Spelling suggestions: "subject:"bigher order thinking skills"" "subject:"2higher order thinking skills""
1 |
The Impact of Non-Academic Involvement on Higher Order Thinking SkillsFranklin, Megan Armbruster 04 April 2014 (has links)
External and internal stakeholders in higher education are asking for accountability about what takes place in the classroom (Alexander, Clinton, and Kean, 1986; Hart Research Associates, 2010; Spellings, 2006). They want to be assured that the learning institutions claim is occurring on campus is in fact happening (Alexander, 2000). In response, academic leaders have produced information about active learning strategies in classrooms (Seifert, Pascarella, Wolniak, and Cruce, 2006; Tsui, 2002; Umbach and Wawrzynski, 2005), student approaches to learning (Biggs, Kember, and Leung, 2001), and faculty-student interaction that lead to increased use of higher order thinking skills (Kuh, 1995; Pascarella and Terenzini, 1991; Reason, Terenzini and Domingo, 2007).
Although there is extensive literature on learning that occurs in academic settings on college campuses, data on whether students are engaging in higher order thinking skills in non-academic settings are less prevalent. This study sought to understand whether students' higher order thinking skills (HOTs) are influenced by their involvement in non-academic activities (NAIs).
I analyzed data from college seniors who completed the 2010 National Survey of Student Engagement (NSSE) to address two questions. First, I explored what factors emerged from the items about non-academic involvement (NAI) on the NSSE. Second, multiple regression models were employed to determine the extent to which variance in HOTs could be explained by these NAI factors.
There were 14 items on the 2010 NSSE that, based on literature, measured frequency with which students engaged in NAIs. Exploratory factor analysis revealed two independent factors consisting of 7 items: Relationships (3 items) and Diverse Perspectives (4 items). These two factors explained 21% of variance in students' higher order thinking skills. Students who are exposed to diversity and develop close relationships use HOT skills more frequently. This suggests implications for those who work in admissions, student affairs, and human resources, among others. The findings also inform policies related to promotion and tenure as well as student involvement. / Ph. D.
|
2 |
Getting the HOTS with what's in the box: Developing higher order thinking skills within a technology-rich learning environmentMcMahon, Graham January 2007 (has links)
Educators are divided with regards to the value of computer technology as a learning tool. Some maintain that computers have had little impact on students’ learning; others suggest that computers have the potential to enhance learning. Within this second group there are those who believe that computers are having a significant impact, while others believe that their potential is yet to be realised. The purpose of this study was to examine the relationship between students working in a technology rich environment and their development of higher order, critical and creative, thinking skills. Staff and students from one school participated in this case study. Data were collected by teachers as part of the normal teaching-learning program, supplemented by classroom observations and teacher interviews. In addition, data pertaining to the technology infrastructure was collated from school databases. The data were used to determine the degree of correlation between factors of the learning environment and the extent to which higher order thinking skills (HOTS) were demonstrated by the students. Collations of the statistically significant, and statistically insignificant, correlations allowed relationships between environmental factors and HOTS to be established. / The results indicate that studying within a technology-rich learning environment improves students’ higher order thinking skills, determined by measuring their critical and creative thinking. Factors such as length of time spent in the environment have a positive, non-linear effect on the development of critical thinking skills. These factors have no significant correlation with the development of creative thinking skills. The interaction of students’ computer skills and the classroom environmental factors was shown to be complex. Three-dimensional correlations were performed to derive equations that explain these interactions. Students with better developed computing skills scored higher on critical and creative thinking activities. This was most significant for students with better computer programming skills and the ability to competently manipulate Boolean logic. The most significant factors in developing higher order thinking skills were the students’ levels of computer skills, tempered with their attitudes towards computers and computer classes, and the teacher-student relationships within the technology-rich learning environment. The research suggests that in order to develop students' higher order thinking skills schools should endeavour to integrate technology across all of the learning areas. This will allow students to apply technology to the attainment of higher levels of cognition within specific contexts. This will need to be paralleled by providing students the opportunity to develop appropriate computer skills.
|
3 |
The Inclusion of Bloom's Taxonomy in State Learning Standards: A Content AnalysisLove, Beverly Joyce 01 January 2009 (has links)
The presence in state standards of the Taxonomy of Educational Objectives: Cognitive Domain (referred to Bloom 1 in this study) and A Taxonomy of Learning, Teaching, and Assessing (referred to as Bloom 2 in this study) was examined in this qualitative investigation. Standards for the English language arts eighth grade curriculum were chosen for examination in order to maximize the opportunity for all Bloom levels to appear; all states have language arts standards and eighth grade is the highest grade level at which NCLB testing is mandated. The standards documents of the 36 stated that have language arts standards unique to eighth grade comprised the analyzed data source and were accessed from state education websites. Descriptive narrations of cognitive levels, benchmarks, indicators, strands, sub-strands, writers of the standards, and any and all references to Bloom 1 and Bloom 2 were investigated. Inter-coder reliability was calculated to address the major research question regarding the clarity of reference to cognitive level of the standards. The qualitative content analysis research methodology chosen to answer the study's research questions culminated in the emergence of four major themes. 1) The extent to which the state standards were classifiable according to Bloom 1 or Bloom 2 depended largely upon consonance in assumptions made by the coders regarding a presumed conditions component for the standards; state standards lack condition components specifying what learners are presented with or have access to at the time the competency stated in the standard is demonstrated. 2) Eighth grade English language arts state standards incorporate cognitive learning levels of Bloom 1 and/or Bloom 2 through the range of Bloom levels. The verb "use" was noted as the most frequent taxonomic verb appearing in the standards. 3) Only five states directly referenced Bloom 1 or Bloom 2 in the documents' introduction/overview, table of contents, document guides, acknowledgements, appendices, and/or bibliography. 4) Of the 2,566 standard statements examined, 96 percent appear to be above the lowest Bloom 1 (Knowledge) and Bloom 2 (Remember) level, employing the researcher's assumed condition component. Overall, results showed that while some states incorporate Bloom 1 and/or Bloom 2, a majority of the standards appear to be written in the lower levels of the Bloom taxonomies. The researcher suggested strategies such as collaboration, consulting, training, and surveying students, parents, teachers, administrators, state committees, and agencies on knowledge of and inclusion of the Bloom taxonomic frameworks in order to improve the clarity of the intended cognitive levels set by the state standards.
|
4 |
A Phenomenological Study of Secondary Teachers' Experiences with Assessing Higher Order Thinking SkillsMiser, Rachael Spiker 20 December 2017 (has links)
No description available.
|
5 |
The Use of Face-to-Face and Out-of-Classroom Technology in Higher EducationHollowell, Meghan Yancy 01 November 2010 (has links)
No description available.
|
6 |
Secondary English Teachers' Experiences on Critical Thinking for African American Male StudentsMurphy Fulford, Wanda 01 January 2018 (has links)
African American male students (AAMSs) can benefit from literacy instruction that is student-based and geared towards using higher-level thinking skills. The conceptual framework was guided by Dewey's constructivism theory, the purpose of this qualitative case study was to explore whether high school English language arts (ELA) teachers in an urban-suburban Midwest region of the United States have sufficient knowledge and skills to incorporate higher order thinking skills (HOT) instruction for AAMSs. Five ELA teachers from a low-performing, urban-suburban high school in the Midwest region of the United States participated in semistructured interviews; observations were conducted in the classroom, and lesson plans were reviewed. Patterns, categories, and themes emerged through using the coding process by breaking down the data into units and then grouped according to their characteristics. According to the findings, participants from this study suggested that problem- solving was the main higher level thinking skill for AAMSs. These local ELA teachers also used the Socratic questioning method as their primary instructional strategy but limited constructivist activities for AAMSs to engage during the instructional process. The findings from the data collection support the development of a professional training program. The professional development program could help teachers engage AAMSs in increasing their academic endeavors. ELA teachers can participate in professional learning communities by communicating concerns about AAMSs, using HOT skills to increase AAMSs literacy performance, become change agents, and promote a positive social change by using constructivist practices into school curriculum and instructions for AAMSs, eventually closing the achievement gap.
|
7 |
Higher order thinking skills in a science classroom computer simulationNesbitt-Hawes, Philip John January 2005 (has links)
Education is rapidly moving away from the instructional models of the 19th century and educationalists are now asserting that not only do students need to be able to learn by rote but also to be able to think in a more profound and complex manner. Students are required to develop new processes to handle the rapidly changing world that they are expected to take part in as they complete their formal learning. This change is evident in all the developed nations and Australian students are finding that they are being asked to demonstrate a range of higher order thinking skills in all their school subjects. Science courses in Queensland require students to be assessed on both complex reasoning and scientific process skills. Studies have shown that students can develop these skills in a number of ways that include the exposure to appropriate open-ended hands-on tasks. As higher order thinking skills underlie the development of both complex reasoning and scientific process, it is important that science educators take appropriate steps to facilitate the development of this level of thinking. This study examined the use of some higher order thinking skills by students using Information Technology in their science classroom. It investigated the degree to which students used their higher order thinking skills when engaged in a computer simulation of a complex science task. The study involved two pairs of Year 9 students, one pair each from the upper and lower quartiles of the year level, in a private Years 4 to 12 boys' school in an inner Brisbane suburb. All students had been immersed in Information Technology in Years 4 to 8 as part of a technology-across-the-curriculum project for all year levels in the school and at the time of the study were at the end of their second semester in Year 9. Students had worked with a large number of computer applications in all their subjects, averaging about one lesson in the computer room per day across all their subjects for the past year of schooling. The school also had a policy for learning and teaching that revolved around the development in students of critical thinking and, specifically in Science, complex reasoning, and scientific process skills. During this study, students engaged in a computer simulation requiring the application of skills and knowledge already learnt in their science course. The modules of this simulation developed an understanding of the essentials for life and the quantities of a range of items from water to seeds to land areas that would be required for a number of people that would be needed to staff the Lunar Base. Prompts were given on the way, which assisted students in their decision making. Students progressed through the various areas and stages of the development of the Lunar Base until they were satisfied that each area supported the others and that there was no imbalance that needed to be corrected. Once all stages had been completed, students were free to change variables and experiment further as they saw fit in order that they might produce the most self-sufficient Lunar Base possible. There was some evidence that the simulation did encourage the students in the pairs observed to think in greater depth about the materials and to argue their convictions in an improved manner. As well as the students appearing to increase in competency in argument over the period of time, the four students in their final interviews, spoke of feeling satisfied with the results of the lessons. The students also appeared more engrossed in their task and the pedagogy provided in the task was appreciated as it gave meaning to why they were required to learn scientific materials as well also presenting them with ways to find the knowledge for themselves.
|
8 |
The development of a framework for evaluating e-assessment systemsSingh, Upasana Gitanjali 11 1900 (has links)
Academics encounter problems with the selection, evaluation, testing and implementation of e-assessment software tools. The researcher experienced these problems while adopting e-assessment at the university where she is employed. Hence she undertook this study, which is situated in schools and departments in Computing-related disciplines, namely Computer Science, Information Systems and Information Technology at South African Higher Education Institutions. The literature suggests that further research is required in this domain. Furthermore, preliminary empirical studies indicated similar disabling factors at other South African tertiary institutions, which were barriers to long-term implementation of e-assessment. Despite this, academics who are adopters of e-assessment indicate satisfaction, particularly when conducting assessments with large classes. Questions of the multiple choice genre can be assessed automatically, leading to increased productivity and more frequent assessments. The purpose of this research is to develop an evaluation framework to assist academics in determining which e-assessment tool to adopt, enabling them to make more informed decisions. Such a framework would also support evaluation of existing e-assessment systems.
The underlying research design is action research, which supported an iterative series of studies for developing, evaluating, applying, refining, and validating the SEAT (Selecting and Evaluating an e-Assessment Tool) Evaluation Framework and subsequently an interactive electronic version, e-SEAT. Phase 1 of the action research comprised Studies 1 to 3, which established the nature, context and extent of adoption of e-assessment. This set the foundation for development of SEAT in Phase 2. During Studies 4 to 6 in Phase 2, a rigorous sequence of evaluation and application facilitated the transition from the manual SEAT Framework to the electronic evaluation instrument, e-SEAT, and its further evolution.
This research resulted in both a theoretical contribution (SEAT) and a practical contribution (e-SEAT). The findings of the action research contributed, along with the literature, to the categories and criteria in the framework, which in turn, contributed to the bodies of knowledge on MCQs and e-assessment.
The final e-SEAT version, the ultimate product of this action research, is presented in Appendix J1. For easier reference, the Appendices are included on a CD, attached to the back cover of this Thesis.. / Computing / PhD. (Information Systems)
|
9 |
Kegelsnedes as integrerende faktor in skoolwiskundeStols, Gert Hendrikus 30 November 2003 (has links)
Text in Afrikaans / Real empowerment of school learners requires preparing them for the age of technology. This empowerment can be achieved by developing their higher-order thinking skills. This is clearly the intention of the proposed South African FET National Curriculum Statements Grades 10 to 12 (Schools). This research shows that one method of developing higher-order thinking skills is to adopt an integrated curriculum approach. The research is based on the assumption that an integrated curriculum approach will produce learners with a more integrated knowledge structure which will help them to solve problems requiring higher-order thinking skills. These assumptions are realistic because the empirical results of several comparative research studies show that an integrated curriculum helps to improve learners' ability to use higher-order thinking skills in solving nonroutine problems. The curriculum mentions four kinds of integration, namely integration across different subject areas, integration of mathematics with the real world, integration of algebraic and geometric concepts, and integration into and the use of dynamic geometry software in the learning and teaching of geometry. This research shows that from a psychological, pedagogical, mathematical and historical perspective, the theme conic sections can be used as an integrating factor in the new proposed FET mathematics curriculum. Conics are a powerful tool for making the new proposed curriculum more integrated. Conics can be used as an integrating factor in the FET band by means of mathematical exploration, visualisation, relating learners' experiences of various parts of mathematics to one another, relating mathematics to the rest of the learners' experiences and also applying conics to solve real-life problems. / Mathematical Sciences / D.Phil. (Wiskundeonderwys)
|
10 |
Kegelsnedes as integrerende faktor in skoolwiskundeStols, Gert Hendrikus 30 November 2003 (has links)
Text in Afrikaans / Real empowerment of school learners requires preparing them for the age of technology. This empowerment can be achieved by developing their higher-order thinking skills. This is clearly the intention of the proposed South African FET National Curriculum Statements Grades 10 to 12 (Schools). This research shows that one method of developing higher-order thinking skills is to adopt an integrated curriculum approach. The research is based on the assumption that an integrated curriculum approach will produce learners with a more integrated knowledge structure which will help them to solve problems requiring higher-order thinking skills. These assumptions are realistic because the empirical results of several comparative research studies show that an integrated curriculum helps to improve learners' ability to use higher-order thinking skills in solving nonroutine problems. The curriculum mentions four kinds of integration, namely integration across different subject areas, integration of mathematics with the real world, integration of algebraic and geometric concepts, and integration into and the use of dynamic geometry software in the learning and teaching of geometry. This research shows that from a psychological, pedagogical, mathematical and historical perspective, the theme conic sections can be used as an integrating factor in the new proposed FET mathematics curriculum. Conics are a powerful tool for making the new proposed curriculum more integrated. Conics can be used as an integrating factor in the FET band by means of mathematical exploration, visualisation, relating learners' experiences of various parts of mathematics to one another, relating mathematics to the rest of the learners' experiences and also applying conics to solve real-life problems. / Mathematical Sciences / D.Phil. (Wiskundeonderwys)
|
Page generated in 0.0799 seconds