EXPERIMENT 6 SUPERPOSITION - INTERFACE CIRCUITS - MAX POWER TRANSFER OBJECTIVE: • To implement the circuits...
EXPERIMENT 11 STEP RESPONSE TO RC AND RL CIRCUITS pages 11-4 thru 11-7. tep response of the RC and RL circuits is included in OBJECTIVE: O analyze the voltage and current characteristics of a Resistance - Capacitance (RC) circuit when driven by a step voltage function. To analyze the voltage and current characteristics of a Resistance- Inductor (RL) circuit when driven by a step voltage function To design an RC circuit to yield a specified output voltage with a step...
Name: ENGT 3050 Fundamentals of Electricity LAB EXERCISE #3 Series and Parallel Circuits Objectives: The objective of this exercise is to examine Kirchhoff's Voltage and Current Laws. Kirchhoff's Voltage Law (KVL) states, for a closed loop series path the algebraic sum of all the voltages around any closed loop in a circuit is equal to zero. Kirchhoff's Current Law (KCL) states, for a parallel path the total current entering a circuits junction is exactly equal to the total current leaving...
EE 282-Circuit I Pre-Lab 9 Maximum Power Transfer Theorem Name Concepts: In this pre-lab we will be leaming about Maximum Power Transfer Theorem. Maximum power is transferred to the load when the load resistance equals the thexenin equivalent, and we carry out the analysis using Thevenin's equivalent circuit. In order to do this, first build the following circuit on Mutism. 1 R1 5.1k0 R3 2 V1 R2 8kQ 6.8㏀ Fig. 1 Part 1: To find the Thevenin equivalent resistance, we...
Use measured resistance values and node analysis to calculate the node voltages. Use measured resistance values and mesh analysis to calculate the mesh currents. Show that the calculated values agree with the measured values and explain any discrepancies between measured and calculated values. Introduction: In this pre-lab we will look at node voltages, mesh currents and bridge circuits. Bridge Circuits are used to make precision measurements, and in this lab -- -0 V2 will look at a DC Bridge Circuit...
would you like please answer all questions in part 3 THEVENIN'S THEOREM AND MAXIMUM POWER TRANSFER 131 Part 3 Maximum Power Transfer (Experimental Approach) (a) Construct the network of Fig. 11.8. Insert the measured value of each resistor R EIOV 95.732 218S2 325 2 . 424e R FIG. 11.8 Eths Vabs 6.8v Rths Resissn (b) The Thevenin equivalent circuit will now be determined for the network to the lel of the terminals a-b without disturbing the structure of the network....
Problem 1) [15 marks] The gain of the dual-op-axap instrumentation amplifier shown in Fig. 1 can be adjusted by the variable resistor Ro. The op-amps are ideal. atu Fig. 1 a)Show that v.-2(1 RG )(v2-v.). b Specify suitable components to have a variable gain from 10 to 100 V/V. Problem 2) [15 marks] a) Design an op-amp limiter circuit for amplitude control with the transfer characteristic of Fig. 2(a). Use +-15V DC sources to power the circuit. Assume Vo-0.7 V...
ENGR 1181 Lab 3: Circuits Preparation Material Lab 3: Circuits Lab-Pre-lab Assignment Team Seat No. Name This is an individual assignment Solve the five problems below and hand it in at the beginning of the Circuits Lab. Show all your work Problem 1. Ohm's Law For the circuit below, calculate the value of the resistor R which would cause the current of 2.5 mA to flow in the circuit What voltage would you measure across the resistor? Show your calculations....
Fall 2019 ECEN 206 Lab 4 Thevenin Equivalent Circuits Due First week of November Introduction: This lab focuses on the Thevenin equivalent circuit and maximum power transfer theorems Complex circuits are often replaced with their Thevenin equivalent to simplify analysis. For example, in the analysis of large industrial power systems the Thevenin equivalent is used in short circuit studies. Maximum power transfer is also an important concept which allows the designer to determine an optimal design when power is a...
Course and Section cto EXPERIMENT ac series-Parallel Sinusoidal Circuits OBJECTIVES 1. Measure the currents of series-parallel R-L and R-C networks using sensing resistors 2. Demonstrate the Pythagorean relationship between the currents of the networks. 3. Measure the phase angles associated with the currents of the networks. 4. Calculate the input impedance of a parallel network using measured values EQUIPMENT REQUIRED Instruments Resistors 1-10-Q, 470-Ω, l-kM (14.W) Inductors 1-10-mH Capacitors 1-0.02-pF I-DMM 1--Oscilloscope 1-Audio oscillator or function generator 1--Frequency counter (if...
Lab 4-Circuits with Dependent Power Sources-A.pdf Lab Procedure: Part 1: Circuit with Dependent Voltage Source, Current Controlled Enter the circuit below using Multisim Schematic capture and use Multisim Simulation for analysis node voltages and branch currents. Compare the Simulation results with the theoretical analysis results showing all calculations. Verify that KCL holds true at node 2 showing all work. Use Ohm's Law and/or KVL as needed for analysis. Comment on any differences in experimental versus theoretical results. 5k VI 4...