thetaEst: Ability estimation (dichotomous and polytomous models)
In mstR: Procedures to Generate Patterns under Multistage Testing
Description
Usage
Arguments
Details
Value
Note
Author(s)
References
See Also
Examples
Description
This command returns the ability estimate for a given response pattern and a given matrix of item parameters, either under the 4PL model or any suitable polytomous IRT model. Available estimators are maximum likelihood, Bayes modal (MAP), expected a posteriori (EAP) and weighted likelihood.
Usage
1
2
3
4
Arguments
it
numeric: a suitable matrix of item parameters. See Details.
x
numeric: a vector of item responses.
model
either NULL (default) for dichotomous models, or any suitable acronym for polytomous models. Possible values are "GRM", "MGRM", "PCM", "GPCM", "RSM" and "NRM". See Details.
D
numeric: the metric constant. Default is D=1 (for logistic metric); D=1.702 yields approximately the normal metric (Haley, 1952). Ignored if model is not NULL.
method
character: the ability estimator. Possible values are "BM" (default), "ML", "WL" and "EAP". See Details.
priorDist
character: specifies the prior distribution. Possible values are "norm" (default), "unif" and "Jeffreys". Ignored if method is neither "BM" nor "EAP". See Details.
priorPar
numeric: vector of two components specifying the prior parameters (default is c(0,1)) of the prior ability distribution. Ignored if method is neither "BM" nor "EAP", or if priorDist="Jeffreys". See Details.
range
numeric: vector of two components specifying the range wherein the ability estimate must be looked for (default is c(-4,4)). Ignored if method=="EAP".
parInt
numeric: vector of three components, holding respectively the values of the arguments lower, upper and nqp of the eapEst command. Default vector is (-4, 4, 33). Ignored if method is not "EAP".
constantPatt
character: the method to estimate ability in case of constant pattern (i.e. only correct or only incorrect responses). Can be either NULL (default), "BM", "EAP", "WL", "fixed4", "fixed7" or "var". Currently only implemented for dichotomous IRT models. See Details.
current.th
numeric: the current ability estimate (default is zero). Required for ability estimation in presence of constant pattern. Ignored if constantPatt is neither "fixed4", "fixed7" nor "var". See Details.
bRange
numeric: vector of two componentns with the range of difficulty parameters in the parent item bank (default is c(-2,2)). Currently only implemented for dichotomous IRT models. See Details.
Details
Dichotomous IRT models are considered whenever model is set to NULL (default value). In this case, it must be a matrix with one row per item and four columns, with the values of the discrimination, the difficulty, the pseudo-guessing and the inattention parameters (in this order). These are the parameters of the four-parameter logistic (4PL) model
(Barton and Lord, 1981).
Polytomous IRT models are specified by their respective acronym: "GRM" for Graded Response Model, "MGRM" for Modified Graded Response Model, "PCM" for Partical Credit Model, "GPCM" for Generalized Partial Credit Model, "RSM" for Rating Scale Model and "NRM" for Nominal Response Model. The it still holds one row per item, end the number of columns and their content depends on the model. See genPolyMatrix for further information and illustrative examples of suitable polytomous item banks.
Four ability estimators are available: the maximum likelihood (ML) estimator (Lord, 1980), the Bayes modal (BM) estimator (Birnbaum, 1969), the expected a posteriori (EAP) estimator (Bock and Mislevy, 1982) and the weighted likelihood (WL) estimator (Warm, 1989). The selected estimator is specified by the method argument, with values "ML", "BM", "EAP" and "WL" respectively.
For the BM and EAP estimators, three prior distributions are available: the normal distribution, the uniform distribution and Jeffreys' prior distribution (Jeffreys, 1939, 1946). The prior distribution is specified by the argument priorPar, with values "norm", "unif" and "Jeffreys", respectively. The priorPar argument is ignored if method="ML" or method="WL".
The argument priorPar determines either the prior mean and standard deviation of the normal prior distribution (if
priorDist="norm"), or the range for defining the prior uniform distribution (if priorDist="unif"). This argument
is ignored if priorDist="Jeffreys".
The parInt argument sets the range and the number of quadrature points for numerical integration in the EAP process. By default, it takes the vector value (-4, 4, 33), that is, 33 quadrature points on the range [-4; 4] (or, by steps of 0.25). See eapEst for further details.
The range argument permits to limit the interval of investigation for the ML, BM and WL ability estimates (in particular, to avoid infinite ability estimates). The default range is [-4, 4].
Specific ability estimation methods are available in presence of constant patterns (that is with only correct or only incorrect responses) under dichotomous IRT models. These methods are specified by the argument constantPatt. By default it is set to NULL and hence ability is estimated with the specified method (even in presence of constant pattern). Six methods are currently available for constant patterns: "BM", "EAP" and "WL" that call for Bayes modal, expected a posteriori and weighted likelihood estimation respectively; "fixed4" and "fixed7" that perform fixed stepsize adjustment (i.e. increase or decrease of constant magnitude) with step 0.4 and 0.7 respectively; and "var" for variable stepsize adjustment. Note that in case odf stepsize adjustment, the range of difficultyu parameters must be provided through the bRange argument, as vector of two components (default value being c(-2,2)). See Dodd, De Ayala, and Koch (1995) for further details.
Value
The estimated ability level.
Note
It has been shown that in some cases the weighted likelihood estimator and the Bayes modal estimator with Jeffreys prior return exactly the same ability estimates. This is the case under the 2PL model, and subsequently the 1PL model (Warm, 1989) as well as under all polytomous models currently available (Magis, 2015). Nevertheless, both estimators remain available since (a) Jeffreys prior can also be considered with the EAP estimator, and (b) the 3PL and 4PL models are also available.
Author(s)
David Magis
Department of Psychology, University of Liege, Belgium
david.magis@uliege.be
References
Barton, M.A., and Lord, F.M. (1981). An upper asymptote for the three-parameter logistic item-response model. Research Bulletin 81-20. Princeton, NJ: Educational Testing Service.
Birnbaum, A. (1969). Statistical theory for logistic mental test models with a prior distribution of ability. Journal of Mathematical Psychology, 6, 258-276. doi: 10.1016/0022-2496(69)90005-4
Bock, R. D., and Mislevy, R. J. (1982). Adaptive EAP estimation of ability in a microcomputer environment. Applied Psychological Measurement, 6, 431-444. doi: 10.1177/014662168200600405
Dodd, B. G., De Ayala, R. J., and Koch, W. R. (1995) . Computerized adaptive testing with polytomous items. Applied Psychological Measurement, 19, 5-22. doi: 10.1177/014662169501900103
Haley, D.C. (1952). Estimation of the dosage mortality relationship when the dose is subject to error.
Technical report no 15. Palo Alto, CA: Applied Mathematics and Statistics Laboratory, Stanford University.
Jeffreys, H. (1939). Theory of probability. Oxford, UK: Oxford University Press.
Jeffreys, H. (1946). An invariant form for the prior probability in estimation problems. Proceedings of the Royal
Society of London. Series A, Mathematical and Physical Sciences, 186, 453-461.
Lord, F.M. (1980). Applications of item response theory to practical testing problems. Hillsdale, NJ: Lawrence Erlbaum.
Magis, D. (2015). A note on weighted likelihood and Jeffreys modal estimation of proficiency levels in polytomous item response models. Psychometrika, 80, 200-204. doi: 10.1007/S11336-013-9378-5
Magis, D., and Raiche, G. (2012). Random Generation of Response Patterns under Computerized Adaptive Testing with the R
Package catR. Journal of Statistical Software, 48 (8), 1-31. URL http://www.jstatsoft.org/v48/i08/
Warm, T.A. (1989). Weighted likelihood estimation of ability in item response models. Psychometrika, 54, 427-450. doi: 10.1007/BF02294627
See Also
eapEst, semTheta, genPolyMatrix
Examples
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
## Dichotomous models ##
# Generation of an item bank under 3PL with 100 items
m.3PL <- genDichoMatrix(100, model = "3PL")
m.3PL <- as.matrix(m.3PL)
# Creation of a response pattern (true ability level 0)
set.seed(1)
x <- genPattern(0, m.3PL)
# ML estimation
thetaEst(m.3PL, x, method = "ML")
# BM estimation, standard normal prior distribution
thetaEst(m.3PL, x)
# BM estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.3PL, x, method = "BM", priorDist = "unif", priorPar = c(-2, 2))
# BM estimation, Jeffreys' prior distribution
thetaEst(m.3PL, x, method = "BM", priorDist = "Jeffreys")
# EAP estimation, standard normal prior distribution
thetaEst(m.3PL, x, method = "EAP")
# EAP estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.3PL, x, method = "EAP", priorDist = "unif", priorPar = c(-2, 2))
# EAP estimation, Jeffreys' prior distribution
thetaEst(m.3PL, x, method = "EAP", priorDist = "Jeffreys")
# WL estimation
thetaEst(m.3PL, x, method = "WL")
# Creation of two constant patterns and estimation with WL,
# 'fixed4', 'fixed7' and 'var' stepsize adjustments
x0 <- rep(0,nrow(m.3PL))
x1 <- x0 + 1
thetaEst(m.3PL, x0, constantPatt = "WL") # equivalent to thetaEst(m.3PL, x0, method = "WL")
thetaEst(m.3PL, x1, constantPatt = "WL") # equivalent to thetaEst(m.3PL, x1, method = "WL")
thetaEst(m.3PL, x0, constantPatt = "fixed4")
thetaEst(m.3PL, x1, constantPatt = "fixed4")
thetaEst(m.3PL, x0, constantPatt = "fixed7")
thetaEst(m.3PL, x1, constantPatt = "fixed7")
thetaEst(m.3PL, x0, constantPatt = "var")
thetaEst(m.3PL, x1, constantPatt = "var")
## Not run:
## Polytomous models ##
# Generation of an item bank under GRM with 100 items and at most 4 categories
m.GRM <- genPolyMatrix(100, 4, "GRM")
m.GRM <- as.matrix(m.GRM)
# Creation of a response pattern (true ability level 0)
set.seed(1)
x <- genPattern(0, m.GRM, model = "GRM")
# ML estimation
thetaEst(m.GRM, x, model = "GRM", method = "ML")
# BM estimation, standard normal prior distribution
thetaEst(m.GRM, x, model = "GRM")
# BM estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.GRM, x, model = "GRM", method = "BM", priorDist = "unif",
priorPar = c(-2, 2))
# BM estimation, Jeffreys' prior distribution
thetaEst(m.GRM, x, model = "GRM", method = "BM", priorDist = "Jeffreys")
# EAP estimation, standard normal prior distribution
thetaEst(m.GRM, x, model = "GRM", method = "EAP")
# EAP estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.GRM, x, model = "GRM", method = "EAP", priorDist = "unif",
priorPar = c(-2, 2))
# EAP estimation, Jeffreys' prior distribution
thetaEst(m.GRM, x, model = "GRM", method = "EAP", priorDist = "Jeffreys")
# WL estimation
thetaEst(m.GRM, x, model = "GRM", method = "WL")
# Generation of an item bank under PCM with 20 items and 4 categories
m.PCM <- genPolyMatrix(20, 4, "PCM", same.nrCat = TRUE)
m.PCM <- as.matrix(m.PCM)
# Creation of a response pattern (true ability level 0)
set.seed(1)
x <- genPattern(0, m.PCM, model = "PCM")
# ML estimation
thetaEst(m.PCM, x, model = "PCM", method = "ML")
# BM estimation, standard normal prior distribution
thetaEst(m.PCM, x, model = "PCM")
# BM estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.PCM, x, model = "PCM", method = "BM", priorDist = "unif",
priorPar = c(-2, 2))
# BM estimation, Jeffreys' prior distribution
thetaEst(m.PCM, x, model = "PCM", method = "BM", priorDist = "Jeffreys")
# EAP estimation, standard normal prior distribution
thetaEst(m.PCM, x, model = "PCM", method = "EAP")
# EAP estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.PCM, x, model = "PCM", method = "EAP", priorDist = "unif",
priorPar = c(-2, 2))
# EAP estimation, Jeffreys' prior distribution
thetaEst(m.PCM, x, model = "PCM", method = "EAP", priorDist = "Jeffreys")
# WL estimation
thetaEst(m.PCM, x, model = "PCM", method = "WL")
## End(Not run)
mstR documentation built on May 2, 2019, 8:28 a.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Description Usage Arguments Details Value Note Author(s) References See Also Examples
Description
This command returns the ability estimate for a given response pattern and a given matrix of item parameters, either under the 4PL model or any suitable polytomous IRT model. Available estimators are maximum likelihood, Bayes modal (MAP), expected a posteriori (EAP) and weighted likelihood.
Usage
1 2 3 4 |
Arguments
it |
numeric: a suitable matrix of item parameters. See Details. |
x |
numeric: a vector of item responses. |
model |
either |
D |
numeric: the metric constant. Default is |
method |
character: the ability estimator. Possible values are |
priorDist |
character: specifies the prior distribution. Possible values are |
priorPar |
numeric: vector of two components specifying the prior parameters (default is |
range |
numeric: vector of two components specifying the range wherein the ability estimate must be looked for (default is |
parInt |
numeric: vector of three components, holding respectively the values of the arguments |
constantPatt |
character: the method to estimate ability in case of constant pattern (i.e. only correct or only incorrect responses). Can be either |
current.th |
numeric: the current ability estimate (default is zero). Required for ability estimation in presence of constant pattern. Ignored if |
bRange |
numeric: vector of two componentns with the range of difficulty parameters in the parent item bank (default is |
Details
Dichotomous IRT models are considered whenever model is set to NULL (default value). In this case, it must be a matrix with one row per item and four columns, with the values of the discrimination, the difficulty, the pseudo-guessing and the inattention parameters (in this order). These are the parameters of the four-parameter logistic (4PL) model
(Barton and Lord, 1981).
Polytomous IRT models are specified by their respective acronym: "GRM" for Graded Response Model, "MGRM" for Modified Graded Response Model, "PCM" for Partical Credit Model, "GPCM" for Generalized Partial Credit Model, "RSM" for Rating Scale Model and "NRM" for Nominal Response Model. The it still holds one row per item, end the number of columns and their content depends on the model. See genPolyMatrix for further information and illustrative examples of suitable polytomous item banks.
Four ability estimators are available: the maximum likelihood (ML) estimator (Lord, 1980), the Bayes modal (BM) estimator (Birnbaum, 1969), the expected a posteriori (EAP) estimator (Bock and Mislevy, 1982) and the weighted likelihood (WL) estimator (Warm, 1989). The selected estimator is specified by the method argument, with values "ML", "BM", "EAP" and "WL" respectively.
For the BM and EAP estimators, three prior distributions are available: the normal distribution, the uniform distribution and Jeffreys' prior distribution (Jeffreys, 1939, 1946). The prior distribution is specified by the argument priorPar, with values "norm", "unif" and "Jeffreys", respectively. The priorPar argument is ignored if method="ML" or method="WL".
The argument priorPar determines either the prior mean and standard deviation of the normal prior distribution (if
priorDist="norm"), or the range for defining the prior uniform distribution (if priorDist="unif"). This argument
is ignored if priorDist="Jeffreys".
The parInt argument sets the range and the number of quadrature points for numerical integration in the EAP process. By default, it takes the vector value (-4, 4, 33), that is, 33 quadrature points on the range [-4; 4] (or, by steps of 0.25). See eapEst for further details.
The range argument permits to limit the interval of investigation for the ML, BM and WL ability estimates (in particular, to avoid infinite ability estimates). The default range is [-4, 4].
Specific ability estimation methods are available in presence of constant patterns (that is with only correct or only incorrect responses) under dichotomous IRT models. These methods are specified by the argument constantPatt. By default it is set to NULL and hence ability is estimated with the specified method (even in presence of constant pattern). Six methods are currently available for constant patterns: "BM", "EAP" and "WL" that call for Bayes modal, expected a posteriori and weighted likelihood estimation respectively; "fixed4" and "fixed7" that perform fixed stepsize adjustment (i.e. increase or decrease of constant magnitude) with step 0.4 and 0.7 respectively; and "var" for variable stepsize adjustment. Note that in case odf stepsize adjustment, the range of difficultyu parameters must be provided through the bRange argument, as vector of two components (default value being c(-2,2)). See Dodd, De Ayala, and Koch (1995) for further details.
Value
The estimated ability level.
Note
It has been shown that in some cases the weighted likelihood estimator and the Bayes modal estimator with Jeffreys prior return exactly the same ability estimates. This is the case under the 2PL model, and subsequently the 1PL model (Warm, 1989) as well as under all polytomous models currently available (Magis, 2015). Nevertheless, both estimators remain available since (a) Jeffreys prior can also be considered with the EAP estimator, and (b) the 3PL and 4PL models are also available.
Author(s)
David Magis
Department of Psychology, University of Liege, Belgium
david.magis@uliege.be
References
Barton, M.A., and Lord, F.M. (1981). An upper asymptote for the three-parameter logistic item-response model. Research Bulletin 81-20. Princeton, NJ: Educational Testing Service.
Birnbaum, A. (1969). Statistical theory for logistic mental test models with a prior distribution of ability. Journal of Mathematical Psychology, 6, 258-276. doi: 10.1016/0022-2496(69)90005-4
Bock, R. D., and Mislevy, R. J. (1982). Adaptive EAP estimation of ability in a microcomputer environment. Applied Psychological Measurement, 6, 431-444. doi: 10.1177/014662168200600405
Dodd, B. G., De Ayala, R. J., and Koch, W. R. (1995) . Computerized adaptive testing with polytomous items. Applied Psychological Measurement, 19, 5-22. doi: 10.1177/014662169501900103
Haley, D.C. (1952). Estimation of the dosage mortality relationship when the dose is subject to error. Technical report no 15. Palo Alto, CA: Applied Mathematics and Statistics Laboratory, Stanford University.
Jeffreys, H. (1939). Theory of probability. Oxford, UK: Oxford University Press.
Jeffreys, H. (1946). An invariant form for the prior probability in estimation problems. Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences, 186, 453-461.
Lord, F.M. (1980). Applications of item response theory to practical testing problems. Hillsdale, NJ: Lawrence Erlbaum.
Magis, D. (2015). A note on weighted likelihood and Jeffreys modal estimation of proficiency levels in polytomous item response models. Psychometrika, 80, 200-204. doi: 10.1007/S11336-013-9378-5
Magis, D., and Raiche, G. (2012). Random Generation of Response Patterns under Computerized Adaptive Testing with the R Package catR. Journal of Statistical Software, 48 (8), 1-31. URL http://www.jstatsoft.org/v48/i08/
Warm, T.A. (1989). Weighted likelihood estimation of ability in item response models. Psychometrika, 54, 427-450. doi: 10.1007/BF02294627
See Also
eapEst, semTheta, genPolyMatrix
Examples
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 | ## Dichotomous models ##
# Generation of an item bank under 3PL with 100 items
m.3PL <- genDichoMatrix(100, model = "3PL")
m.3PL <- as.matrix(m.3PL)
# Creation of a response pattern (true ability level 0)
set.seed(1)
x <- genPattern(0, m.3PL)
# ML estimation
thetaEst(m.3PL, x, method = "ML")
# BM estimation, standard normal prior distribution
thetaEst(m.3PL, x)
# BM estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.3PL, x, method = "BM", priorDist = "unif", priorPar = c(-2, 2))
# BM estimation, Jeffreys' prior distribution
thetaEst(m.3PL, x, method = "BM", priorDist = "Jeffreys")
# EAP estimation, standard normal prior distribution
thetaEst(m.3PL, x, method = "EAP")
# EAP estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.3PL, x, method = "EAP", priorDist = "unif", priorPar = c(-2, 2))
# EAP estimation, Jeffreys' prior distribution
thetaEst(m.3PL, x, method = "EAP", priorDist = "Jeffreys")
# WL estimation
thetaEst(m.3PL, x, method = "WL")
# Creation of two constant patterns and estimation with WL,
# 'fixed4', 'fixed7' and 'var' stepsize adjustments
x0 <- rep(0,nrow(m.3PL))
x1 <- x0 + 1
thetaEst(m.3PL, x0, constantPatt = "WL") # equivalent to thetaEst(m.3PL, x0, method = "WL")
thetaEst(m.3PL, x1, constantPatt = "WL") # equivalent to thetaEst(m.3PL, x1, method = "WL")
thetaEst(m.3PL, x0, constantPatt = "fixed4")
thetaEst(m.3PL, x1, constantPatt = "fixed4")
thetaEst(m.3PL, x0, constantPatt = "fixed7")
thetaEst(m.3PL, x1, constantPatt = "fixed7")
thetaEst(m.3PL, x0, constantPatt = "var")
thetaEst(m.3PL, x1, constantPatt = "var")
## Not run:
## Polytomous models ##
# Generation of an item bank under GRM with 100 items and at most 4 categories
m.GRM <- genPolyMatrix(100, 4, "GRM")
m.GRM <- as.matrix(m.GRM)
# Creation of a response pattern (true ability level 0)
set.seed(1)
x <- genPattern(0, m.GRM, model = "GRM")
# ML estimation
thetaEst(m.GRM, x, model = "GRM", method = "ML")
# BM estimation, standard normal prior distribution
thetaEst(m.GRM, x, model = "GRM")
# BM estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.GRM, x, model = "GRM", method = "BM", priorDist = "unif",
priorPar = c(-2, 2))
# BM estimation, Jeffreys' prior distribution
thetaEst(m.GRM, x, model = "GRM", method = "BM", priorDist = "Jeffreys")
# EAP estimation, standard normal prior distribution
thetaEst(m.GRM, x, model = "GRM", method = "EAP")
# EAP estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.GRM, x, model = "GRM", method = "EAP", priorDist = "unif",
priorPar = c(-2, 2))
# EAP estimation, Jeffreys' prior distribution
thetaEst(m.GRM, x, model = "GRM", method = "EAP", priorDist = "Jeffreys")
# WL estimation
thetaEst(m.GRM, x, model = "GRM", method = "WL")
# Generation of an item bank under PCM with 20 items and 4 categories
m.PCM <- genPolyMatrix(20, 4, "PCM", same.nrCat = TRUE)
m.PCM <- as.matrix(m.PCM)
# Creation of a response pattern (true ability level 0)
set.seed(1)
x <- genPattern(0, m.PCM, model = "PCM")
# ML estimation
thetaEst(m.PCM, x, model = "PCM", method = "ML")
# BM estimation, standard normal prior distribution
thetaEst(m.PCM, x, model = "PCM")
# BM estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.PCM, x, model = "PCM", method = "BM", priorDist = "unif",
priorPar = c(-2, 2))
# BM estimation, Jeffreys' prior distribution
thetaEst(m.PCM, x, model = "PCM", method = "BM", priorDist = "Jeffreys")
# EAP estimation, standard normal prior distribution
thetaEst(m.PCM, x, model = "PCM", method = "EAP")
# EAP estimation, uniform prior distribution upon range [-2,2]
thetaEst(m.PCM, x, model = "PCM", method = "EAP", priorDist = "unif",
priorPar = c(-2, 2))
# EAP estimation, Jeffreys' prior distribution
thetaEst(m.PCM, x, model = "PCM", method = "EAP", priorDist = "Jeffreys")
# WL estimation
thetaEst(m.PCM, x, model = "PCM", method = "WL")
## End(Not run)
|
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.