In order to support the sharing of assessment process information in an interoperable, abstract, and efficient way, we developed APS as a high-level assessment-specific process modeling
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concept support-activity in LD An assessment process model based on APS can be
transformed into an executable model represented in LD and QTI Thus, we should be able to use an integrated LD and QTI run-time environment to execute various forms of assessment based on APS In addition, APS will be organized using the IMS Content Package specification It can use IEEE Learning Object Metadata (LOM) to describe the meta-data of elements in APS Moreover, the IMS Reusable Definition of Competency
or Educational Objectives can be used to specify traits and assessment objectives The IMS ePortfolio can be used to model portfolios (coupled with artifacts in APS) and inte-grate a portfolio editor The IMS Learner Information Profile can be used to import global properties from a run-time environment and export them to it IMS Enterprise can
be used for mapping roles when instantiating a UoA Therefore, APS is compatible with most existing, relevant e-learning technical specifications
5 Conclusions and Future Work
This paper addressed the problems one faces when attempting to use QTI and LD to support the management of assessment processes, in particular, formative assessment and competence assessment In order to support the sharing of assessment process information in an interoperable, abstract, and efficient way, we developed APS as a high-level assessment-specific process modeling language We have developed the conceptual model of APS by adopting a domain-specific modeling approach The conceptual model has been described through detailing the semantics aggregation model, the conceptual structure model, and the process structure model The first validation study has been conducted through investigating whether the conceptual model of APS meets the requirements of completeness, flexibility, adaptability, and compatibility The results suggest that the model does indeed do so
APS should meet additional requirements (e.g., reproducibility, formalization, and reusability), which we intend to investigate after the development of the information model and XML Schemas binding In order to enable practitioners to easily design and customize their own assessment process models, an authoring tool for modeling assessment processes with APS will be developed in the near future In order to exe-cute an instantiated model in existing LD and QTI compatible run-time environments, transformation functions have to be developed as well Then we will carry out ex-periments to investigate the feasibility and usability of APS and the corresponding authoring tool Finally, we will propose APS as a candidate, new open e-learning technical standard
Acknowledgments The work described in this paper has been fully supported by the
European Commission under the TENCompetence project [project No: IST-2004-02787]
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© Springer-Verlag Berlin Heidelberg 2008
Computer-Aided Generation of Item Banks Based on
Ontology and Bloom's Taxonomy
Ming-Hsiung Ying1 and Heng-Li Yang2
1
Department of MIS, Chung-Hua University, 707, Sec.2, WuFu Rd., HsinChu, Taiwan
2
Department of MIS, National Cheng-Chi University, 64, Sec.2,
Chihnan Rd., Taipei, Taiwan mhying@chu.edu.tw, yanh@nccu.edu.tw
Abstract Online learning and testing are important topics in information
edu-cation Students can take online tests to assess their achievement of learning goals However, the test results should assign student scores and assess their achievement of knowledge and cognition levels Teachers currently need to spend considerable time on producing and maintaining on-line testing items This study applied ontology, Chinese semantic database, artificial intelligence and Bloom's taxonomy to propose a CAGIS E-learning system architecture to assist teachers in creating test items As the result, the computer assisted teach-ers in producing a large number of test items quickly These test items covered three types of knowledge and five dimensions of cognitive skills The test items could meaningfully assess learning level meaningfully
Keywords: Online Test, Test Item Bank, Bloom’s Taxonomy, Ontology,
Se-mantic Web
1 Introduction and Related Works
Online learning and subsequent testing have been important topics in information education Because education is intended to change students behaviors, teachers must use tests well to assess student achievements Computer-based testing has numerous benefits, including data-rich test results, immediate test feedback, convenient test times and locations, and so on [1]
In designing test items, teaching goals should be considered when designing test items According to education testing theory, educational goals can be classified into three different levels: cognition field, emotional field and movement ability [2] Types
of instruction assessment can be grounded in types of knowledge Three distinct knowledge types require assessment: declarative (knowing what/knowing about), procedural (knowing how), and conditional (knowing why and when) [3] Bloom identified six levels within the cognitive domain, including knowledge, comprehen-sion, application, analysis, synthesis and evaluation [4] Anderson and Krathwohl [5] revised the original taxonomy of Bloom by combining both the cognitive process and knowledge dimensions The revised Bloom's taxonomy comprises a two-dimensional table One dimension identifies the knowledge (the kind of knowledge to be learned), while the other identifies the cognitive process (the process used to learn) The knowledge dimension comprises four levels: factual, conceptual, procedural, and
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meta-cognitive The cognitive process dimension comprises six levels: remember, understand, apply, analyze, evaluate, and create This new expanded taxonomy can help instructional designers and teachers set meaningful learning objective, and pro-vide the measurement tool for thinking
Creating and maintaining the item bank is a time-consuming When the item bank contains an insufficient number of items, the exposure frequencies of items may be too high and students may directly recall the answers [6] Therefore, how to prepare sufficient items in the bank and efficiently generate items have become important research issues [7]
Deveszic [8] proposed developing Web-based educational applications with more theory and content-oriented intelligence To increase the effectiveness of the testing system, numerous researchers have applied artificial intelligence, fuzzy theory and other techniques If information techniques can be properly applied, numerous om-plex issues can be solved, such as test item selection, item generation, scoring, expla-nation, and test feedback to enhance education and learning [9-15]
This study claims that computers can assist in aiding item generation in e-learning environments, if the material can be first stored based on knowledge ontological structure and semantic relation An intelligent online learning system has been pro-posed to resolve the above problems
2 Proposed System Architecture
To propose a system architecture for computer-aided tem bank generation, this study followed the following steps: (1) Conducting a pilot study to explore the difficulty faced by teachers in manually creating items, and analyzing the item types; (2) De-veloping course material knowledge and item structure ontologies, involving concept
of Bloom’s taxonomy; (3) Creating a knowledge base related to online course materi-als; (4) Developing a prototype for computer-aided generation of item system (CAGIS)
2.1 A Pilot Study Exploring the Difficulty of Manual Item Creation
Fifteen university teachers from 11 different universities - who had taught "manage-ment information system" courses, participated in the pilot study These teachers were given two weeks to create test items from specific chapters of a textbook It was re-quired that the test items should include four types: true-false, multiple-choice, multi-ple-response, and fill-in-the-blank No upper limited constrained the quantity of test items Finally, the teachers produced 440 items manually, with the average time taken
to complete the task being 4.3 hours After deleting the duplicate items, there are 386 items left and shown in Table 1 The knowledge types of those items included “fac-tual, concep“fac-tual, procedural” knowledge, and their cognitive levels included: “re-member, understand, analyze, and evaluate” The specific chapters are no suitable knowledge content to generate the item of "apply" level Some teachers indicated that
it would be very difficult to generate the "create" level items using true-false, multi-ple-choice, multiple-response, and fill-in-the-blank question type