about
Online assessment of patients' views on hospital performances using Rasch model's KIDMAP diagramKIDMAP, a web based system for gathering patients' feedback on their doctors.Reliability of 95% confidence interval revealed by expected quality-of-life scores: an example of nasopharyngeal carcinoma patients after radiotherapy using EORTC QLQ-C 30.Intraclass reliability for assessing how well Taiwan constrained hospital-provided medical services using statistical process control chart techniques.The validity of the Type D construct and its assessment in TaiwanA web-based computerized adaptive testing (CAT) to assess patient perception in hospitalization.Quality of life in overweight and obese young Chinese children: a mixed-method study.Reduction in patient burdens with graphical computerized adaptive testing on the ADL scale: tool development and simulationModified Logistic Regression Approaches to Eliminating the Impact of Response Styles on DIF Detection in Likert-Type Scales.Non-ignorable missingness item response theory models for choice effects in examinee-selected items.Assessment of Differential Rater Functioning in Latent Classes with New Mixture Facets Models.Rasch analysis of positive changes following adversity in cancer patients attending community support groups.A Multidimensional and Multilevel Extension of a Random-Effect Approach to Subjective Judgment in Rating Scales.Assessment of differential item functioning.Chinese parental perceptions of weight and associated health risks of young children.Hostility trait and vascular dilatory functions in healthy Taiwanese.Rasch analysis of combining two indices to assess comprehensive ADL function in stroke patients.A Rasch analysis of a self-perceived change in quality of life scale in patients with mild stroke.Item Response Theory Models for Carry-Over Effect Across Different Scales.Unfolding IRT Models for Likert-Type Items With a Don't Know Option.Item Response Theory Models for Wording Effects in Mixed-Format Scales.Modeling Randomness in Judging Rating Scales with a Random-Effects Rating Scale ModelAssessment of Differential Item Functioning in Testlet-Based Items Using the Rasch Testlet ModelLocal Item Dependence for Items Across Tests Connected by Common StimuliThe Rasch Testlet ModelUsing SAS PROC NLMIXED to fit item response theory models.Improving measurement precision of test batteries using multidimensional item response modelsComputing confidence intervals of item fit statistics in the family of Rasch models using the bootstrap methodItem Response Theory Models for Ipsative Tests With Multidimensional Pairwise Comparison ItemsA General Unfolding IRT Model for Multiple Response StylesUsing Odds Ratios to Detect Differential Item FunctioningMultilevel Modeling of Cognitive Diagnostic Assessment: The Multilevel DINA ExampleItem Response Theory Modeling for Examinee-selected Items with Rater EffectMultidimensional Computerized Adaptive Testing Using Non-Compensatory Item Response Theory Models
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Q21254578-281B78B3-38B5-4019-AD6D-E391B06012FEQ33469942-8C17BF69-C1DD-40C7-AEEE-675DA332D7B9Q34031119-FF3772C5-A07B-4D4F-B017-B88C428AABEDQ34269698-9EEB1A16-1A84-4F27-AB88-C9C536EE2ACAQ34573930-AEB098EC-F5F2-4B05-AE2C-39447E9C4A67Q35567653-6FE500A1-717C-4A78-9AA2-134D5A14EB39Q36707754-9E2DA438-73D5-49D7-ADF8-6135643DE999Q37207652-239F08EA-4C7F-4393-B2B9-DB061C2739A2Q38665589-DD650B3A-2B06-459C-A55C-49CEF10387DCQ38846843-4F1FE0AD-A78B-4230-96E3-726C5D8E9DF9Q38887157-6A3D9A0C-43C8-484B-BA6F-BF7A46C53AA5Q39895646-690F0C42-0402-4B7B-B25A-402C3822B27AQ40132750-5B41FD4E-ACC1-4FD6-B175-EEC58A6FFF59Q43915177-4AA39AB1-6AC4-41D1-BA0F-217B7571A440Q45787800-9366F441-A9C9-4E94-91FF-EEAAE60A5FCBQ50774709-1A72A0BD-8E0F-4D29-BE6A-F27951D464BBQ52003456-C7FD9838-FB7F-4B63-967B-DBB2353B823BQ53267822-CA6F2F27-0CC8-40AA-95E4-CFF8D50099C2Q55096011-FA8A1496-6128-49D1-84D8-6DD1A805145CQ55112674-F2A14C63-FBF6-4BAC-AD5A-8F5D26D8F4D3Q55279845-9808B560-9DFA-4979-8EEA-03FBC964BDC5Q58297912-E3EC663B-1A03-4DB2-B9EE-F7ECFF19A4CDQ58297918-73C9A367-A4CA-4F6D-BA95-31B1957B7AE3Q58297923-4AE414D3-0948-46D9-BFF0-27CDAF1A5D11Q58297930-DB2CCDE5-52C2-4063-A5C1-AE525DB64985Q64904848-64D8FB24-4474-4B18-9330-BAA0AB181991Q79844405-B1D9CCE1-F780-4C5E-A525-31C1DE908E6EQ80172056-02E7AED9-5612-40D6-9A70-8F6A420E26A8Q89032674-E0EFFAB1-7877-4D79-B581-0E7E50224502Q90284886-1EB6EFC4-6B9D-4DF0-A551-ABE7535B6924Q90597800-A31CFF3B-0703-448C-8ABC-720E823434D9Q90682633-29088397-5F85-4D78-8448-468B30809FB9Q92888668-17877351-DE50-4D84-A9D6-4F7ADC05D438Q92888679-B4AD308E-3A58-4D00-98A5-53B87332030C
P50
description
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wetenschapper
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հետազոտող
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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Wen-Chung Wang
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P106
P1153
7501757876
P31
P496
0000-0001-6022-1567