Abstract
Developing a better understanding of the measurement process and measurement uncertainty is one of the main goals of university physics laboratory courses. This study investigated the influence of graphical representation of data on student understanding and interpreting of measurement results. A sample of 101 undergraduate students (48 first year students and 53 third and fifth year students) from the Department of Physics, University of Zagreb were tested with a paper-and-pencil test consisting of eight multiple-choice test items about measurement uncertainties. In one version of the test items included graphical representations of the measurement data. About half of the students solved that version of the test while the remaining students solved the same test without graphical representations. The results have shown that the students who had the graphical representation of data scored higher than their colleagues without graphical representation. In the second part of the study, measurements of eye movements were carried out on a sample of thirty undergraduate students from the Department of Physics, University of Zagreb while students were solving the same test on a computer screen. The results revealed that students who had the graphical representation of data spent considerably less time viewing the numerical data than the other group of students. These results indicate that graphical representation may be beneficial for data processing and data comparison. Graphical representation helps with visualization of data and therefore reduces the cognitive load on students while performing measurement data analysis so students should be encouraged to use it.
Highlights
Measurement is the basis of the scientific method, and as such is fundamental for student understanding of experimental work
About half of the participants (48) were first-year students and they were tested during their first semester, so they did not have any prior experience with university physics laboratory
Previous physics education research (PER) studies suggested that graphical representation of the data might be helpful in understanding measurement and data processing, but this issue had not been systematically studied
Summary
Measurement is the basis of the scientific method, and as such is fundamental for student understanding of experimental work. Understanding of measurement and measurement uncertainty is crucial for all phases of experimental work and, these concepts are introduced through physics laboratories and statistics courses. The professional association of physics teachers emphasizes that “students should learn enough about uncertainties to understand the inherent limitations of measurement processes” [1]. Several physics education research (PER) studies focused on student understanding of measurement uncertainty and their ability to process and compare experimental data [2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17]
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