This equation is true for all waveforms. Exercise: For each of the following voltage waveforms, calculate...
Problems 1 through 8 refer to the sinusoidal waveforms on the right, which are displayed on an oscilloscope having the following settings: Channel 1 Vertical Axis: 1 V/Division Channel 2 Vertical Axis: 50 mV/Division Horizontal Axis: 1 ms/Division The zero-volt level is at the center of the screen for both channels. Consider the left edge of the screen to be the t=0 axis. Consider the waveform displayed on Channel 1 as the output voltage of a function generator. In ze...
2. Diode circuits and output waveforms. (a) Sketch the output waveforms expected when a 100Hz, 6Vp sine wave is applied to each of the circuits shown. Label important voltage levels and time values. Your plots should be large enough, at least 4 to 6 inches on a side, and semi-quantitative to represent accurately the output waveform. Note: the input signal is ap- plied to the left side of the circuit and the output taken from the two terminals on the...
1. Write an equation that describes voltage supplied by
a wall outlet.
(f = 60 Hz, Vrms = 120 V)
2. What is the instantaneous voltage of a sine wave at
half of a period?
Describe Alternating Current (AC). Explain how resistors, capacitors, and inductors behave in an AC circuit. WRITEUP REQUIREMENTS Informal: Questions - 6 pts, Data Tables - 3 pts, Survey Questions from Syllabus - 1 pt INTRODUCTION V Up to this point, we have been using supply...
1. Consider the single-phase VSI inverter shown below dc VR(t) iz(t) a) If your input voltage Vdc - 100V2 V and switching frequency is 60 Hz with zero delay angle. Then, sketch the square wave output. Mark the peak values [10 marks] b) Sketch the fundamental output on the top of the above waveform. Mark the peak value По marksl c) The above A VSI is used to create a square wave output with 100v2 V at 60 Hz. This...
Use NI Multisim
3) (+3) Do the following in Multisim and verify the results with calculations (see equations 1.7-1.9). Use the function generator to create the 120 Vrms signal as you would see in the classroom wall outlet. Connect it to a resistor (the value of the resistor is your choice, but must have two decimal places) and measure the RMS voltage across the resistor and current through the resistor with separate Multimeters. Calculate the RMS voltage and current and...
. Convert the following pairs of voltage and current waveforms to phasor form. Each pair of waveforms corresponds to an unknown element. Determine whether the element is a resistor, a capacitor, or an inductor, when v(t) = 2 sin (150t - 42o) and i(t) = 13 cos (150t - 42o). The element is a(n) _____. Note: Write the component name in all lower case letters.
Please help me all steps.
1- Set up the circuit as shown in figure (7). Then 330 resistor is to limit the maximum current reached. Then 100 resistor is to display the current waveform on the oscilloscope. 0.033k Chi (Voltage) 10mH Ch2 (Current) 0.01K common Figure (7) 2- Adjust the wave generator to give a peak voltage of 10 V square wave at 250Hz (Period is 4msec and Pulse Width is 2msec). Set the OSC as follows: Time base: 1...
URGENT!! PLEASE HELP! be clear and answer all questions
clearly!!
Lab ll: Voltage Follower ECE 210: 1. For the following circuit, Theoretically calculate the peak voltage across R3 (Vo) an ved R1-2.2k0 2.17362(Actual) R2 = 3.3kN-3.Z44KAL (Actual) R3-10kΩ 9.873M. (Actual) Vin- 1kHz Triangle wave, 2V peak, NO DC offset e) R Draw the output waveform Vo: UI R1 R2 X-Axis 0.1 msec/div 2. Remove the resistor R2 to create the following circuit Draw the output waveform Vo: U1 R1 R3...
For each graph below, you are instructed to find the RMS.
However, do NOT find it. Instead, find the equation for
each "segment" of the graph.
For example:
Do only the green part.
Remember to not skip any steps and explain/show HOW you
got the equations.
Period (T= 6 ms) Vminimum = 0V,Vpeak = 6V тії Voltage waveform falls across R2=102. Vrms=?, Power dissipation in R2? Write equations for each segment V1 R2 {R2} v7(t) = 2t v2(t) = -2t...
1000 Hz Fig. 3 10. Using the measured values of R and V calculate the voltage Vo when the applied square wave is +2.5 V and -2.5 V. Show all the steps of your calculation. 11. Using the results of part 10 to sketch the expected waveform for Vo 12. Using the oscilloscope to measure the output voltage Vo of the Fig. 3 and compare with result of part 10. 13. Repeat steps 9 and 12 Using MULTISIM and compare...