Modeling item response profiles using factor models, latent class models, and latent variable hybrids Dena Pastor James Madison University [email protected].

Modeling item response profiles using factor models,

latent class models, and latent variable hybrids

Dena Pastor

James Madison University

[email protected]

Purposes of the Presentation

• To present the model-implied item response profiles (IRPs) that correspond to latent variable models used with dichotomous item response data

• To provide an example of how these models can be used in practice

Item Response Profiles (IRPs)

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Item Number

Pro

port

ion

Res

pond

ing

Cor

rect

ly

Pattern Differences

IRPs for classes of examinees with different patterns

Elevation Differences

IRPs for classes of examinees with the same pattern, but differences in elevation

Latent Variable Model

PARALLELNON-PARALLEL

C

Latent Class Model

C is a latent categorical

variable with as many levels as #

of classes

C is a nominal latent variable

C is a ordinal latent variable

Exploratory Process

• In latent class modeling a variety of models are fit to the data with differing numbers of classes– 1-class model, 2-class model, 3-class

model, etc.

• Use fit indices and a priori expectations to determine the number of classes to retain

• Can allow latent categorical variable to be nominal and examine resulting profiles; can also constrain latent categorical variable to be ordinal

Alternative Model for Parallel Profiles

Do we have 3 classes, with no variability within class?

OR

Do we have 1 profile with systematic variability within class?

F

Factor ModelF is a latent continuous

variable

Different Models for Different IRPs

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1 profile…

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…+ within profile variability

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2 parallel profiles…

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…+ within profile variability

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2 non-parallel profiles…

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…+ within profile variability

LCM: 1 class

Factor Model

LCM: 2 classes (C is

ordinal)

Semi-parametric

Factor Model

LCM: 2 classes(C is nominal)

Factor Mixture Model

Latent Variable Hybrids

Deci

sion

sM

od

els

IRP

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1

Number of profiles?(number of

classes)

no

Latent class model(LCM)

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yes

Factor model(FM)

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Systematic variability

within profiles?

1+

Nature of profile

differences?

Parallel

LCM with

parallel

profiles

Semi-parametric factor model

(SPFM)

Systematic variability

within profiles?

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no

yes

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Non-parallel

Factor mixtur

e model(FMM

)

LCM with non-

parallel profiles

Systematic variability

within profiles?

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no

yes

Sem

i-p

ara

metr

ic f

act

or

mod

el

(SP

FM

)

F C

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2 classes

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FC

1 class: Factor Model!

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F C

2 classes, w/in class factor variance = 0

2 classes

Fact

or

mix

ture

mod

el

(FM

M)

F C

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1 class: Factor Model!

F C

CLatent class model(LCM)

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F C

2 classes, w/in class factor variance = 0

1

( 1| ) ( 1| )K

i k ik

P u P u c

Marginal probability of getting an item correct is sum across classes of probability of getting item correct conditional on class membership

Conditional probability differs across models

exp( )

1 (exp( ))ki ki k

ki ki k

F

F

~ (0, )k kF N F C

Factor mixtur

e model(FMM

) exp( )

1 (exp( ))i i k

i i k

F

F

~ ( , )k k kF N F CSemi-

parametric factor model

(SPFM)

Cexp( )

1 (exp( ))ki

ki

Latent class model(LCM)

C

Latent class model(LCM)

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C

C

IRPPath diagram

Latent Variable Distribution

C is ordinal

C is nominal

Semi-Parametric Factor Model

(SPFM)

IRP Path diagramLatent Variable

Distribution

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F C

F C

Measurement Invariance

Same measurement model parameters (thresholds, loadings) for each class

Quantitative differences between

classes

Factor Mixture Model(FMM)

IRP Path diagramLatent Variable

Distribution

F C

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F C

Measurement Non-Invariance

Different measurement model parameters (thresholds, loadings) for each class

Qualitative differences between classes

Example

• 9 dichotomously scored items measuring 3 aspects of psychosocial research:

1. Confidentiality

2. Generalizability

3. Informed Consent

• Sample 2,259 incoming freshmen tested in low-stakes conditions prior to start of classes

Exploratory Model Selection

• Exploratory model selection approach to answer the question, “What type and number of latent variables are most salient for our data?”

• Reasons to believe that IRPs would differ in pattern and/or elevation because students differ in:• Completion of psychosocial coursework

• Effort they put forth on test

Model Fit Indices

Model LL # paras BIC SSA-BIC LMRFM 1f -12628 18 25395 25338 NA

  2f -12576 26 25352 25270 NA  3f -12547 33 25348 25243 NA             

LCM 1c -12938 9 25946 25918 NA  2c -12649 19 25445 25384 0.00  3c -12591 29 25406 25314 0.07  4c -12538 39 25377 25253 0.01  5c -12520 49 25418 25262 0.14             

SPFM 1f2c -12618 21 25399 25332 0.01             

FMM 1f2c -12539 35 25348 25237 0.00

IRPs of 4 Class LCM

0.18 0.36 0.25 0.20

generalizability

2-class FMM

0.44

0.56

ˆ 0.27

ˆ 3.96X

Y

26. Which ethical practice is not considered by Marty?a) She failed to obtain

informed consent from her participants

b) She failed to randomly select participants

c) …d) …

Factor Variability Within Each Class

Visually Conveying Loading Information

Item Content Item Number Class X Class YConfidentiality 17 0.26 0.36

34 0.28 0.7439 0.16 0.81

Generalizability 25 0.46 -0.0327 0.49 -0.0736 0.46 0.27

Informed Consent 23 0.51 0.3026 0.88 0.3532 0.44 0.31

Standardized Loadings

ˆ 0.27

ˆ 3.96X

Y

X Y

Validity Evidence for 2-class FMM Solution

• Students with higher SAT-V scores, who reported put forth more effort on the test, and who have completed psychosocial coursework more likely to be in Class X

• Positive relationship between SAT-V, coursework completion and factor scores in that class (negative relationship with effort)

• Negative relationship between number of missing responses and factor scores in Class Y

X Y

Correspondence Between Models

A & B from

LCM, X from FMM

C & D from

LCM, Y from FMM

X & Y from FMMwith

intervals

Parting Thoughts…

• These models are like potato chips…– It was so much easier to settle on a brand of

chip when I had a limited number of brands to choose from

– But I also like having more brands because it increases my chances of finding the brand that is right for me

– With all these brands, it is possible that some are selling essentially the same chip….but which ones?

– When two brands are essentially the same chip, what criteria do I use to choose between the two brands?

[email protected]

Pastor, D. A., & Gagné, P. (2013). Mean and covariance structure mixture models. In G. R. Hancock & R. O. Mueller (Eds.), Structural Equation Modeling: A Second Course (2nd Ed.). Greenwich, CT: Information Age.

Pastor, D. A., Lau, A. R., & Setzer, J. C. (2007, August). Modeling item response profiles using factor models, latent class models, and latent variable hybrids. Poster presented at the annual meeting of the American Psychological Association, San Francisco.