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The venin Equivalents and Max Power Transfer

Abstract

            The present lab report is based upon the venin Equivalents and Max Power Transfer. The objectives of the report are to describe and explain the venin Equivalents and Max Power Transfer. It is important to fully describe such functions.  Moreover, the lab report is also designed to make simplify and verify the circuit network that is quite necessary to make identification to the level of the venin equivalent. In addition, it is also important that the maximum level of power transfer is also needed to investigate. The result of the lab reports are important and show that the venin equivalent circuits are necessary to close. It is enough to the original level that is equal to the level of 470 Ω. Moreover, the maximization of the power is dependent on the completion of the circuit in an effective manner.

Introduction

            The present lab report is designed to describe the venin Equivalents and Max Power Transfer. Moreover, the simplification and verification of the circuit network is necessary to identify to the venin equivalent. In addition, the maximum level of power transfer was also identified.  The venin theorem is applied on the DC resistive circuits. The theorem holds that the linear electronic network with the help of the voltage as well as the current sources is important and the level of resistance can be replaced with the equivalent voltage source. To fulfill such objectives, the lab experiment was designed.

             The material for the experiment includes three types of the resistors. First resister is 1 of 470 Ω. The second resister is of 2 of 1k Ω and the last one is 2 of 2k Ω.  One potential meter is also required which is equal to 2k Ω with screw drive. In addition, the banana to alligator clip test cables is also essential. Two pairs are required in that regard. Moreover, cadet breadboard is also necessary in that realm. This is the complete and essential list of material required to complete the experiment.

            First the actual resistor resistance was measured and then circuit was building on the banana board. After that open circuit voltage across terminal AB was measured and short circuit that pass through the terminal AB. The calculation of the venin equivalent residence was also evaluated. Voltage across the board and resistant terminal was also calculated. The result of the report shows that the venin equivalent circuits are close enough to the original level of 470 Ω. Moreover, the maximization of the power is dependent on the completion of the circuit in an effective manner.                                                Rth

                                                                                                C

+ –

            Vth

                                                                        RL

                                                                                                D

The remaining section of the report is conclusion that will elaborate the conclusive remarks that will be drawn upon the results that were presented in the experiment. This section will state whether the desired level of results are maintained or not.  

Conclusion

            It can be concluded that the lab report provides sufficient results in that regard. The result of the report explains that the circuits are related to the original level of current that is equivalent to 470 Ω. Besides that, the maximization of the range of the power is also dependent and that is required to the completion of the circuit in an effective manner. The results are related to the observed number of the reading that is required. The level of the current in the circuit is up to the minimum level of the current that is required in order to complete the circuit with 470 Ω. Moreover, Voltage across the board and resistant terminal was also up to the desired level and the circuit is essential to produce the same level of electricity that is equal to keep flow the current.

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