Knowledge-building community model: Difference between revisions

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To measure increase in scientific thinking, Jianwei Zhang et al. (2007) present a table of research questions and analysis that we reproduced in summarized form:
To measure increase in scientific thinking, Jianwei Zhang et al. (2007) present a table of research questions and analysis that we reproduced in summarized form:


 
{| class="wikitable"
 
! Dynamics !! Specific questions !! Analyses !! Expected performances
Dynamics
|-
 
| Idea improvement || How do questions and ideas evolve and refine over time ? || Trace the change of student's ideas. || Students shift toward a more scientific view.
Specific questions
|-
 
| Real ideas, authentic problems || How are real-world empirical data used ? || Use of empirical data as evidence on quality of ideas. || Students bring valuable data into the discourse and make sense of them.
Analyses
|-
 
| Community knowledge || How do individual contributions spread and how are they used ? || Analyze contributions to the work of others and related knowledge gains. || Students interact in a way that supports conceptual advancement.
Expected performances
|-
 
| Constructive use of authoritative sources || What are the patterns of their use ? || Use of expert resources. || Students integrate expert and go beyond given information to generate and improve their ideas.
Idea improvement
| Overall || Overal measure of knowledge gains || Pre- and post-test comparisons; analyses of student portfolios. Correlations. || Improvement of performance pre- to post-test; Students’ portfolio notes reflect high levels of scientificness and epistemic complexity. Indicators of the dynamics correlate with quality of ideas in portfolio notes.
 
|}
How do questions and ideas evolve and refine over time ?
 
Trace the change of student's ideas.
 
 
Students shift toward a more scientific view.
 
Real ideas, authentic problems
 
How are real-world empirical data used ?
 
Use of empirical data as evidence on quality of ideas.
 
Students bring valuable data into the discourse and make sense of them.
 
Community knowledge
 
How do individual contributions spread and how are they used ?
 
Analyze contributions to the work of others and related knowledge gains.
 
Students interact in a way that supports conceptual advancement.
 
Constructive use of authoritative sources
 
What are the patterns of their use ?
 
Use of expert resources.
 
Students integrate expert and go beyond given information to generate and improve their ideas.
 
Overall
 
Overal measure of knowledge gains
 
Pre- and post-test comparisons; analyses of student portfolios. Correlations.
 
 
Improvement of performance pre- to post-test; Students’ portfolio notes reflect high levels of scientificness and epistemic complexity. Indicators of the dynamics correlate with quality of ideas in portfolio notes.


==Examples==
==Examples==

Revision as of 16:09, 27 June 2008

Definition

We define Knowledge-building community model is a socio-constructivist pedagogic strategy developed by what we can call the "Toronto school". that emphasized instructional design models that focus on a combination of situated learning, writing-to-learn, knowledge building, community, etc. It does have points in common with inquiry-based learning, i.e. the idea that learners should create knowledge through collective and collaborative inquiry. There is also a relation to transformative pedagogy.

Bereiter and Scardamalia believe a knowledge-building community should be modeled after scientific research centers, where “problem redefinition at increasingly high levels is the goal, based on a fundamentally social process. Researchers benefit from the advances of others, with continual interplay of findings, not just among scientists working concurrently but from generation to generation.”(1994). Knowledge-building communities support discourses that aim to advance the knowledge of the members collectively, while supporting individual growth with the aim of producing new experts and extending expertise within the community's domain.

A KB community can engage in collecting information, supporting discourse and exchanges, encouraging a social and professional network of learners and experts and making the knowledge acquired collectively available for future use. That even children in elementary school levels can engage in knowledge-building makes the process accessible to all levels of education.

Bereiter and Scardamalia's knowledge-building model for educational contexts suggests a way to organize instruction so that student initiated contributions to the collective knowledge and peer evaluation of knowledge produced is possible. Knowledge forum is their technological response to the needs of building a KB community. At the center is support for "knowledge-building discourse".

Knowledge-building discourse

Knowledge-building discourse has certain characteristics defined by Bereiter and Scardamalia (1994) and outlined here:

  • Focused on problems, not topics: knowledge is advanced through discussion and argumentation in the effort to understand concepts and resolve discrepancies.
  • Decentralized, open knowledge building, with a focus on collective knowledge: through constructive social interactions with others engaged in similar or related problems.
  • More knowledgeable members are engaged in the knowledge-building process, but do not delineate the limits of investigation.
  • Less knowledgeable members' participation is valued as it determines the gaps, inadequacies, difficulties in the knowledge being created that can demand a clarification of ideas by the 'experts'.
  • Engages a broader knowledge community than that involved in the current local problem, bringing in views from the outside.
  • Makes for a "second order environment" (one where the one's adaption to the environment changes the environment itself) where one's contributions can determine what contributions will follow, thus changing the direction of the discourse and the knowledge constructed.

These characteristics are built into the framework of CSILE designed as “an enabling technology for knowledge-building discourse.”

A summarizing excerpt from the poster session "Sustaining knowledge building communities: E-learning and knowledge building environments" at an ikit.org event in 2004

Sustaining knowledge building communities online requires the creation of electronic environments that support both formal and informal learning, and capture significant tasks and activities that are central to the day-to-day work of the participants. These environments must provide supports for real world activities and learning, while providing the potential for something more. That something more is knowledge building, or the production and continual improvement of ideas of value to a community (Scardamalia & Bereiter, 2003). Knowledge building is emergent; an environment that supports it must evolve from the contributions of team members and demonstrate collective knowledge advances (Scardamalia, in press).

The instructional design model

The Toronto school advocates a model that differs radically from the current trend of strong scenarisation that we can find in various schools of thought in CSCL or learning design. To state it bluntly, modern learning-design and CSCL is about filling in forms and acquiring existing beliefs and such these approaches are not that different from very traditional instructional systems design.

The model is somewhat related to the inquiry-based learning. The major difference is that advanced teachers not necessarily follow a rigid inquiry circle, but rather opportunistically (in the sense of artificial intelligence planning vocabulary) guide the process. Beginning teachers however, can be encouraged to follow a more structure model. Knowledge building is not unguided (radical constructivist) discovery learning, since the teacher does play an important role to insure that learning activities lead to results.

Research approaches and tools

Recent versions of knowledge forum have built-in data-collection and analysis tools. Most Toronto school research can probably be situated in the design-based research tradition founded by Ann Brown in the early 1990s.

To measure increase in scientific thinking, Jianwei Zhang et al. (2007) present a table of research questions and analysis that we reproduced in summarized form:

Dynamics Specific questions Analyses Expected performances
Idea improvement How do questions and ideas evolve and refine over time ? Trace the change of student's ideas. Students shift toward a more scientific view.
Real ideas, authentic problems How are real-world empirical data used ? Use of empirical data as evidence on quality of ideas. Students bring valuable data into the discourse and make sense of them.
Community knowledge How do individual contributions spread and how are they used ? Analyze contributions to the work of others and related knowledge gains. Students interact in a way that supports conceptual advancement.
Constructive use of authoritative sources What are the patterns of their use ? Use of expert resources. Students integrate expert and go beyond given information to generate and improve their ideas. Overall Overal measure of knowledge gains Pre- and post-test comparisons; analyses of student portfolios. Correlations. Improvement of performance pre- to post-test; Students’ portfolio notes reflect high levels of scientificness and epistemic complexity. Indicators of the dynamics correlate with quality of ideas in portfolio notes.

Examples

  • This wiki (to some extent only, i.e. Daniel K. Schneider believes that he learnt something about educational technology writing and linking concepts)
  • social software websites like built with tools like ELGG (e.g. [1] or [2]) may other partial implementations of this model).
  • Most "strong" examples can be found in various knowledge forum websites and that are usually not open to the public.
  • KP-LAB (A EC project focusing on creating a learning system aimed at facilitating innovative practices of sharing, creating and working with knowledge in education and workplaces. 2006+).

Technology

  • CSILE and Knowledge Forum
  • Wikis, in particular sophisticated wikis like Mediawiki on which this one is based
  • C3MS and other kinds of portalware
  • LMSs (by repurposing the way they are intended to be used !).

Links

References

  • Bereiter, C. (2002). Education and Mind in the Knowledge Age (Second ed.): Lawrence Erlbaum Associates.
  • Bereiter, C., & Scardamalia, M. (2003). Learning to work creatively with knowledge. In E. De Corte, L. Verschaffel, N. Entwistle, & J. van Merriënboer (Eds.), Unravelling basic components and dimensions of powerful learning environments. EARLI Advances in Learning and Instruction Series. Pergamon. PDF Reprint
  • Bereiter, C., Scardamalia, M., Cassells, C., & Hewitt, J. (1997). Postmodernism, knowledge building, and elementary science. Elementary School Journal. (97) 4, 329-340. PDF Reprint
  • Hakkarainen & De Jong, Toward practices of knowledge building. (symposium). Proceedings of the 8th European biennial meeting for research on learning and instruction, (Göteborg, Sweden), 1999.
  • Scardamalia, M., & Bereiter, C. (1994). Computer support for knowledge-building communities. The Journal of the Learning Sciences, 3(3), 265-283. [3]
  • Scardamalia, M. (2002). Collective cognitive responsibility for the advancement of knowledge. In B. Smith (Ed.), Liberal education in a knowledge society (pp. 67-98). Chicago: Open Court. PDF Reprint
  • Scardamalia, M., & Bereiter, C. (2003). Knowledge Building. In J. W. Guthrie (Ed.), Encyclopedia of Education, Second Edition (pp.). New York: Macmillan Reference, USA. PDF Reprint
  • Swan, K., Shea, P., Fredericksen, E., Pickett, A, Pelz, W. & Maher, G. (2000). “Building knowledge building communities: consistency, contact and communication in the virtual classroom.” Journal of Educational Computing Research, 23(4), 389-413.
  • Zhang, Jianwei; Marlene Scardamalia, Mary Lamon, Richard Messina and Richard Reeve (2007). Socio-cognitive dynamics of knowledge building in the work of 9- and 10-year-olds, ETR&D, 55 (2), 117.145 http://dx.doi.org/10.1007/s11423-006-9019-0.