Leveraging multimodal learning analytics to differentiate student learning strategies

Multimodal analysis has had demonstrated effectiveness in studying and modeling several human-human and human-computer interactions. In this paper, we explore the role of multimodal analysis in the service of studying complex learning environments. We compare uni-modal and multimodal; manual and semi-automated methods for examining how students learn in a hands-on, engineering design context. Specifically, we compare human annotations, speech, gesture and electro-dermal activation data from a study (N=20) where student participating in two different experimental conditions. The experimental conditions have already been shown to be associated with differences in learning gains and design quality. Hence, one objective of this paper is to identify the behavioral practices that differed between the two experimental conditions, as this may help us better understand how the learning interventions work. An additional objective is to provide examples of how to conduct learning analytics research in complex environments and compare how the same algorithm, when used with different forms of data can provide complementary results.

[1]  Marcelo Worsley,et al.  1st international workshop on multimodal learning analytics: extended abstract , 2012, ICMI '12.

[2]  Paulo Blikstein,et al.  Modeling how students learn to program , 2012, SIGCSE '12.

[3]  Lucienne Blessing,et al.  Understanding the differences between how novice and experienced designers approach design tasks , 2003 .

[4]  S. Levinson,et al.  Considerations in dynamic time warping algorithms for discrete word recognition , 1978 .

[5]  Marcelo Worsley,et al.  Programming Pluralism: Using Learning Analytics to Detect Patterns in the Learning of Computer Programming , 2014, Journal of the Learning Sciences.

[6]  Marcelo Worsley,et al.  Towards the development of multimodal action based assessment , 2013, LAK '13.

[7]  Arthur C. Graesser,et al.  Automatic detection of learner’s affect from conversational cues , 2008, User Modeling and User-Adapted Interaction.

[8]  Johanna D. Moore,et al.  Using Natural Language Processing to Analyze Tutorial Dialogue Corpora Across Domains Modalities , 2009, AIED.

[9]  Julia Hirschberg,et al.  Detecting certainness in spoken tutorial dialogues , 2005, INTERSPEECH.

[10]  Nadir Weibel,et al.  ChronoViz: a system for supporting navigation of time-coded data , 2011, CHI Extended Abstracts.

[11]  Marcelo Worsley,et al.  Multimodal learning analytics: enabling the future of learning through multimodal data analysis and interfaces , 2012, ICMI '12.

[12]  Marcelo Worsley,et al.  Analyzing Engineering Design through the Lens of Computation , 2014, J. Learn. Anal..

[13]  David Hammer,et al.  Student Behavior and Epistemological Framing: Examples from Collaborative Active-Learning Activities in Physics , 2007, ICLS.

[14]  K. Holyoak,et al.  Analogical problem solving , 1980, Cognitive Psychology.

[15]  Marcelo Worsley,et al.  Assessing the “ Makers ” : The Impact of Principle-Based Reasoning on Hands-on , Project-Based Learning , 2014 .

[16]  David Hammer,et al.  Making classroom assessment more accountable to scientific reasoning: A case for attending to mechanistic thinking , 2009 .

[17]  Ryan S. Baker,et al.  The State of Educational Data Mining in 2009: A Review and Future Visions. , 2009, EDM 2009.

[18]  Yale Song,et al.  Multimodal human behavior analysis: learning correlation and interaction across modalities , 2012, ICMI '12.

[19]  Marcelo Worsley,et al.  Toward the Development of Learning Analytics: Student Speech as an Automatic and Natural Form of Assessment , 2010 .

[20]  Tanja Schultz,et al.  Vision-based handwriting recognition for unrestricted text input in mid-air , 2012, ICMI '12.

[21]  Mihaly Csikszentmihalyi,et al.  Flow: the psychology of happiness , 1992 .

[22]  N. Law,et al.  Productive Multivocality in the Analysis of Group Interactions , 2013 .

[23]  G. McCullough,et al.  International Encyclopedia of Education , 2008 .

[24]  Arthur C. Graesser,et al.  Emote aloud during learning with AutoTutor: Applying the Facial Action Coding System to cognitive–affective states during learning , 2008 .

[25]  L. Schauble,et al.  Reasoning about Structure and Function: Children's Conceptions of Gears , 1998 .

[26]  J. Kolodner Educational implications of analogy. A view from case-based reasoning. , 1997, The American psychologist.

[27]  Cristina Conati,et al.  Empirically building and evaluating a probabilistic model of user affect , 2009, User Modeling and User-Adapted Interaction.

[28]  Michelene T. H. Chi,et al.  Expertise in Problem Solving. , 1981 .

[29]  Cynthia J. Atman,et al.  Comparing freshman and senior engineering design processes: an in-depth follow-up study , 2005 .

[30]  Kurt VanLehn,et al.  Inducing Effective Pedagogical Strategies Using Learning Context Features , 2010, UMAP.

[31]  Paulo Blikstein,et al.  Multimodal learning analytics , 2013, LAK '13.

[32]  Christian D. Schunn,et al.  Problem solving and human expertise , 2010 .

[33]  Vladimir I. Levenshtein,et al.  Binary codes capable of correcting deletions, insertions, and reversals , 1965 .