# 3.13: Percent Error

- Page ID
- 52697

### Introduction

A complicated piece of electronics equipment may contain several resistors whose role is to control the voltage and current in the electrical circuit. Too much current and the apparatus malfunctions. Too little current and the system simply does not perform. The resistor values are always given with an error range. A resistor may have a stated value of 200 ohms, but a \(10\%\) error range, meaning the resistance could be anywhere between 195 and 205 ohms. By knowing these values, an electronics person can design and service the equipment to make sure it functions properly.

### Percent Error

An individual measurement may be accurate or inaccurate, depending on how close it is to the true value. Suppose that you are doing an experiment to determine the density of a sample of aluminum metal. The **accepted value** of a measurement is the true or correct value based on general agreement with a reliable reference. For aluminum the accepted density is \(2.70 \: \text{g/cm}^3\). The **experimental value** of a measurement is the value that is measured during the experiment. Suppose that in your experiment you determine an experimental value for the aluminum density to be \(2.42 \: \text{g/cm}^3\). The **error** of an experiment is the difference between the experimental and accepted values.

\[\text{Error} = \text{experimental value} - \text{accepted value}\]

If the experimental value is less than the accepted value, the error is negative. If the experimental value is larger than the accepted value, the error is positive. Often, error is reported as the absolute value of the difference in order to avoid the confusion of a negative error. The **percent error** is the absolute value of the error divided by the accepted value and multiplied by \(100\%\).

\[\% \: \text{Error} = \frac{\left| \text{experimental value} - \text{accepted value} \right|}{\text{accepted value}} \times 100\%\]

To calculate the percent error for the aluminum density measurement, we can substitute the given values of \(2.45 \: \text{g/cm}^3\) for the experimental value and \(2.70 \: \text{g/cm}^3\) for the accepted value.

\[\% \: \text{Error} = \frac{\left| 2.45 \: \text{g/cm}^3 - 2.70 \: \text{g/cm}^3 \right|}{2.70 \: \text{g/cm}^3} \times 100\% = 9.26\%\]

If the experimental value is equal to the accepted value, the percent error is equal to 0. As the accuracy of a measurement decreases, the percent error of that measurement rises.

### Summary

- Definitions of accepted value and experimental values are given.
- Calculations of error and percent error are demonstrated.

### Contributors

CK-12 Foundation by Sharon Bewick, Richard Parsons, Therese Forsythe, Shonna Robinson, and Jean Dupon.