- Using PVAAS for a Purpose
- Key Concepts
- Concept of Growth
- Growth Measures and Standard Errors
- Growth Standard Methodology
- Predictive Methodology
- Topics in Value-Added Modeling
- Public Reports
- Additional Resources
- General Help
Due to the pandemic's impact on student learning, the 2020-21 reporting might yield patterns between growth and student characteristics that are different from the typical relationships. These trends provide information on students' different learning experiences during the pandemic.For more information about changes to reporting, see What's New in 2021 and the Statistical Models and Business Rules.
Interpreting the Data
Scatterplots illustrate the relationship between two variables, such as achievement and growth. Specifically, scatterplots enable you to visually examine the relationship between the variables and answer the question, "As variable A changes, what happens to variable B?" In the case of achievement and growth, you might ask, "As the average achievement of students in a school increases, does the average growth also increase?" In other words, is there a relationship between achievement and growth?
When data points on a scatterplot are distributed somewhat symmetrically along a horizontal or vertical line, there is little to no relationship between the selected variables.
On the other hand, a more diagonal pattern indicates that the variables are related. The closer the pattern is to a diagonal line, the stronger the relationship.
Variables are positively correlated if one variable increases or decreases as the other variable increases or decreases. A good example of positive relationship is that of temperature and the sale of ice cream. As the temperature rises, ice cream sales rise with it.
Variables are negatively correlated if they move in opposition to each other. In other words, when one increases, the other decreases. For example, as the temperature goes up, sales of hot chocolate go down.
When interpreting the relationship between two variables on a scatterplot, it's important to remember that correlation does not prove causation. If variable B increases as variable A increases, that does not necessarily mean that changes in variable A caused the changes in variable B. Also, if the graph contains only a small number of data points, a correlation might be suggested that does not exist in a larger set of data.
For example, if we were to create a scatterplot of achievement vs. growth in fifth-grade math and we included only a few schools, the relative achievement and growth of those schools would determine the correlation that is suggested in the graph. We might mistakenly conclude that achievement and growth are positively correlated if the selected schools that serve a lower-achieving population of students haven't had great success in helping those students make academic growth, and the other schools serve a higher-achieving population of students and have had great success with student growth. In other words, we might believe that schools serving lower-achieving students cannot achieve high growth.
However, comparing only a few schools might not offer a fair representation of the true relationship between achievement and growth. If we added all the schools in the LEA/district to the scatterplot, we would see little to no relationship between the two variables. With that in mind, it's important to be careful when drawing conclusions from small amounts of data on a scatterplot.