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| title | chunk | source | category | tags | date_saved | instance |
|---|---|---|---|---|---|---|
| Collaboratory | 2/6 | https://en.wikipedia.org/wiki/Collaboratory | reference | science, encyclopedia | 2026-05-05T09:03:22.295395+00:00 | kb-cron |
=== The evolution of the collaboratory === As stated in Chapter 4 of the 50+20 "Management Education for the World" book, "the term collaboratory was first introduced in the late 1980s to address problems of geographic separation in large research projects related to travel time and cost, difficulties in keeping contact with other scientists, control of experimental apparatus, distribution of information, and the large number of participants. In their first decade of use, collaboratories were seen as complex and expensive information and communication technology (ICT) solutions supporting 15 to 200 users per project, with budgets ranging from 0.5 to 10 million USD. At that time, collaboratories were designed from an ICT perspective to serve the interests of the scientific community with tool-oriented computing requirements, creating an environment that enabled systems design and participation in collaborative science and experiments. The introduction of a user-centered approach provided a first evolutionary step in the design philosophy of the collaboratory, allowing rapid prototyping and development circles. Over the past decade the concept of the collaboratory expanded beyond that of an elaborate ICT solution, evolving into a “new networked organizational form that also includes social processes, collaboration techniques, formal and informal communication, and agreement on norms, principles, values, and rules”. The collaboratory shifted from being a tool-centric to a data-centric approach, enabling data sharing beyond a common repository for storing and retrieving shared data sets. These developments have led to the evolution of the collaboratory towards a globally distributed knowledge work that produces intangible goods and services capable of being both developed and distributed around the world using traditional ICT networks. Initially, the collaboratory was used in scientific research projects with variable degrees of success. In recent years, collaboratory models have been applied to areas beyond scientific research and the national context. The wide acceptance of collaborative technologies in many parts of the world opens promising opportunities for international cooperation in critical areas where societal stakeholders are unable to work out solutions in isolation, providing a platform for large multidisciplinary teams to work on complex global challenges. The emergence of open-source technology transformed the collaboratory into its next evolution. The term open-source was adopted by a group of people in the free software movement in Palo Alto in 1998 in reaction to the source code release of the Netscape Navigator browser. Beyond providing a pragmatic methodology for free distribution and access to an end product's design and implementation details, open-source represents a paradigm shift in the philosophy of collaboration. The collaboratory has proven to be a viable solution for the creation of a virtual organization. Increasingly, however, there is a need to expand this virtual space into the real world. We propose another paradigm shift, moving the collaboratory beyond its existing ICT framework to a methodology of collaboration beyond the tool- and data-centric approaches, and towards an issue-centered approach that is transdisciplinary in nature."
== Characteristics and considerations == A distinctive characteristic of collaboratories is that they focus on data collection and analysis. Hence the interest to apply collaborative technologies to support data sharing as opposed to tool sharing. Chin and Lansing (2004) explore the shift of collaboratory development from traditional tool-centric approaches to more data-centric ones, to effectively support data sharing. This means more than just providing a common repository for storing and retrieving shared data sets. Collaboration, Chin and Lansing (2004) state, is driven both by the need to share data and to share knowledge about data. Shared data is only useful if sufficient context is provided about the data such that collaborators may comprehend and effectively apply it. It is therefore imperative, according to Chin and Lansing (2004), to know and understand how data sets relate to aspects of overall data space, applications, experiments, projects, and the scientific community, identifying the critical features or properties among which we can mention:
General data set properties (owner, creation data, size, format); Experimental properties (conditions of the scientific experiment that generated that data); Data provenance (relationship with previous versions); Integration (relationship of data subsets within the full data set); Analysis and interpretation (notes, experiences, interpretations, and knowledge produced) Scientific organization (scientific classification or hierarchy); Task (research task that generated or applies the data set); Experimental process (relationship of data and tasks to the overall process); User community (application of data set to different users). Henline (1998) argues that communication about experimental data is another important characteristic of a collaboratory. By focusing attention on the dynamics of information exchange, the study of Zebrafish Information Network Project (Henline, 1998) concluded that the key challenges in creating a collaboratory may be social rather than technical. “A successful system must respect existing social conventions while encouraging the development of analogous mechanisms within the new electronic forum” (Henline, 1998, p. 69). Similar observations were made in the Computer-supported collaborative learning (CSCL) case study (Cogburn, 2003). The author (Cogburn, 2003) is investigating a collaboratory established for researchers in education and other related domains from United States of America and southern Africa. The main finding was that there have been important intellectual contributions on both sides, although the context was that of a developed country working together with a developing one and there have been social as well as cultural barriers. He further develops the idea that a successful CSCL would need to draw the best lessons learned on both sides in computer-mediated communication (CMC) and computer-supported cooperative work (CSCW). Sonnenwald (2003) conducted seventeen interviews with scientists and revealed important considerations. Scientists expect a collaboratory to “support their strategic plans; facilitate management of the scientific process; have a positive or neutral impact on scientific outcomes; provide advantages and disadvantages for scientific task execution; and provide personal conveniences when collaborating across distances” (Sonnenwald, 2003, p. 68). Many scientists looked at the collaboratory as means to achieve strategic goals that were organizational and personal in nature. Other scientists anticipated that the scientific process would speed up when they had access to the collaboratory.