phenotypic multivariate analysis. last 2 days……. 1 p a a c c e e 1/.5 a cecae p
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Phenotypic multivariate analysis
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Last 2 days…….
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This lecture
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This lecture
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Data analysis in non-experimental designs using latent constructs
Principal Components Analysis Triangular Decomposition (Cholesky) Exploratory Factor Analysis Confirmatory Factor Analysis Structural Equation Models
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Principal Components Analysis
SPSS, SAS Is used to reduce a large set of correlated
observed variables (xi) to (a smaller number of) uncorrelated (orthogonal) components (yi)
yi is a linear function of xi Transformation of the data, not a model
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PCA path diagram
D
P
S = observed covariances = P D P’
x1 x2 x3 x4 x5
y1 y2 y3 y4 y5
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PCA equations
Covariance matrix qSq = qPq qDq qPq’ = P# P # ’ P = orthogonal matrix of eigenvectors D = diagonal matrix with eigenvalues P’P = I and P# = P D Criteria for number of factors Kaiser criterion, scree plot, %var Important: models not identified!
x1 x2 x3 x4 x5
y1 y2 y3 y4 y5
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Correlations: satisfaction, n=100
Var 1
work
Var 2
work
Var 3
work
Var 4
home
Var 5
home
Var 6
home
Var 1 1
Var 2 .65 1
Var 3 .65 .73 1
Var 4 .14 .14 .16 1
Var 5 .15 .18 .24 .66 1
Var 6 .14 .24 .25 .59 .73 1
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++++ ++
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work home
Var 1 Var 2 Var 3 Var 4 Var 5 Var 6
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Triangular decomposition (Cholesky)
x1 x2 x3 x4 x5
y1 y2 y3 y4 y5
1 operationalization of all PCA outcomes
Model is just identified and saturated (df=0)
1 1 1 1 1
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Triangular decomposition
S = Q * Q’ ( = P# * P# ‘)
5Q5 = f11 0 0 0 0f21 f22 0 0 0f31 f32 f33 0 0f41 f42 f43 f44 0f51 f52 f53 f54 f55
Q is a lower matrix This is not a model! This is a transformation of
the observed matrix S. Fully determinate!
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Matrix algebra, Cholesky
3Q3 = f11 0 0
f21 f22 0f31 f32 f33
Calculate Q * Q’
Var x1: f11*f11Var x2: f21*f21+f22*f22Cov x1,x3: f31*f11Cov x2,x3: f31*f21+f32*f22
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Exploratory Factor Analysis
Account for covariances among observed variables in terms of a smaller number of latent, common factors
Includes error components for each variable x = L * f + u x = observed variables f = latent factors u = unique factors L = matrix of factor loadings
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EFA path diagram
C
L
U
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EFA equations
S = L * C * L’ + U * U’ S = observed covariance matrix L = factor loadings C = correlations between factors U = diagonal matrix of errors
Correlations between latent factors are allowed
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Exploratory factor analysis
No prior assumption on number of factors All variables load on all latent factors Factors are either all correlated or all
uncorrelated Unique factors are uncorrelated Underidentification
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Confirmatory factor analysis
A model is constructed in advance The model has a specific number of factors Variables do not have to load on all factors Measurement errors may correlate Latent factors may be correlated
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CFA
An initial model (i.e., a matrix of factor loadings) may be specified, because:
its elements have been obtained from a previous analysis in another sample
its elements are described by a theoretical process
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CFA equations
x = L * f + u x = observed variables, f = latent factors u = unique factors, L = factor loadings S = L * C * L’ + U * U’ S = observed covariance matrix L = factor loadings C = correlations between factors U = diagonal matrix of errors
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Structural equations models
The factor model x = L * f + u is sometimes refered to as the measurement model
The relations between latent factors can also be modelled
This is done in the covariance structure model, or the structural equations model
Higher order factor models
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Structural Model
X1
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X2
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X3
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X6 X7
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Practice!
Problem behavior in children (CBCL at age 3) 7 syndromes (aggression, oppositional,
withdrawn/depressed, anxious, overactive, sleep and somatic problems
Syndromes are correlated
Datafile: cbcl1all.cov
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Observed correlations (2683 subj.)
Opp w/d agg anx act sleep Withdrawn .41 Aggression .63 .35 Anxious .45 .47 .27 Overactive .53 .34 .52 .29 Sleep .32 .24 .28 .26 .23 Somatic .21 .22 .18 .17 .15 .23
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Cholesky: How many underlying factors?– S = Q * Q’, Q is 7x7 lower– Fact7.mx
What is the fit of a 1 factor model?– S = F * F’ + U, F = 7x1 full, U = 7x7 diagonal– Fact1.mx
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What is the fit of a 2 factor model?– Same model,but F = 7x2 full with loading of aggression fixed– Fact2.mx
Achenbach suggests 2 factors: externalizing and internalizing: what is the evidence for this model?
– Same model, F = 7x2 full, internalizing factor and externalizing factor
– Fact2a.mx
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Can the 2 factor model be improved by adding a 3rd general problem factor or by having a correlation between the 2 factors?
– Same model, F = 7x3 full with general factor, internalizing factor and externalizing factor, Fact3.mx
– S = F * C * F’ + U, F = 7x2 full matrix, C = stand 2x2 matrix (correlation), U = 7x7 diagonal matrix, Fact2b.mx