R Circuit: Difference between revisions
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==Mathematics== | ==Mathematics== | ||
As discussed above, resistance of a material is dependent on two factors: the properties of the material, and the area of the resistor. | |||
From the above factors, we get the following definition of resistance: | |||
<math>R = \frac{L}{σ A}</math> | |||
In this definition <math> L </math> is the length of the resistor, <math> A </math> is the cross-sectional area of the resistor, and <math> σ </math> is the conductivity of the material. | |||
<math> σ </math> can be further broken down to show <math> σ = |q|nu </math>. | |||
Revision as of 18:33, 22 November 2017
Claimed by Matthew Munns - Fall 2017
Resistors may exist in a circuit and resist electric charge. The resistance of a resistor depends on the properties of the material and the area of the resistor. These two attributes will be investigated later in the page.
Resistors may be ohmic or non-ohmic. An ohmic resistor has a conductivity that is nearly constant, while a non-ohmic resistor will vary depending on the conditions. This page will focus on ohmic resistors in a complex circuit.
The following is an image of an ohmic resistor like the resistor used in lab:
Mathematics
As discussed above, resistance of a material is dependent on two factors: the properties of the material, and the area of the resistor.
From the above factors, we get the following definition of resistance: [math]\displaystyle{ R = \frac{L}{σ A} }[/math]
In this definition [math]\displaystyle{ L }[/math] is the length of the resistor, [math]\displaystyle{ A }[/math] is the cross-sectional area of the resistor, and [math]\displaystyle{ σ }[/math] is the conductivity of the material. [math]\displaystyle{ σ }[/math] can be further broken down to show [math]\displaystyle{ σ = |q|nu }[/math].