In the context of scientific measurement, precision and accuracy are two fundamental concepts that describe the quality of data. While often used interchangeably in everyday language, they have distinct meanings. Understanding this difference is crucial for interpreting experimental results and minimizing errors.
Definition: Precision refers to the consistency and reproducibility of a measurement. It describes how close a series of measurements of the same quantity are to one another.
Indicator of Random Error: High precision indicates low random error. If repeated measurements are tightly clustered, the random error is small.
Relationship to Instrument: Precision is often determined by the limitations of the measuring instrument, specifically its least count (the smallest value it can measure).
Significant Figures: The number of Significant Figures→ in a measurement reflects its precision. More significant figures imply a more precise measurement (e.g., 5.432 g is more precise than 5.4 g).
Example of Precision: An archer shoots three arrows that all land very close to each other, but far from the bullseye. This is a display of high precision but low accuracy. In measurements, values like 15.81 g, 15.82 g, and 15.81 g are highly precise.
Example of Accuracy: An archer shoots an arrow that lands directly in the center of the bullseye. This is an accurate shot. If the true mass of an object is 20.00 g, a measurement of 20.01 g is highly accurate.
The classic analogy of a target helps illustrate the distinction:
| High Accuracy | Low Accuracy | |
|---|---|---|
| High Precision | All shots are tightly clustered on the bullseye. | All shots are tightly clustered but off-center. |
| Low Precision | Shots are scattered, but their average is on the bullseye. | Shots are scattered and not centered on the bullseye. |
| Aspect | Precision | Accuracy |
|---|---|---|
| Definition | How close repeated measurements are to each other. | How close a measurement is to the true value. |
| Related Error | Random Error | Systematic Error |
| Indicated by | Absolute uncertainty, significant figures, least count. | Percentage uncertainty, comparison to a known standard. |
All measurements contain some degree of uncertainty — this is an unavoidable feature of measurement, not a sign of poor technique. Sources of unavoidable uncertainty include:
Example: For a measurement of cm:
For more on uncertainties, see Uncertainties In Final Result→.
Q: Can a measurement be accurate but not precise? A: Yes. If you take several measurements that are widely scattered (low precision) but their average happens to be very close to the true value, the overall result could be considered accurate.
Q: Which is more important, precision or accuracy? A: In science, the goal is to be both precise and accurate. High precision suggests a reliable method, but without accuracy, the results are misleading. High accuracy without precision might mean you got lucky with an average.
Understanding and controlling for factors that affect precision and accuracy is fundamental to reliable data collection in all scientific and engineering fields. For more on types of errors, see Errors→.