Effects of instructional aids on the acquisition of dynamic decision-making skills

This study tested the effects of two instructional aids in a complex, dynamic environment, specifically, a business simulation. Participants studied (1) a “causal map,” which depicted key variables in an interconnected network, (2) a textual outline of the same relationships, or (3) no-aid. With the relevant aid still available, the participants ran the simulation three times. Then, the aid was removed, and the participants ran another three simulations. Both when the aid was available and later when removed, the group receiving the causal map gained a greater market share than the other two groups, which failed to differ. With respect to profits, however, a cross-over interaction appeared. When the aid was available, the causal map group showed lower profits than the other two groups, but, without the aid, the causal map group showed greater profits. The results are discussed in the context of information processing theories of instructional design.     

The effects of computer-assisted instruction and locus of control upon preservice elementary teachers' acquisition of the integrated science process skills

The purpose of this study was to determine the effects of computer-assisted instruction (CAI) versus a text mode of programmed instruction (PI), and the cognitive style of locus of control, on preservice elementary teachers' achievement of the integrated science process skills. Eighty-one preservice elementary teachers in six sections of a science methods class were classified as internally or externally controlled. The sections were randomly assigned to receive instruction in the integrated science process skills via a microcomputer or printed text. The study used a pretest-posttest control group design. Before assessing main and interaction effects, analysis of covariance was used to adjust posttest scores using the pretest scores. Statistical analysis revealed that main effects were not significant. Additionally, no interaction effects between treatments and loci of control were demonstrated. The results suggest that printed PI and tutorial CAI are equally effective modes of instruction for teaching internally and externally oriented preservice elementary teachers the integrated science process skills.     

The effectiveness of online instructional videos in the acquisition and demonstration of cognitive,affective and psychomotor rehabilitation skills

The use of instructional videos to teach clinical skills is an ever growing area of e‐learning based upon observational learning that is cited as one of the most basic yet powerful learning strategies. The aim of the current study is to evaluate the effectiveness of online instructional videos for the acquisition and demonstration of cognitive, affective and psychomotor skills among undergraduate students, throughout formative assessments with two different durations of instructional videos. The research suggests that the use of videos to support traditional learning should be encouraged. While a conclusive evidence—base for their usage has not yet been established they are a medium which is likely to benefit a proportion of a cohort, and it is very unlikely that they will be harmful to students' learning.     

The acquisition of basic multiplication skills

Children learning the basic multiplications, use knowledge which they acquired in former stages. Certain additions, for instance the doubles, known by heart, can support the learning process for multiplication. It makes a great difference in cognitive achievement whether children know multiplication facts by heart or whether they are able to figure out basic multiplications. If education supports the development of informal thinking strategies, children become so skilled at this, that the border between figuring out and knowing by heart will gradually disappear. By using informal strategies children will acquire a flexible mental structure of multiplication facts instead of a collection of rules.     

The effects of metacognitive instruction embedded within an asynchronous learning network on scientific inquiry skills

The study is aimed at investigating the effects of four learning methods on students’ scientific inquiry skills. The four learning methods are: (a) metacognitive‐guided inquiry within asynchronous learning networked technology (MINT); (b) an asynchronous learning network (ALN) with no metacognitive guidance; (c) metacognitive‐guided inquiry embedded within face‐to‐face (F2F) interaction; and (d) F2F interaction with no metacognitive guidance. The study examined general scientific ability and domain‐specific inquiry skills in microbiology. Participants were 407 10th‐grade students (15 years old). The MINT research group significantly outperformed all other research groups, and F2F (group d) acquired the lowest mean scores. No significant differences were found between research groups (b) and (c). MINT makes significant contributions to students’ achievements in designing experiments and drawing conclusions. The novel use of metacognitive training within an ALN environment demonstrates the advantage of enhancing the effects of ALN on students’ achievements in science.     

The effects of part-task and whole-task instructional approaches on acquisition and transfer of a complex cognitive skill

This study was designed to investigate the effects of two instructional approaches (whole-task versus part-task) and two levels of learner prior knowledge (lower versus higher) on learner acquisition and transfer of a complex cognitive skill. Participants were 51 undergraduate pre-service teachers. In the part-task condition, a complex skill (preparing a grade book using Excel) was decomposed into a series of smaller tasks, each of which was demonstrated and practiced separately. In the whole-task condition, which was based on the 4C/ID-model (van Merriënboer 1997), learners were exposed to the entire complex skill from the beginning of the instruction and were required to practice performing a series of whole tasks throughout the unit. Results indicated that the whole-task group performed significantly better than the part-task group on a skill acquisition test and a transfer test. Possible reasons for these findings and suggestions for future research are discussed.     

The effects of daily homework assignments on the acquisition of basic skills by students with learning disabilities

Examined in this two-study investigation was the effectiveness of supplemental homework assignments on the acquisition of basic skills by students with diagnosed learning disabilities (LD). In Experiment 1, an adapted alternating treatments design was used to investigate the efficacy of unstructured homework assignments with 6 elementary school-aged students having basic math problems. Although the impact of the homework assignments differed across students, three factors maximized the effectiveness of the homework assignments: rate of homework completion, percentage correct on the homework assignments, and the rate of acquisition of the content being presented. Experiment 2, designed to formally test the effectiveness of homework assignments structured specifically to address these identified factors, confirmed that homework can be employed to increase the effectiveness of direct instruction sequences with students diagnosed as LD.     

The effects of instructional intervention on improving proportional,probabilistic, and correlational reasoning skills among undergraduate education majors

The main purpose of this study was to test the effect of instruction to improve the reasoning skills of undergraduates majoring in the field of education. The results of this investigation demonstrate the lack of proficiency in formal reasoning by undergraduate education majors in the areas of proportional, probabilistic, and correlational reasoning. However, after receiving three specifically planned interventions, students in the experimental group showed improvement in all three areas of reasoning (p ≤ 0.05). Also, it was noted that students with science and/or math in their backgrounds performed significantly (p ≤ 0.05) better in all three areas of reasoning on both pre‐ and post‐tests than did students with no science or math in their backgrounds. This study is among the first to show that background knowledge obtained from college level science and math courses correlates with better reasoning skills. Data from this study also demonstrated that interventions focusing on probability and proportionality improved the correlational reasoning skills of students. The results of this investigation indicate that deficiencies in reasoning abilities in the areas of proportionality, probability, and correlational reasoning can be successfully addressed even with limited classroom intervention. © 2000 John Wiley & Sons, Inc. J Res Sci Teach 37: 981–995, 2000     

Teacher collaborative inquiry in the context of literacy education: examining the effects on teacher self-efficacy,instructional and assessment practices

This case study research reports on elementary (grade 8) and secondary school (grade 9) teachers’ participation in job-embedded, professional learning and engagement in collaborative inquiry. Teachers constructed an inquiry-oriented media literacy unit following the collaborative inquiry model. The current study sought to investigate how collaborative inquiry influenced their self-efficacy in literacy instruction, instructional and assessment practices. Qualitative data sources included researchers’ anecdotal notes, teacher interviews, and professional learning blog conversations. Inductive analyses of the data generated six major themes comprising enhancements to teachers’ literacy instructional and assessment practices, which were evident in their adoption of the backward-design model, use of success criteria, and greater emphasis on diagnostic and formative assessment. With respect to teachers’ self-efficacy, data analyses also revealed increased levels of intrinsic motivation, professional satisfaction, and reflective practice. This study provides evidence for the transformative potential and characteristics of school-based teacher collaborative inquiry and the resultant impacts on teacher learning.     

Supporting the development of science inquiry skills with special classes of software

Computers have been used with science learners to teach facts, aid in information processing, facilitate problem solving, and stimulate conceptual change. The hallmark of science learning, however, is independent student inquiry. Although there is ample evidence that computers can support various aspects of students' inquiry activities, such as conducting virtual experiments and visualizing data, there has been limited discussion of how certain classes of software can facilitate learners' development, over time, from simple to sophisticated forms of inquiry. This theory-based article describes how data analysis tools, simulations, and modeling software, when used in the proper instructional contexts, provide young learners with rich intellectual environments for inquiry. Arguments from the research literature support claims that even the youngest elementary school learners have the capacity to engage in inquiry, and that special classes of software can stimulate these capacities and aid the transition from identifying basic patterns in data to conducting systematic experiments and constructing viable models of natural phenomena.     

Development of student inquiry skills in a computerised classroom environment

This paper discusses a study in progress which involves the use of a computerised research science database (Birds of the Antarctica) and specially designed curriculum materials. The purpose of the study is to investigate the extent to which students’ inquiry skills can be facilitated by the materials. Much attention is given in the programme to developing both students’ inquiry skills and their subject-matter knowledge. Year 11 and 12 students’ knowledge and skills development are interpreted as they interact with the computerised database and the curriculum materials. Preliminary findings about students’ abilities and perceptions are discussed and, in particular, constraints to the development of inquiry skills and construction of understanding are explored. Specializations: Science education, computers in education, learning environment.     

The effects of microcomputer-based laboratory exercises on the acquisition of line graph construction and interpretation skills by high school biology students

Effects of microcomputer-based laboratories and level of cognitive development on tenth-grade biology students' ability to construct and interpret line graphs was investigated. Fortysix students enrolled in general biology classes at a rural high school volunteered to participate in the study. These students were administered instruments to assess level of cognitive development and line-graphing ability. Ten students that scored between zero and three and ten students that scored between six and ten on the graphing assessment were chosen to participate in the study. The 20 students were then assigned to either experimental or conventional groups to achieve a matched design with relation to gender and line-graphing ability. Statistical analysis of the data indicated no effect due to instructional method on graph-interpretation abilities. An instructional effect was demonstrated for graph-construction tasks (p < 0.10) with the conventional group outperforming the microcomputer-based laboratory group. Effect sizes of ?1.01 and 0.48 were found for graph-construction and -interpretation skills, respectively. Effects related to cognitive development were indicated with those students classified as high cognitive development outscoring those classified as low (p < 0.10) This was true for both graph-construction and graph-interpretation tasks. No two-way interactions were found.     

The comparative effects of teacher-demonstration and self-paced instruction on concept acquisition and problem-solving skills of college level chemistry students

A comparison is made of the relative effectiveness of teacher-demonstration and self-paced modes of teaching concepts and problem-solving skills in chemistry. Sixty students were randomized into two treatment groups. A self-paced instructional package was used by subjects in the self-paced group. Subjects in the second group were taught by a teacher who used the same self-paced package. Results of the analyses of variance performed showed that the selfpaced mode of instruction was significantly more effective for teaching concepts and problem-solving skills. An attitude test was given at the end of the third unit. Results of the test showed that most students preferred the self-paced instruction to the teacher-demonstration method.     

Students' perceptions of teaching skills and overall effectiveness across instructional settings

This study examines the differences in students' perceptions of the amount of improvement in dimensions of teaching skills across levels of instruction, class sizes, and disciplines. The relationship between factor scores on the dimensions of teaching and students' overall ratings are also analyzed across instructional settings.Student ratings were collected in 2,816 classes in a Faculty of Commerce over three semesters. Using class means as a unit of analysis, the data were factor-analyzed. Factor scores were used as dependent variables in examining differences across course characteristics. Factor scores were further used to predict ratings of the overall quality of instruction. These predictions were subsequently compared across instructional settings.In the combined sample, differences in students' perceptions were found across levels of instruction for all factors, and across class size for two factors. When analyses were conducted on these variables within separate disciplines, the results varied. The relationship between factor scores on the dimensions of teaching and students' overall ratings varied across instructional settings.The results are discussed in relation to previous research on the dimensions of teaching and in relation to the concept of students' normative assumptions about teaching behavior. Some practical implications of the results are also described.     

Towards powerful learning environments for the acquisition of problem-solving skills

It is generally agreed that acquiring thinking and problem-solving skills is nowadays a primary objective of general education. Responding appropriately to this challenge requires an answer to the following questions: 1. what does the acquisition of problem-solving skills involve, and 2. how can those abilities be fostered through systematic instruction? This contribution describes a four-step model of skilled problem-solving processes, and gives an overview of three major categories of cognitive skills involved in competent problem solving, namely, the flexible and integrated application of domain-specific knowledge, of heuristic methods, and of metacognitive skills. Furthermore, a framework is presented for the design and elaboration of powerful teaching-learning environments in which such problem-solving skills can be acquired efficiently. Two basic ideas underlying this model are: the view of learning as a constructive process, and the idea of cognitive apprenticeship as an effective and appropriate method for learning and teaching. Finally, some recent research findings supporting the educational significance of the framework are briefly reviewed.