# O 12.75 Amps Q18-A PV Module Has A Surface Area Of 1.5 M, And

O 12.75 Amps Q18-A PV Module Has A Surface Area Of 1.5 M, And. Get college assignment help at Smashing Essays o 12.75 Amps Q18-A PV module has a surface area of 1.5 m, and the radiation striking the module is 900 W/m What is the short circuit current (Isc) of the module if at 1 m2 Isc is 8.5 amps? o 5.67 Amps o 8.5 Amps o 11.3 Amps o 12.75 Amps keta de ane al

## Scho ポスメ Electrical Circ Ty Of Ta Quiz 1 Given That V,= 4V, I

Scho ポスメ Electrical Circ ty of Ta Quiz 1 Given that v,= 4V, i 4A, i2 2A, R R2-42 , R R 20, solve for currents i4, i Ry R. R2 R. L06 Capacitance Circuit ircuit Analys w

## 7.29 Noise N () Has The Power Spectral Density Shown In Figure 7.16. We

7.29 Noise n () has the power spectral density shown in Figure 7.16. We write () cos(2 foi 0)-n, (t) sin(2x fot 0) n t)n Make plots of the power spectral densities of n, () and n, (t) for the following cases: (a) fo f (b) fo f (c) fo2 i) (d) For which of these cases are n, (t) and n, (t) uncorrelated? Figure 7.16 -f2

## 6.1 Determine The Noise-equivalent Bandwidth For A Filter That Have A Transfer Function Given

6.1 Determine the noise-equivalent bandwidth for a filter that have a transfer function given by: Hf) Sketch Hof b. Sketch HO c. Determine the noise equivalent bandwidth Ho(f 65)Ho(f 65) where H) = 2A(f/10)    a.

## 5 EE207- ELECTRONIC MEASUREMENT TECHNIOUES LABORATORY No.5: OSCILLOSCOPE USING ОBJЕСТIVES In This Experiment, Student

Could you please solve only the 2 questions below 1 and 2. Thank you

## I Have A JBS 15 Amp Air Compressor And The Engineering Department Requires A

I have a JBS 15 amp air compressor and the engineering department requires a P

## NODE 1 NODE 2 NODE 3 R3 NOCE O NODE 4 Fig. 1. Resistor

NODE 1 NODE 2 NODE 3 R3 NOCE O NODE 4 Fig. 1. Resistor ciraut Measure with the multimeter and recod the power supply voltages. Measure and record the voltages at nodes 1, 2, 3, and 4 with respect to node 0 with R set to zero ohms. Repeat the node measurements for P 4. n 4 k2. 10 QUESTIONS: Derive the node equations to solve for node valtages 1 and 3. Solve for V, and V 1. leaving Rs as a variable. Calculate from the equations V, Vs and I for two Ra values other than zero or infinity. 2. Write a PSPICE computer program and run it to find the node voltages and the current I for all values of Ra used in Step 4 above. This program and the results are to be tumed in with the lab write-up. (Note: PSPICE will be graded separately.) 3. Compare the measured node voltages and cumrent I (from VyR with the calcudated values from Question 2 and the calculated values from PSPICE for the two Rs values chosen In Question 2. Which is most accurate? Why? 4 Note that for the special R values of zero and infinity it is particularty simple to solve for the node voltages. Redraw the network for Ra 0 and for Rs do eliminating all superfluous elements. For both cases calculate V, and Va For both cases check your results against the experimental results and the SPICE results. This type of check when practical, is always a good idea. It can help to detect errors in the solution for the more general cases 5 ww ww wwM Measured Resistance Va lues: R12-2kR4- 2.3kRe-6.8k0 R5 R2 Measured Power Supply Voltages: 18-050 V E1 E2 -085IV VOLTAGES NODE 4 (V) NODE 2 (V) NODE 3 R3 () NODE 1 (V) (V) 8-7582 V.6.688 V8-7581 V 18-05 V 8.9116 6.o884 V8-1998V18.053 V 500 9-1995V 6-0582V7-1568 V18-051 V 9.392 V 9.0845 V6-4588V 18-052V 9-6232V6.0851 V5.6223V 18.05 V 9-8973 V6-085Y V 4.63 V 2000 4000 10000 18-05 PURPOSE: The objectives of this experiment are to become familiar with node voltage measurements, and to leam to use PSPICE DISCUSSION: Circuit analysis is used to predict voltages and currents in any complicated resistor circuit by means of nodal or mesh analysis. In this laboratory anly the node method is considered. A resistance network is assembled and tested. The resulting measured voltages are compared with values calculated by solving the node equations and by a computer code (PSPICE) BEFORE LABORATORY: Ewvfauw eview the ECE 201 class notes covering Nodal Analysis APPARATUS REQUIRED Dual DC power supply with leads Multimeter with leads 5 resistors as specified by the instructor. 10 KO Variable resistor Assortéd hook-up wires PROCEDURE: Measure with the multimeter and record the actual resistance values. 1. Set up the circuit shown in Figure 1 using the variable resistor for R3 and the other values as specified by the instructor- 2 Set channel 1 of the power supply to 18 V (E) and connect it between node 0 and one end of resistor R,(node 4). Set channel 2 of the power supply to 6 V (E) and connect it between nodes 0 and 2. 3.

## NOTE: THIS SHOULD SOLVE BY PSPICE APP IN COMPUTER INCLUDING THE SIMULATION . Please

NOTE: THIS SHOULD SOLVE BY PSPICE APP IN COMPUTER INCLUDING THE SIMULATION . please I need to solve it by this way This is sample answer: _____________________________________________________________________________________________________________________________________________ This is the question ;

## 1. Change Message Symbol 1000011000001 To HDB3 Code. 2. Change Message Symbol 1000000000E011

1. Change Message symbol 1000011000001 to HDB3 code. 2. Change Message symbol 1000000000E011 to AMI code, HDB3 code, Biphase code 3. The Occurrence probability of Letter E is 0. 105, find its Information content I 4 Comparison of 13 broken line method and 15 broken line method 5. In 2ASK system, the Sinusoidal carrier is c(t)=5 cos 1000lIt, elementary modulation signal is m(t)=1 5 cos 2001It, find the modulated signal and draw its spectrum 6. x(t)=4e”e(t) is this a energy signals or a power signals? Try to find its energy spectral density or power spectral density 7. For an equal probability quaternary symbol with bit-width 125 u s. Find its symbol rate: RB and Information rate: rb

## A Rotameter Is Chosen To Measure Air Flow (SG=1.0), At 25oC And 1 Atmosphere

A rotameter is chosen to measure air flow (SG=1.0), at 25oC and 1 atmosphere pressure. However, it had to be used in an installation where the fluid is nitrogen (SG=0.967) at a pressure of 1.8 atmospheres and a temperature of 15oC. If you are reading 10l/min in the new installation, what is the correct flow (use the formula provided)? Q corrected = Q measured x Factor Subscript m = measured or actual conditions/reading on scale Subscript std = Standard, design or calibrated conditions Convert to absolute scales Kelvin and absolute pressure

## For The Circuit Shown, Use The Voltage Divider Rules To Find The Phasor V0

Get college assignment help at Smashing Essays For the circuit shown, use the voltage divider rules to find the phasor V0 I combined 15ohms with the j8 ohms in parallel, however using voltage divider on that combined impedance, the voltage is higher than the source.

## 3 Experiment Troubleshooting Ar Open Device Always Has Zero Current And Unknown Voltage The

3 Experiment Troubleshooting Ar open device always has zero current and unknown voltage The voltage present across the open terminals is determined by inspecting the rest of the circuit On the other hand, a shorted device always has the zero voltage and unknown current. The current flowing through the shorted device is determined by inspecting the rest of the circuit In this experi- ment, component failures will be inserted into a basic circuit and the voltages present across each device will be calculated and then verified through measurement GOOD TO KNOW In the schematic drawing, mark the predicted polarities on the resistors so that the DMM leads can be connected properly. Required Reading 5. Sketch Fig. 3-1 with R, shown as an open (removed). Calculate the voltages at nodes A and B. Record these values in Table 3-1. Next, open resistor R, by remov- Chapter 1 (Sec. 1-7) of Electronic Principles, 8th ed. ing one leg of the resistor from the circuit. Measure the voltages at nodes A and B. Record the values in Table 3-1, 6. Repeat Step 5 for each of the remaining resistors listed in Table 3-1. 7. Short-circuit resistor R, by placing a jumper wire across it. Calculate and record the voltages in Table 3-1. Equipment 1 power supply: 10 V 4 ½-W resistors: 1 kf), 2.2 k0, 3.9 k), and 4.7 kn 1 DMM (digital multimeter) Procedure 8. Repeat Step 7 for each of the remaining resistors in Table 3-1. 1. Sketch Fig. 3.1 and then calculate the voltage between node A and ground. Record the value in Table 3-11 under “Circuit OK.” 2. Calculate the voltage between node B and ground. Re- A WW 10 V cord the value. 3. Measure and record the value of cach of the resistors 22 kn 3.9 kn SR2 S47 kn used in this experiment. Connect the circuit shown in Fig. 3-1. 4. Measure the voltages at A and B. Record these values 1 kn in Table 3-1. Figure 3-1 11 w DATE NAME Experiment 3 Lab Partner(s) SCHEMATIC PARTS USED Nominal Value Measured Value 1 kn 2.2 kn 3.9 kn 4.7 kn CALCULATIONS TABLE 3-1. TROUBLES AND VOLTAGES Measured Calculated Multisim Actual Trouble VA V VA V’B Circuit OK R, open R; open Ry open R4 open Ri shorted R, shorted Ry shorted R, shorted

## EEE216 ELECTRONICS EXPERIMENT 1 DIODE APPLICATIONS YASAR ETANTSt ID NAME SIGNATURE PRELIMINARY WORK 1.

EEE216 ELECTRONICS EXPERIMENT 1 DIODE APPLICATIONS YASAR ETANTSt ID NAME SIGNATURE PRELIMINARY WORK 1. For the circuit given in Figure 1, make use of the characteristic curve of diode to determine IR1. IR1. and VR2 Si R2 R 12 VaV- R,=1000, R2 2600, I=90mA a7 v Figure 1. Experimental circuit diagram and characteristic curve of Si diode

## 1.2 A 0.4 A 22Q 6) What Is The Power Absorbed By The 1.2

1.2 A 0.4 A 22Q 6) What is the power absorbed by the 1.2 A current source in the circuit above? A. -31.3 W B. -21.1 W C. -10.56 W D. 21.1 W E. 42.2 W

## 02: A) Find The Phasor Representation V For Following: Ve’sin(5t 45°) 1) 2)

02: a) Find the phasor representation V for following: ve’sin(5t 45°) 1) 2) v 2e (3 cos3t 4 sin 3t) b) Find ) for following 1) I(s)=4 j3 with s= -1 j2 2) l(s)=-j6 withs=j4

## O 12.75 Amps Q18-A PV Module Has A Surface Area Of 1.5 M, And

o 12.75 Amps Q18-A PV module has a surface area of 1.5 m, and the radiation striking the module is 900 W/m What is the short circuit current (Isc) of the module if at 1 m2 Isc is 8.5 amps? o 5.67 Amps o 8.5 Amps o 11.3 Amps o 12.75 Amps keta de ane al

## D%4(κυ)G(ix-1) Cube Σ. 6nthe Side 1νeγtlon Χ Prove SbvΦ 5

please show all steps and write clearly im trying to learn for exam thank you!

## PRACTICE Und 4.2 For The Circuit Of Fig. 4.5, Compute The Voltage Across Each

PRACTICE und 4.2 For the circuit of Fig. 4.5, compute the voltage across each CUp source. 20 aso beEE68.0 geSaDblas M ww niSho 40 0.0 e latter n w .Using r’s rul 7 A 5Ω 3Ω 3 A .0- EE88 des 131 0.3167 keso Reference node FIGURE 4.5 Ans: v3A = 5.235 V; v7A = 11.47 V. 5929

## 1. For The Circuit Shown In The Figure Below, Determine The Current In The

1. For the circuit shown in the figure below, determine the current in the inductor L2 after the switch is closed at t 0 using Laplace transformations. [Hint: When switch is open the circuit achieves the steady state and L1 acts as short circuit. When switch is closed use KVL to the two loops to solve for 12(s). Find partial fractions, solve for i2(0)] R2= 22 L1 2H L2 3H i2 1V R1 2 2. Solve the following differential equation for it) using Laplace transform d2i di t22t dt2 dt di(0 -2 initial conditions i(0″) = 4 and dt Hint: take Laplace Transform substitute initial conditions, find partial fractions, and take inverse Laplace transform to get it). No convolution needed]

## EEE216 ELECTRONICS EXPERIMENT 1 DIODE APPLICATIONS YASAR ID NAME SIGNATURE 2 OBJECTIVE Through Experimentation,

EEE216 ELECTRONICS EXPERIMENT 1 DIODE APPLICATIONS YASAR ID NAME SIGNATURE 2 OBJECTIVE Through experimentation, be able observe and explain the principle of circuit operation in a number of diode applications in DC and AC circuits 220 1000 ZD 1512 v-36V POT 10K (a) Clamper Circuit (Voltage Doubler) (b) Zener diode circuit Figure 1. Experimental circuit diagrams EXPERIMENTAL WORK Part 1

## Part 2 1. Construct The Experimental Circuit Given In Figure 1 (b). 2. Set

Part 2 1. Construct the experimental circuit given in Figure 1 (b). 2. Set the resistance of potentiometer down to its minimum and using a multimeter, measure the voltage across the Zener diode. Vmeasured 3. Gradually increase the resistance of potentiometer and observe the measured voltage across the Zener diode. You are expected to make a brief explanation on the nature and cause of the change in measured voltage. Vmeasured,max

O 12.75 Amps Q18-A PV Module Has A Surface Area Of 1.5 M, And