The Future of Embodied Design for Mathematics Teaching and Learning

Abrahamson, Dor; Nathan, Mitchell J.; Williams-Pierce, Caro; Walkington, Candace; Ottmar, Erin; Soto, Hortensia; Alibali, Martha W.

doi:10.3389/feduc.2020.00147

Cited by 76 publications

(48 citation statements)

References 219 publications

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“…Embodied learning is implemented at several degrees of bodily engagement: finger tracing (Botzer & Yerushalmy, 2008), gestures (e.g., Alibali & Nathan, 2012), large motor action (e.g., Abrahamson et al, 2012), full‐body movements (e.g., Johnson‐Glenberg et al, 2014), and force feedback: feeling the force that contributes to or that is involved in the studied motion (Han & Black, 2011; Magana & Balachandran, 2017; Minogue & Borland, 2016; Neri et al, 2018; Reiner, 1999). Empirical studies show that embodied learning environments enhance understanding either when the action is performed by the learner, such as gestures (e.g., Abrahamson et al, 2020), or when the action is performed on the learner, such as a haptic force exerted on the body (e.g., Neri et al, 2018; Reiner, 1999).…”

Section: Theoretical Frameworkmentioning

confidence: 99%

“…Changing persistent concepts requires, among other things, well‐designed learning environments that promote the restructuring of knowledge schemas (Plass et al, 2012; Stieff & Wilensky, 2003). We approach this challenge from the perspective of embodied learning, which relates the knowledge‐construction process to the physical interactions of learners with their surroundings (Abrahamson et al, 2020). According to embodied learning theory, perceptual experience may provide the grounds for constructing mental simulations of an abstract phenomenon.…”

Section: Introductionmentioning

confidence: 99%

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From feeling forces to understanding forces: The impact of bodily engagement on learning in science

Zohar

Levy

2021

J Res Sci Teach

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Embodied cognition theories view sensorimotor activity as fundamental to learning, knowing, and reasoning. To investigate the role of physical movement in conceptual learning, we developed and explored an Embodied Learning Interactive Chemistry environment (ELI‐Chem). The ELI‐Chem learning environment includes a computer simulation, a device for interacting with the simulation, and an online activity guide. In particular, we focused on the topic of chemical bonding—an abstract and nonintuitive phenomenon that is crucial to chemistry learning and that presents pervasive problems in learning. The ELI‐Chem learning environment embodies atoms' movement through four increasing degrees of bodily engagement in terms of range of motion and forces—movie, simulation, joystick, and haptic device (applies force feedback). A randomly assigned pretest‐intervention‐posttest four‐group comparison design was used with a mixed‐methods research approach. Quantitative analysis of pretest and posttest questionnaires tested the conceptual learning. Qualitative analysis of students' filled activity guides explored students' perceptions of the learning process and features of understanding. The participants were 48 high school chemistry students, 12 students in each degree of bodily engagement. During the activity, students were prompted to discover the forces underlying chemical bonding and to explore the energy changes involved. We found an increase in students' conceptual understanding in all four degrees of bodily engagement, with significantly higher learning gains and causal understanding in the haptic condition with a greater range of motion and forces. This study highlights the states in which embodied learning uniquely contributes to understanding and perception: absence of prior embodied experience, learning about a nonvisual concept related to forces, and a high congruence with the concept learned.

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Section: Theoretical Frameworkmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

From feeling forces to understanding forces: The impact of bodily engagement on learning in science

Zohar

Levy

2021

J Res Sci Teach

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“…These researchers proposed attentional anchors as a mechanism that channels attention during agentmedium couplings, as enabling restrictions for action (Hutto and Sánchez-García, 2014). In addition to this, Abrahamson et al (2020) carried out an exhaustive review on different research approaches based on perception and action design, which would be very useful for STEM design. The researchers suggest that being informed about the research on how we learn to move in new ways could help us better design, measure, and theorize the performance of physical movements that underpin STEM learning, particularly the enactive and ecological approaches.…”

Section: Introductionmentioning

confidence: 99%

“…Even though the studies framed in the enactive and ecological approaches of Hutto et al (2015) and Abrahamson et al (2020) provide solid evidence about embodied design research and the sensorimotor dynamics that is at the base of learning in the context of STEM, we consider it necessary to report some untreated and highly relevant aspects within the framework of a unified enactive-ecological approach for a STEAM pedagogy. In particular, we consider certain knowledge gaps that are recognized in the empirical evidence and that would be of great use to researchers in the STEM/STEAM field and educational organizations wishing to incorporate these methodologies.…”

Section: Introductionmentioning

confidence: 99%

“…To justify point 1), we ascribe to the proposals of Abrahamson et al (2020) on the need for enactive (Varela et al, 1991) and ecological (Gibson, 1979) approaches for the design of educational environments based on perception and action, since current approaches to cognition obviate the importance of cultural artifacts and the body as sources of knowledge. The enactive and ecological approaches provide new ways of understanding the role of sensorimotor activity in the development of learning experiences, mediated by the action of perception of and adaptation to the environment.…”

Section: Introductionmentioning

confidence: 99%

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From STEM to STEAM: An Enactive and Ecological Continuum

2021

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STEM and STEAM education promotes the integration between science, technology, engineering, mathematics, and the arts. The latter aims at favoring deep and collaborative learning on students, through curricular integration in K-12 science education. The enactive and ecological psychology approach to education puts attention on the role of the teacher, learning context and socio-cultural environment in shaping lived learning experiences. The approach describes education as a process of embodied cognitive assemblage of guided perception and action. The latter process depends on the interaction of learners with digital and/or analogue learning affordances existing within the socio-technological environment. This article proposes that the scope of an enactive-ecological approach can be extended to the domain of learning science, technology, engineering, arts, and mathematics (STEAM), especially when it comes to understanding deep roots of the learning process. We first present an exhaustive literature review regarding the foundations of both the enactive and the ecological learning theories, along with their differences and key similarities. We then describe the fundamentals and latest research advances of an integrated STEAM pedagogy, followed by the notion of mixed reality (XR) as an emerging educational technology approach, offering an understanding of its current foundations and general disposition on how to understand digital immersion from ecological psychology. Next, we propose a systems theoretical approach to integrate the enactive-ecological approach in STEAM pedagogy, framed in the Santiago school of cognition attending to the interactive dynamics occurring between learners and their interaction with learning affordances existing within their educational medium, establishing that sensorimotor contingencies and attentional anchors are important to restrict sensory variety and stabilize learning concepts. Finally, we consider two empirical studies, one from Chile and the other from New Zealand, in which we demonstrate how the enactive-ecological approach built upon a systems theory perspective can contribute to understanding the roots of STEAM learning and inform its learning design.

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The role of embodied scaffolding in revealing “enactive potentialities” in intergenerational science exploration

Nygren,

Price,

Thomas Jha

2023

Science Education

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Although adults are known to play an important role in young children's development, little work has focused on the enactive features of scaffolding in informal learning settings, and the embodied dynamics of intergenerational interaction. To address this gap, this paper undertakes a microinteractional analysis to examine intergenerational collaborative interaction in a science museum setting. The paper presents a fine‐grained moment‐by‐moment analysis of video‐recorded interaction of children and their adult carers around science‐themed objects. Taking an enactive cognition perspective, the analysis enables access to subtle shifts in interactants’ perception, action, gesture, and movement to examine how young children engage with exhibits, and the role adult action plays in supporting young children's engagement with exhibits and developing ideas about science. Our findings demonstrate that intergenerational “embodied scaffolding” is instrumental in making “enactive potentialities” in the environment more accessible for children, thus deepening and enriching children's engagement with science. Adult action is central to revealing scientific dimensions of objects’ interaction and relationships in ways that expose novel types of perception and action opportunities in shaping science experiences and meaning making. This has implications for science education practices since it foregrounds not only “doing” science, through active hands‐on activities, but also speaks to the interconnectedness between senses and the role of the body in thinking. Drawing on the findings, this paper also offers design implications for informal science learning environments.

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The Future of Embodied Design for Mathematics Teaching and Learning

Cited by 76 publications

References 219 publications

From feeling forces to understanding forces: The impact of bodily engagement on learning in science

From feeling forces to understanding forces: The impact of bodily engagement on learning in science

From STEM to STEAM: An Enactive and Ecological Continuum

The role of embodied scaffolding in revealing “enactive potentialities” in intergenerational science exploration

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