Following is a collection of visual syntheses comparing and contrasting T-GEM/Chemland with the following technology-enhanced learning environments: Learning for Use (LfU)/My World, Scaffolded Knowledge Integration (SKI)/WISE, and Anchored Instruction/Jasper. The visual syntheses contain a focus on TPCK and learner activity with the guiding TELE being T-GEM/Chemland, and all other TELEs being compared and contrasted through alignment with the T-GEM/Chemland framework.
Each one of these TELEs is developed on inquiry instruction and learning, with T-GEM/Chemland consisting of specifically model-based inquiry. Each one of these TELEs promotes a community of inquiry with purposeful teacher-student and student-student interactions. To emphasize the non-linear processes of inquiry, each visual synthesis is designed in a circular format.
Unique to T-GEM is the cyclical progress that the learner takes moving through the steps of the learning theory. Arrows are placed in each TELE’s visual representation to elicit the learner’s movement in comparison to the T-GEM’s model.
As a general mathematics and science teacher for elementary grade levels, the process of exploring, analyzing and synthesizing the four foundational TELEs presented in this course has been transformational in my development of TPCK. Initially, the importance of CK (Schulman, 1986), and my self-diagnosed lack of CK, was convicting as I tend towards growing in pedagogical ideas and creative ways of implementing them. To further this conviction, my understanding of inquiry processes and the intricate role that the teacher facilitates in conducting a community of inquiry began to become clearer throughout the readings and discussions of Module B. Skillful inquiry instruction requires a facilitator who is saturated in CK, being equipped to prepare, respond, question, prompt, and guide with carefully considered PK. At this time, I am challenged as an educator to begin with one brave adventure in mathematics using an anchored instructional approach, and another brave lesson in physical science using a T-GEM approach. I am certain that I will be generating, evaluating and modifying all along the way.
Cognition and Technology Group at Vanderbilt (1992). The jasper experiment: An exploration of issues in learning and instructional design. Educational Technology Research and Development, (40), 1, pp.65-80
Edelson, D.C. (2001). Learning-for-use: A framework for the design of technology-supported inquiry activities. Journal of Research in Science Teaching,38(3), 355-385.
The following posting is guided by the the following process questions:
What broader questions about learning and technology have provoked WISE research and the development of SKI?
Describe the authors’ pedagogical design considerations that shaped the development of “What’s on your Plate?” How and where was WISE integrated into a larger sequence of activities?
Analyze the evidence and author’s conclusions. Are the conclusions justified? In what ways does WISE support the processes commonly associated with “inquiry” in science? How might these processes be used to support math instruction?
What might be the cognitive and social affordances of the WISE TELE for students? Use “What’s on your Plate?” as an example to support your hypotheses.
Inquiry is the newest trend in pedagogical design and curriculum and infiltrates BCs New Curriculum established for K-9 students. As described in the following video on the BC Ministry of Education website, inquiry requires students to ask questions, hypothesize, investigate, experiment, create, reflect and revise. These actions are intended to help students to learn the processes of science, and not solely the content, while building skills in communication, collaboration, critical thinking, vocabulary building and analysis.
Linn, Clark and Slotta (2003) offer a deeper definition of inquiry and describe it as “engaging students in the intentional process of diagnosing problems, critiquing experiments, distinguishing alternatives, planning investigations, revising views, researching conjectures, searching for information, constructing models, debating with peers, communicating to diverse audiences, and forming coherent arguments (p.518). The designers of WISE (Web-based Inquiry Science Environment) have taken this latter definition, placed it into the Scaffolded Knowledge Integration network (SKI), while asking questions of how to design a technology-based learning environment that “scaffold[s] designers in creating inquiry curriculum projects and designing patterns of activities to promote knowledge integration for students and teachers” (Linn et al., 2003, p.518). The designing of WISE is an evolving inquiry as the design team, including science teachers, pedagogical specialists, scientists and technology designers, engage in inquiry processes through its continuous designing and revising. The designers of WISE are not simply interested in inquiry, but in the intersection of inquiry and technology and the enhancement of learning as a result. A considerable statistic cited by Linn et al. (2003) describing the participation level of students through asynchronous communication in comparison to face-to-face discussion is convincing: “Online asynchronous discussions enable students to make their ideas visible and inspectable by their teachers and peers and give students sufficient time to reflect before making contributions. Hsi (1997) reports that under these circumstances, students warrant their assertions with two or more pieces of evidence and over ninety percent of the students participate. In contrast, Hsi observed that only about 15% of the students participate in a typical class discussion, and that few statements are warranted by evidence” (p.530). Other WISE related studies also reveal enhanced learning as a result of students learning through a technology-based environment. One such design study is conducted by Gobert, Snyder and Houghton (2002) using a WISE project entitled, “What’s on your Plate” – a geology focussed project.
Gobert et al. (2002) pursue a design study “to investigate the impact of decisions about curricular materials with the express goal of redesigning them in accordance with the findings obtained” (p.7). More specifically, they ask, “[I]n what ways does model-building, learning with dynamic runnable visual models in WISE, and the process of critiquing peer’s models promote a deeper understanding of the nature of science as a dynamic process?” (p.7). The two areas of SKI that are focussed on in this study are: 1) making thinking visible and 2) learning from others. Gobert et al.(2002) are also interested in observing changes in students’ epistemologies as they work through the WISE project. Specifically, they asked these questions: “How can we use the technology effectively to promote deep learning in line with epistemic goals? and How can we identify change in students’ epistemic understanding?” (p.2). In order to measure these epistemic changes, pre and post tests are conducted indicating significant increases in student understanding and reasoning related to model-based learning. Student post test responses include significantly more detail, scientific vocabulary and accurate knowledge, while peer critiques include reasoning and communicative understanding. Gobert et al. (2002) state established research for integrating model-based learning within science education, both models to learn from and model construction assignments. Positive effects of model-based learning integration are described here: “It is believed that having students construct and work with their own models engages them in authentic scientific inquiry, and that such activities promote scientific literacy, understanding of the nature of science, and lifelong learning” (Gobert et al., 2002, p.3). These positive effects of model-based learning are evidenced in the conclusions of the design study by Gobert et al. (2002). While model-based learning through WISE indicates significant growth in the students’ understanding of the use of dynamic visual models and the nature of science, can this model-based learning also be effective in the acquisition of mathematics?
WISE supports the processes of inquiry through the “What’s on Your Plate” project including diagnosing, planning, researching, constructing, critiquing, revising, communicating and reasoning. Through these inquiry processes, students successfully make their thinking visible through the construction of models which are then critiqued by peers, and then revised through reasoning. Model-based learning in mathematics could be structured similarly using inquiry processes that require students to diagnose a problem, research the information necessary to solve the problem, construct a model using software or hands-on materials, and share their model with an explanation for peer critique. {This process is evident in The Jasper Series.} Reasoning and further research follow the critique leading to a revised model construction. In essence, model-based learning affords the student to become a “teacher” through the construction of a teachable model. In mathematics, model-based learning could predictably enhance understanding in areas of geometry, patterning and problem solving. Models could include simulations, diagram representations, symbolic data, or three-dimensional constructions.
After brief research, this following resource seems valuable in inquiring further inquiry into model-based learning: Model-Based Approaches to Learning: Using Systems Models and Simulations to Improve Understanding and Problem Solving in Complex Domains by Patrick Blumschein, Woei Hung, David Jonassen, and Johannes Stroebel (2009).
References
Blumschein,P., Hung, W., Jonassen, D., & Stroebel, J. (2009). Model-based approaches to learning: Using systems models and simulations to improve understanding and problem solving in complex domains. Rotterdam, The Netherlands: Sense Publishers.
Gobert, J., Snyder, J., & Houghton, C. (2002, April). The influence of students’ understanding of models on model-based reasoning. Paper presented at the Annual Meeting of the American Educational Research Association (AERA), New Orleans, Louisiana. This is a conference paper. Retrieved conference paper Saturday, October 29, 2013 from: http://mtv.concord.org/publications/epistimology_paper.pdf
Linn, M. C., Clark, D. and Slotta, J. D. (2003), WISE design for knowledge integration . Sci. Ed., 87: 517–538. doi:10.1002/sce.10086
McAleer,N. (2005, June 21). Getting started with student inquiry in science. [Video file]. Retrieved from https://www.youtube.com/watch?v=KYGawWpiDOE
Renamed: Plate Tectonics: Reshaping the Ground Below Us – ID 19738
WISE is theoretically based on the Scaffolded Knowledge Integration network (SKI) which includes the following four tenets: 1) accessibility to science, 2) making knowledge visible, 3) learning from others and 4) promoting autonomy (Linn, Clark, & Slotta, 2003). In piecing together a unit study for middle school students (grade 6-8), incorporating these four tenets of SKI into the non-technology based areas of learning is intentional to enhance visibility of knowledge and opportunities for peer review and critique. The WISE Plate Tectonic project is being used as a final assignment within a geology unit based on the structure of the earth, the surface of the earth, plate tectonics, and earthquakes and volcanoes. A few authorship changes have been made to the Plate Tectonic project mainly to include a Canadian perspective. These changes include the addition of Canadian map images showing placement of volcanoes, earthquakes and mountain ranges, along with appropriate text. As well, small alterations have occurred in the subtitles of the lesson outline.
The geology unit includes three resources, two non-technology based texts and one project from WISE. The two non-technology based resources that have been chosen are faith-based resources as the school that I work for is an independent religious school. The Geology Book by Dr. John D. Morris is a textbook, but includes detailed and colourful diagrams illustrating the inside of the earth and side views of how the earth’s surface is formed. A Child’s Geography: Volume 1 by Ann Voskamp includes conversational style writing, hands-on activities, real world extensions and a living book list of extension readings. Talking about thinking is incorporated into both of these resources through oral narrations, discussions and the sharing of written work for peer critique. Learning is made visible through notebooking and hands-on model making.The table below illustrates the order of the unit with how resources will be completed in conjunction with each other.
In designing this unit, the four tenets of SKI are intentionally incorporated in addition to, or through the use of each resource. These four tenets provide a framework for students to work through an inquiry process as described in Inquiry and the National Educational Standards with students thinking “about what we know, why we know, and how we have come to know” (Center for Science, Mathematics, and Engineering Education, 2000, p.6). Linn, Clark and Slotta (2013) more specifically define inquiry “as engaging students in the intentional process of diagnosing problems, critiquing experiments, distinguishing alternatives, planning investigations, revising views, researching conjectures, searching for information, constructing models, debating with peers, communicating to diverse audiences, and forming coherent arguments” (p.518). The following table analyses each of the three resources and aligns them with the four tenets of SKI as well as the inquiry processes described by Linn, Clark and Slotta in the above definition.
Scaffolded Integration Knowledge Network
Processes of Inquiry
Geology Unit Resource
Accessibility to Science – {content, relevancy, real-life application}
Diagnosing problems
Planning investigations
Revising views
Researching conjectures
Searching for information
WISE Plate Tectonics
Researching conjectures
Searching for information
Revising views
The Geology Book
Revising views
Researching conjectures
Searching for information
A Child’s Geography
Making Thinking Visible
Constructing models
Communicating to diverse audiences
Forming coherent arguments
WISE Plate Tectonics
Constructing models
The Geology Book
Constructing models
A Child’s Geography
Learning From Others
Diagnosing problems
Critiquing experiments
Distinguishing alternatives
Revising views
Debating with peers
WISE Plate Tectonics
Critiquing by peers
Revising views
The Geology Book
Critiquing by peers
Revising views
A Child’s Geography
Promote Autonomy
Diagnosing problems
Critiquing experiments
Distinguishing alternatives
Planning investigations
Revising views
Researching conjectures
Searching for information
WISE Plate Tectonics
Researching conjectures
Searching for information
Critiquing by peers
Revising views
The Geology Book
Researching conjectures
Searching for information
Critiquing by peers
Revising views
A Child’s Geography
Center for Science, Mathematics, and Engineering Education. (2000) Inquiry and the national science education standards. Washington, DC: Author.
Linn, M. C., Clark, D. and Slotta, J. D. (2003), WISE design for knowledge integration . Sci. Ed., 87: 517–538. doi:10.1002/sce.10086
When considering student misconceptions and conceptual challenges in science and mathematics, the use of digital technology can offer educators a tool through which to challenge previously acquired misconceptions. Initially, educators may choose to take an approach based on Vygotsky’s zone of proximal development by developing an online multiple choice test consisting of specific questions designed to reveal the common misconceptions that students bring to the learning environment. Once misconceptions are determined, technology may be used to reshape students’ conceptual ideas through varied presentation and inquiry tools. Keeping in mind Gardner’s theory of multiple intelligences, varied digital technology approaches to exploring a concept can be chosen that focus on oral, auditory, visual, interactive and constructive ways of learning.
WISE (Web-based Inquiry Science Environment) is an online science space that was explored from a constructivist perspective in ETEC 510: Design of Technology Supported Learning Environments. This digital technology tool is a space that students are required to be critical thinkers, problem solvers and role players. As students work through their relevant inquiry, they are encouraged to collaborate through problem solving and anonymous critiquing. Frequent feedback is available from the teacher as the students move through interactive activities to construct their final solution. Although I have not used this site as an educator, I continue to hold it in the back of my mind as an “ideal” in design for effective use of digital technology due to its collaborative, critical thinking and constructivist focus.
As a general mathematics and science teacher for elementary grade levels, the process of exploring, analyzing and synthesizing the four foundational TELEs presented in this course has been transformational in my development of TPCK. Initially, the importance of CK (Schulman, 1986), and my self-diagnosed lack of CK, was convicting as I tend towards growing in pedagogical ideas and creative ways of implementing them. To further this conviction, my understanding of inquiry processes and the intricate role that the teacher facilitates in conducting a community of inquiry began to become clearer throughout the readings and discussions of Module B. Skillful inquiry instruction requires a facilitator who is saturated in CK, being equipped to prepare, respond, question, prompt, and guide with carefully considered PK. At this time, I am challenged as an educator to begin with one brave adventure in mathematics using an anchored instructional approach, and another brave lesson in physical science using a T-GEM approach. I am certain that I will be generating, evaluating and modifying all along the way. 
