Interview Room versus Classroom: How Do the Data Compare*?
Jacquelyn J. Chini, Adrian Carmichael, N. Sanjay Rebello
Kansas State University, Manhattan, KS 66506; USA
Sadhana Puntambekar
University of Wisconsin, Madison, WI 53706; USA
In our research, we often use data collected during teaching/learning interviews [1] to investigate student learning. While the teaching/learning interview is intended to model a natural learning environment, it is different than an actual classroom learning atmosphere. A teaching/learning interview typically involves one to four students working with one researcher/facilitator in an interview room. The interaction is audio and video recorded. These differences may potentially cause students to act differently than they would in their actual class. To investigate this possibility, we used the same instructional materials in a teaching interview and laboratory setting. The instructional materials were from the CoMPASS curriculum that integrates hypertext based concept maps with design-based activities [2]. All participants were enrolled in introductory concept-based physics. We will describe how the data collected in these two settings compare.
[1] Engelhardt, P.V., et al. The Teaching Experiment - What it is and what it isn't. in Physics Education Research Conference, 2003. 2003. Madison, WI.
[2] Puntambekar, S., A. Stylianou, and R. Hübscher, “Improving navigation and learning in hypertext environments with navigable concept maps.” Human-Computer Interaction, 2003. 18: p. 395-428.
*This work is funded in part by the U.S. Department of Education, Institute of Education Sciences, Award # R305A080507
Showing posts with label simulations. Show all posts
Showing posts with label simulations. Show all posts
Tuesday, September 8, 2009
Chini, Carmichael, Rebello, Puntambekar: AAPT Summer 2009 (Poster)
Can Simulations Replace Hands-on Experiments in Mechanics Too?*
Jacquelyn J. Chini, Adrian Carmichael, N. Sanjay Rebello
Kansas State University, Manhattan, KS 66506; USA
Sadhana Puntambaker
University of Wisconsin, Madison, WI 53706; USA
It has previously been demonstrated [1] that an appropriately designed simulation can be more effective than analogous hands-on activities in the context of circuits. Circuits involve microscopic phenomenon, such as the movement of electrons, which can be modeled more clearly by a computer than real equipment. Will simulations be more effective than hands-on activities in other contexts, too? We investigated whether simulations could effectively replace hands-on experiments in a unit on inclined planes from the CoMPASS curriculum, which integrates hypertext concept maps with design-based activities [2]. Three sections of an introductory physics laboratory completed hands-on experiments, and two sections completed the same experiment in simulation. Students who used the simulations performed statistically significantly better on the post-test than students who completed the hands-on experiments.
[1] Finkelstein, N.D., et al., “When learning about the real world is better done virtually: A study of substituting computer simulations for laboratory equipment.” PRST-PER, 2005. 1: p. 010103.[2] Puntambekar, S., A. Stylianou, and R. Hübscher, “Improving navigation and learning in hypertext environments with navigable concept maps.” Human-Computer Interaction, 2003. 18: p. 395-428.
*This work is funded in part by the U.S. Department of Education, Institute of Education Sciences, Award # R305A080507.
Jacquelyn J. Chini, Adrian Carmichael, N. Sanjay Rebello
Kansas State University, Manhattan, KS 66506; USA
Sadhana Puntambaker
University of Wisconsin, Madison, WI 53706; USA
It has previously been demonstrated [1] that an appropriately designed simulation can be more effective than analogous hands-on activities in the context of circuits. Circuits involve microscopic phenomenon, such as the movement of electrons, which can be modeled more clearly by a computer than real equipment. Will simulations be more effective than hands-on activities in other contexts, too? We investigated whether simulations could effectively replace hands-on experiments in a unit on inclined planes from the CoMPASS curriculum, which integrates hypertext concept maps with design-based activities [2]. Three sections of an introductory physics laboratory completed hands-on experiments, and two sections completed the same experiment in simulation. Students who used the simulations performed statistically significantly better on the post-test than students who completed the hands-on experiments.
[1] Finkelstein, N.D., et al., “When learning about the real world is better done virtually: A study of substituting computer simulations for laboratory equipment.” PRST-PER, 2005. 1: p. 010103.[2] Puntambekar, S., A. Stylianou, and R. Hübscher, “Improving navigation and learning in hypertext environments with navigable concept maps.” Human-Computer Interaction, 2003. 18: p. 395-428.
*This work is funded in part by the U.S. Department of Education, Institute of Education Sciences, Award # R305A080507.
Chini, Carmichael, Rebello, Puntambekar: PERC 2009
Does the Teaching/Learning Interview Provide an Accurate Snapshot of Classroom Learning?
Jacquelyn J. Chini, Adrian Carmichael, and N. Sanjay Rebello
Kansas State University, Manhattan, KS 66506; USA
Sadhana Puntambekar
University of Wisconsin, Madison, WI 53706; USA
The teaching/learning interview has been used to investigate student learning. The aim of the teaching/learning interview is to model a natural learning environment while allowing more direct access to a student’s or group’s thinking and reasoning. The interview typically involves one to four students working with a researcher/interviewer while being audio and video recorded. It has previously been reported [1] that the data collected in a teaching/learning interview is richer in detail than data collected in an actual classroom. We investigated the possibility that there were also other differences between these formats. We used the same instructional materials as well as pre-, mid- and post-tests in a teaching/learning interview and in a classroom laboratory setting. We will describe how the data collected in these two settings compare.
1. D. L. McBride, “Concept Categorization Analysis: Comparing Verbal and Written Data” in American Association of Physics Teachers Winter Meeting, Chicago, IL, 2009
**This work is funded in part by U.S. Department of Education, Institute of Education Sciences Award R305A080507.
Jacquelyn J. Chini, Adrian Carmichael, and N. Sanjay Rebello
Kansas State University, Manhattan, KS 66506; USA
Sadhana Puntambekar
University of Wisconsin, Madison, WI 53706; USA
The teaching/learning interview has been used to investigate student learning. The aim of the teaching/learning interview is to model a natural learning environment while allowing more direct access to a student’s or group’s thinking and reasoning. The interview typically involves one to four students working with a researcher/interviewer while being audio and video recorded. It has previously been reported [1] that the data collected in a teaching/learning interview is richer in detail than data collected in an actual classroom. We investigated the possibility that there were also other differences between these formats. We used the same instructional materials as well as pre-, mid- and post-tests in a teaching/learning interview and in a classroom laboratory setting. We will describe how the data collected in these two settings compare.
1. D. L. McBride, “Concept Categorization Analysis: Comparing Verbal and Written Data” in American Association of Physics Teachers Winter Meeting, Chicago, IL, 2009
**This work is funded in part by U.S. Department of Education, Institute of Education Sciences Award R305A080507.
Monday, September 7, 2009
Carmichael, Chini, Rebello and Puntambekar: AAPT Summer 2009 Talk
Effectiveness of Hands on Experiments versus Computer Simulations in Mechanics*
Adrian Carmichael, Jacquelyn J. Chini, N. Sanjay Rebello
Department of Physics, Kansas State University
Sadhana Puntambaker
Department of Educational Psychology, University of Wisconsin, Madison
Research has shown that that simulations can be more effective than hands-on activities when studying microscopic phenomenon such as electric currents, It has yet to be determined if they have the same effectiveness with macroscopic phenomenon, such as those in mechanics. This study investigates the effectiveness of replacing a hands-on laboratory with a computer simulation in the context of a unit on inclined planes in the CoMPASS curriculum. CoMPASS integrates hypertext based concept maps in a design-based context. Students in three of the five introductory physics laboratory sections completed the hands-on experiment while the other two sections performed the experiment virtually. The post- test scores of the students who used the simulations were found to be statistically significantly greater than those of students who completed the hands on experiment.
Carmichael, Chini, Rebello and Puntambekar: PERC 2009 Paper
Comparing Student Learning in Mechanics Using Simulations and Hands-on Activities
Adrian Carmichael1, Jacquelyn J. Chini1, N. Sanjay Rebello1 and Sadhana Puntambekar2
1Kansas State University, 2University of Wisconsin, Madison
Abstract. Often computer simulation environments present students with an idealized version of the real world which can affect students’ conceptual understanding. In this study we investigate the effects of completing an experiment in mechanics using this ideal world as compared to an identical experiment in the real world. Students in three of five conceptual physics laboratory sections completed the physical experiment while the other two sections performed the virtual experiment. The experiments were part of a unit on simple machines from the CoMPASS curriculum which integrates hypertext-based concept maps in a design-based context. There was no statistically significant difference between the pre and post data of the students in the two groups. Students who performed the virtual experiment were able to answer questions dealing with work and potential energy more correctly, though neither group was able to offer sound reasoning to support their answers.*This work is funded in part by U.S. Department of Education, Institute of Education Sciences Award R305A080507
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