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Gifts in the treasure chest of
Methodology: A personal view
Rolf Steyer
Friedrich Schiller University Jena
Institute of Psychology
Department of Methodology and Evaluation Research
Germany
Items in the treasure chest
•
•
•
•
•
•
•
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Latent Class Models
Mixture Distribution Models
Structural Equation Models
Generalized Linear Models
Loglinear Models
Multilevel Models
CART (Classification and Regression Trees)
...
• LISREL and the other SEM programs
• ConQuest and other IRT programs
• ...
• EM-Algorithm
• Newton-Raphson
• ...
Outline
• Measurement
• Causality
• Statistics
Outline
• Measurement
• Causality
• Statistics
I have deliberately choosen this order, because:
• (Causal) modeling does not make sense if we don´t have
reasonable measurements
• Statistcal analysis does not make sense if we don´t have
reasonable measurements and a causal model, if we are
looking for causal effects (which we do most of the time)
Measurement
The fundament of every science
-
Fundamental measurement theory
-
IRT, uni- and multidimensional
-
SEM modeling including models for ordinal variables
-
Multidimensional Scaling
Measurement
Measurement
-
is much more than assigning numbers to observations
-
defines the concepts to which empirical research really
refers to
-
explicates the relationship between observations and
theoretical concepts (constructs)
Measurement
Measurement
-
is not reading numbers from a meter stick
-
it rather means introducing the concept of length
-
and spells out the rules of assigning numbers to
observations representing the length of the objects
considered
Measurement (cont´d)
Measurement defines our theoretical concepts by
-
selecting the observables or items
-
specifying a mathematical measurement model
relating the observables to the theoretical concepts
Of course both these points need substantive theory and
ideas. They are part of the substantive theory.
Measurement (cont´d)
The measurement model determines
-
the logical nature of our theoretical variables
(metric, ordinal, or nominal concepts)
-
the scale level of the theoretical variables
Measurement (cont´d)
Latent variable models are flexible enough to model
complex reality
Measurement (cont´d)
1.00
SEELE
0.56
Trait 1
1.00
Depr1
1.00
A_DEPR1
0.10
A_DEPR2
0.11
C_DEPR1
0.03
C_DEPR2
0.09
D_DEPR1
0.04
0.74
D_DEPR2
0.12
0.70
E_DEPR1
0.03
0.70
E_DEPR2
0.11
0.85
0.08 1.00
-0.26
Trait2-1
-0.06
Trait 2
1.00
0.10
1.00
Depr2
1.00
0.85
1.00
1.00
Depr3
1.00
Trait3-2
1.00
1.00
0.85
Trait 3
0.97
Depr4
1.00
0.85
Chi-Square=35.77, df=20, P-value=0.01637, RMSEA=0.020
MetFac
Measurement (cont´d)
IRT-Models
-
introduce metric variables on the basis of qualitative
variables
-
allow adaptive testing
-
are recently going multivariate ...
Measurement (cont´d)
Where are we going?
-
IRT-Models and Structural Equation Models will
merge
-
Adaquate and sophisticated latent variable
modeling will increase
Causality
-
we know much more than „correlation is not
causality“ or „noncorrelation is not noncausality“
-
what we really want are individual causal effects,
what we get are expectations and their difference,
which are not the average of the individual causal
effects
Causality (cont´d)
-
If we have a client, we have at least two alternative
treatments for him
-
we are able to decide which treatment to choose
only when we have a hypothesis about the
individual effect of the treatment compared to its
alternative
-
when there is no knowledge about the individual
effect we need at least some knowledge about the
average effect
E(Y  X = x2, U = u)
E(Y  X = x1, U = u)
P(U = u)
Observational units
Causality (cont´d)
Individual treatment assignment probabilities
P(X = x1  U = u)
Example Ia
Example Ib
Example Ic
u1
1/2
85
91
1/4
1/2
1/3
u2
1/2
105
109
3/4
1/2
1/3
Note. According2 to the theorem of the total probability, the unconditional probability for treatment assignment
is P(X = x1) =  i1 P(X =x1  U = ui) P(U = ui) = 1/2 for Examples Ia and Ib and P(X = x1) = 1/3 for Example Ic.
 u E(Y  X = x , U = u) P(U = u  X = x ) = 85  1/4 + 105  3/4 = 100,
1
1

u
E(Y  X = x ) =
E(Y  X = x , U = u) P(U = u  X = x ) = 91  3/4 + 109  1/4 = 95.5.
E(Y  X = x1) =
2
2
2
Causality (cont´d)
we know
-
sufficient conditions for causal unbiasedness
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necessary conditions for unconfoundedness
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how to analyze causal effects in nonorthogonal ANOVA
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how to test for unconfoundedness
Causality (cont´d)
Where are we going? We will learn more about
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nonexperimental design and analysis
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systems of regression equations (causality in SEMs)
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generalize to distributions
-
applying it to sophisticated data
Statistics
-
statistical tests important, but are we really happy with
knowing the probability of the test statistic being this or
more extreme under the assumption of H0 ?
-
Shall we be going Bayesian and ask for the probabilities of
hypotheses?
-
How long will it take for the resampling procedures
(bootstrapping etc.) to be an easy tool in our standard
software?
Conclusions
-
There is much more in our treasure chest than an
individual could even learn and apply
-
Hence we need to organize, distribute and teach our
knowledge in a more efficient way
-
Intensifying cooperation in Europe may be one way to
achieve these goals
Where to find more
For example, this power point file and more useful things, such as
papers, infos on workshops etc. may be found at:
http://www.uni-jena.de/svw/metheval/
Or mail to:
[email protected]