x 107 m/s and the fringing at the edges of the plates and gravity are negligible. (b) Which plate in the pair must be ...
Chip Detects Shorts and Overloads, Measures Current
... the motor-side and microcontroller/DSP side so you don't have to include an isolation amplifier or opto-isolator or any sensor signal-conditioning components. The 16-pin IC (SO-16 package) costs about $9.50 for a single device. Find more information at www.avagotech.com (search for "HCPL-788J"). The ...
... the motor-side and microcontroller/DSP side so you don't have to include an isolation amplifier or opto-isolator or any sensor signal-conditioning components. The 16-pin IC (SO-16 package) costs about $9.50 for a single device. Find more information at www.avagotech.com (search for "HCPL-788J"). The ...
1. The following questions refer to the waveform shown below. a
... 4. The following questions refer to the following two sinusoids: v1(t) = 50 cos(200t + 12°) V, v2(t) = 8 cos(200t + 30°) V. a. What is v1’s phase angle (in degrees)? b. What is v2’s phase angle (in degrees)? c. Which voltage leads the other one, and by how many degrees? d. Which voltage lags the oth ...
... 4. The following questions refer to the following two sinusoids: v1(t) = 50 cos(200t + 12°) V, v2(t) = 8 cos(200t + 30°) V. a. What is v1’s phase angle (in degrees)? b. What is v2’s phase angle (in degrees)? c. Which voltage leads the other one, and by how many degrees? d. Which voltage lags the oth ...
Data Encoding
... would appear as constant voltage pulses Timing is critical, because any drift results in lack of synchronization and incorrect bit values being transmitted ...
... would appear as constant voltage pulses Timing is critical, because any drift results in lack of synchronization and incorrect bit values being transmitted ...
Oscilloscope history
This article discusses the history and development of oscilloscope technology.