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Latent Growth Curve Analysis
Daniel Boduszek
Department of Behavioural and Social Sciences
University of Huddersfield, UK
d.boduszek@hud.ac.uk
Introduction to Latent Growth Analysis
Amos procedure
Interpretation of results
Outline
Latent Growth Curve Analysis – a way to explain change Measurement has to be taken at 3 or more times With two data points, a straight line will fit perfectly, every
time, because two points determine a line There is nothing to test (no degrees of freedom - no data that
could disprove the straight line)
2 statistical approaches for studying change (LGA) Structural equation modelling of latent growth curves (our
focus!!!) Multilevel modelling (hierarchical modelling)
Introduction
Change
Linear – going up or down in a straight direction
Non-linear - going up rapidly and then leveling off
Introduction
Two parameters determine a straight line
One of them is Intercept
It is the value at the start of the process.
Sometimes call it a constant, because it is what we start
with and the standard from which change is measured
Growth curve—the intercept
The intercept for the range of data is 10 (mean). The 13-year-olds have an average delinquency score of 10
The intercept is the value of the outcome when the growth curve begins
Growth curve—the intercept
Slope – parameter which tells us much the curve grows over time
Between13 to 17 years old the mean delinquency score jumps from 10 to 70
The slope is 15 (average)
Growth curve—the slope
Latent Growth Model
Delinquency Measured at Age 13, 14, 15, and 16
Latent Growth Model
We assume our measures are not perfectly reliable
Variety of symbols are used for measurement error including e, ε and δ.
Latent Growth Model
There might be more than one slope for complex nonlinear models.
Latent Growth Model
The four lines from the intercept to the four y’s are all fixed at a constant value of 1
Since all four values are fixed at the same value, this is the constant level of delinquency, if there were no growth
Latent Growth Model
The values for the lines are fixed at 0, 1, 2, and 3 respectively
0 means zero growth – the initial level
Fixing the values from the slope is how you identify model growth
Latent Growth Model
Using values of 1, 2, and 3 results in a linear growth curve, since there is a 1-year difference between each measure
The y1 is delinquency at the age of 13, the y2 is one year later at 14 (so its value is 1), the y3 is one more year latter at 15 (so its value is 1 + 1 = 2), and y4 is one more year later at 16 (so its value is 1 + 1 + 1 = 3)
Suppose we had no data for when the adolescents were 14 we would use 0, 2, and 3
Latent Growth Model
If the model should have a curve, we would have two slopes.
One would be fixed at 0, 1, 2, and 3 as in Figure 13. The Second slope would have the four paths fixed at 0, 1, 4, and 9, the square of the corresponding the linear paths
Latent Growth Model
For both the slope and intercept there is a mean and a variance.
Mean Intercept: Where does the
average person start? Slope: What is the average
rate of change?
Variance Intercept: How much do
individuals differ in where they start?
Slope: How much do individuals differ in their rates of change: “Different slopes for different folks.”
Latent Growth Model
Correlation of variances
If positive covariance It means that individuals
who have higher intercepts also have higher slopes and individuals with lower intercepts have lower slopes
E.g., an adolescent who starts out with a high initial level of delinquency will become increasingly more delinquent than others
Latent Growth Model
Latent Growth Model with predictors
Empirical Example with Two Growth Curves
Amos procedure for LGM
Data used in this example:
268 offenders from high security prison
Criminal identity measured at 3 time points (2009, 2010, 2011)
To launch the Amos on your computer go to Start
All Programs
IBM SPSS Statistics
IBM SPSS Amos 20
Amos Graphics
Amos is a part of IBM SPSS software thus it can read the SPSS file without converting.
To load the data go to File and Data Files.
The Data Files dialog box then opens.
Click on File Name and navigate to the location where the data file is stored.
By default, Amos looks for an SPSS file.
Choose Plugins ---> Growth Curve Model.
Enter the number of measures when you are prompted for the number of time points.
In this example, you would enter 3 for the number of time points because you have data for criminal identity at 3 distinct points in time
Choose View ---> Analysis Properties ---> Estimation tab.
Check the Estimate Means and Intercepts check box.
Choose Output tab ---> Standardized regression weights
Click on View and select Variables in Data Set
Click on (and hold) your first observed variable (CrIdent) and move it to the observed box (X1)
Then CrIdent2 to X2 and CrIdent3 to X3
Right-click on each of the 3 observed variable boxes one at a time and select Object Properties.
Click on the Parameters tab to fix the intercept parameter; fix each observed variable's intercept value to 0
Specify regression weights for each parameter. All of the Intercept paths get a regression weight of 1 (automatically done ). The slope gets a weight relative to the time point for each measure (in this example 0, 1, 2).
Move the pointer onto the arrow that leads from the slope to the Criminal Identity variable so it is highlighted
Right click and select Object Properties from the menu
Specify a value of 0 for the regression weight
Keep the Object Properties window open while you move to the next arrows and apply the appropriate weights to the slope
You can create a Figure Caption that displays important information about your model. This will help you identify important changes as you test different models.
Select the Diagram option from the Main Menu
Select the Figure Caption option and left click above your path diagram
In the Caption window type the following commands:
chi square = \cmin
df = \df
p = \p
It is now time to fit the model.
Choose the Analysis tab from the Main Menu
Select the Calculate Estimates option
Result (Default model) Minimum was achieved Chi-square = 15.263 Degrees of freedom = 3 Probability level = .002
Before interpreting the results on the model diagram, you should first verify that the model fits the data well on an overall basis.
The chi-square test of overall model fit was statistically significant (chi-square = 15.263, df= 3, p = .002). Model does not fit the data Warning: Chi-square is
sensitive to large sample (more than 200)
Check CFI and TLI in Baseline
Comparison (values above .95 indicate good model fit) Good fit!
After you determine that the model fit the data acceptably, you may interpret the parameter estimates.
The mean intercept value of 18.81 indicates that the average starting amount of criminal social identity was 18.81 units.
The mean slope value was 7.34 (the average growth in criminal social identity).
Criminal social identity is expected to increase by 7.34 each studied time period, beginning with an average score of 18.81
The means and variances were statistically significant when tested with the null hypothesis
Substantively, the finding that the variances of the intercepts is statistically significant suggests that there is non-trivial variation in the amount of criminal social identity at the initial time point.
Significant variation in slope values, indicating that criminal social identity may be quite varied over time.
Interestingly, the amount of criminal social identity at the initial time of measurement appeared to be unrelated to changes over time, as illustrated by the non-significant correlation of .08 between the slopes and intercepts.
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