I. Introduction
In today’s society, the need to have an adequate supply of electricity to run everyday tasks is in greater demand than ever. Everyday we turn our lights in our homes on and off without really thinking about if there is enough electricity to power each and every light. Throughout this paper, we examine Kirchhoff’s Voltage Law the sum of the electrical potential differences around any closed network is zero [1]. Represented by the equation ΣV=0, which means v1+ v2+ v3+…+ vn=0 [2]. A way at looking at this equation in words is by the sum of the voltage rises in the loop will equal the sum of voltage drops in the loop [2]. By applying this principle electrical engineers can use this to determine if there is enough energy to power an entire circuit ranging from small items like a flashlight, to skyscrapers in the world’s largest cities.
II. Procedure
Three experiments were performed in order to prove Kirchhoff’s Voltage Law. The first experiment performed would verify that the voltage across a straight path would add up to the same voltage summed from the voltage sources. The second experiment performed would be to verify that voltage across multiple paths would add up to the voltage of the voltage source. The third experiment performed would be to verify that both of the ideas expressed in experiment one and experiment two would remain consistent together.
All of the experiments we performed utilized a voltmeter, a breadboard, some wire, two different types of voltage sources, and resistors with a range of resistance. All components were plugged into the breadboard for ease of testing purposes using the voltmeter.
For experiment one, a continuous loop was made on the bread board using a 9 volt (v) bat...
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...al zero; known as Kirchhoff’s Voltage Law. With the three trials conducted we were able to provide evidence to prove that the sum will in fact equal zero. Kirchhoff’s Voltage Law is a very important tool engineers can use to determine whether or not there is enough voltage in a closed circuit to carry a current through the world’s tallest skyscrapers so the entire building can be with electricity.
Works Cited
[1] Kirchhoff’s Voltage Law. (nd). Arizona State University. [Online]. Available: http://holbert.faculty.asu.edu/ece201/kvl.html.
[2] American Academy of Arts and Sciences, “Gustav Robert Kirchhoff,” Proceedings of the American Academy of Arts and Sciences, Vol. 23, No. 2, pp. 370-375, May, 1888
[3] Scolof, Sidney, (26, January 2008). How Circuits Work. HowStuffWorks.com [Online]. Available: http://science.howstuffworks.com/environmental/energy/circuit.html
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