| Social Construction Of Technology |
Article Index for Social |
Website Links For Social |
Information AboutSocial Construction Of Technology |
| CATEGORIES ABOUT SOCIAL CONSTRUCTION OF TECHNOLOGY | |
| history of technology | |
| science and technology studies | |
| sociology of scientific knowledge | |
| social constructionism | |
|
SCOT draws on work done in the constructivist school of the Sociology Of Scientific Knowledge , and its subtopics include Actor-network Theory (a branch of the Sociology Of Science And Technology ) and historical analysis of sociotechnical systems Thomas P. Hughes . Leading adherents of SCOT include Wiebe Bijker , Trevor Pinch and Bruno Latour . SCOT holds that those who seek to understand the reasons for acceptance or rejection of a technology should look to the social world. It is not enough, according to SCOT, to explain a technology's success by saying that it is "the best" -- researchers must look at how the criteria of being "the best" is defined and what groups and stakeholders participate in defining it. In particular, they must ask who defines the technical criteria by which success is measured, why technical criteria are defined in this way, and who is included or excluded. SCOT is not only a theory, but also a methodology: it formalizes the steps and principles to follow when one wants to analyze the causes of technological failures or successes. LEGACY OF THE STRONG PROGRAMME IN THE SOCIOLOGY OF SCIENCE At the point of its conception, the SCOT approach was partly motivated by the ideas of the Strong Programme in the Sociology of Science (Bloor 1973). In their seminal article, Pinch and Bijker refer to the ''Principle of Symmetry'' as the most influential tenet of the Sociology of Science, which should be applied in historical and sociological investigations of technology as well. It is strongly connected to Bloor's theory of social causation. Symmetry The ''Principle of Symmetry'' holds that in explaining the origins of scientific beliefs, that is, assessing the success and failure of models, theories, or experiments, the historian / sociologist should deploy the same ''kind'' of explanation in the cases of success as in cases of failure. When investigating beliefs, researchers should be impartial to the (a posteriori attributed) truth or falsehood of those beliefs, and the explanations should be unbiased. The strong programme adopts a position of relativism or neutralism regarding the arguments that social actors put forward for the acceptance/rejection of any technology. All arguments (social, cultural, political, economic, as well as technical) are to be treated equally. The symmetry principle addresses the problem that the historian is tempted to explain the success of successful theories by referring to their "objective truth", or inherent "technical superiority", whereas s/he is more likely to put forward sociological explanations (citing political influence or economic reasons) only in the case of failures. For example, having experienced the obvious success of the chain-driven bicycle for decades, it is tempting to attribute its success to its "advanced technology" compared to the "primitiveness" of the Penny Farthing , but if we look closely and symmetrically at their history (as Pinch and Bijker do), we can see that at the beginning bicycles were valued according to quite different standards than nowadays. The early adopters (predominantly young, well-to-do gentlemen) valued the speed, the thrill, and the spectacularity of the Penny Farthing - in contrast to the security and stability of the chain-driven Safety Bicycle . Many other social factors (e.g., the contemporary state of urbanism and transport, womens' clothing habits and feminism) have influenced and changed the relative valuations of bicycle models. A weak reading of the ''Principle of Symmetry'' would point out that there often are many competing theories or technologies, which all have the potential to provide slightly different solutions to similar problems. In these cases the sociological factors are those, which tip the balance between them: that's why we should pay equal attention to them. A strong, social constructivist reading would add that even the emergence of the questions or problems to be solved are governed by social determinations, so the Principle of Symmetry is applicable even to the apparently purely technical issues. CORE CONCEPTS Interpretative Flexibility ''Interpretative Flexibility'' means that each technological artifact has different meanings and interpretations for various groups. Bijker and Pinch show that the air tire of the bicycle meant a more convenient mode of transportation for some people, whereas it meant technical nuisances, traction problems and ugly aesthetics to others. Sport cyclists were concerned by the speed reduction caused by the air tire. These alternative interpretations generate different ''problems'' to be solved. Aesthetics, convenience or speed should be priorized? What is the best tradeoff between traction and speed? Relevant Social Groups The most basic relevant groups are the ''users'' and the ''producers'' of the technological artifact, but most often many subgroups can be delineated - users with different socioeconomic status, competing producers, etc. Sometimes there are relevant groups who are neither users, nor producers of the technology - journalists, politicians, civil groups, etc. (Just think of Inter-continental Ballistic Missiles , for example) The groups can be distinguished based on their shared or diverging interpretations of the technology in question. Design Flexibility Just as technologies have different meanings in different social groups, there are always multiple ways of constructing technologies. A design is only a single point in the large field of technical possibilities, reflecting the interpretations of certain relevant groups. Problems and Conflicts The different intepretations often give rise to conflicts between criteria that are hard to resolve technologically (in the case of the bicycle, one such problem was: how can women ride the bicycle decently, in skirt?), or conflicts between the relevant groups (the "Anti-cyclists" lobbied for the banning of the bicycles). Different groups in different societies construct different problems, leading to different designs. The first stage of the SCOT research methodology is to reconstruct the alternative interpretations of the technology, analyze the problems and conflicts these interpretations give rise to, and connect them to the design features of the technological artifacts. The relations between groups, problems, and designs can be visualized in diagrams. Closure Over time, as technologies are developed, the interpretative and design flexibility collapse through closure mechanisms. Two examples of closure mechanisms: #Rhetorical Closure: When social groups ''see'' the problem as being solved, the need for alternative designs diminishes. This is often the result of advertising. #Redefinition of the Problem: A design standing in the focus of conflicts can be stabilized by inventing a new ''problem'', which is solved by this very design. The aesthetic and technical problems of the air tire diminished, as the technology advanced to the stage where air tire bikes started to win the bike races. Tires were still considered cumbersome and ugly, but they provided a solution to the "speed problem", and this overrode previous concerns. Closure is not permanent. New social groups may form and reintroduce interpretative flexibility, causing a new round of debate or conflict about a technology. (For instance, in the 1890s automobiles were seen as the "green" alternative, a cleaner environmentally-friendly technology, to horse-powered vehicles; by the 1960s, new social groups had introduced new interpretations about the environmental effects of the automobile) The second stage of the SCOT methodology is to show how closure is achieved. Relating the content of the technological artifact to the wider sociopolitical milieu This is the third stage of the SCOT methodology, but the seminal article of Pinch and Bijker does not proceed to this stage. Many other historians and sociologists of technology nevertheless do. For example, Paul N. Edwards shows in his book "The Closed World: Computers and the Politics of Discourse in Cold War America" {Link without Title} the strong relations between the political discourse of the Cold War and the computer designs of this era. CRITICISM In 1993, Langdon Winner published an influential critique of SCOT entitled "Upon Opening the Black Box and Finding it Empty: Social Constructivism and the Philosophy of Technology." In it, he raises a few problems with social constructivism: # It explains how technologies arise, but ignores the effects of the technology after the fact. # It is a social construction of knowledge in itself, subject to the same limitations as it postulates ("Who says what are relevant social groups and social interests?") # It disregards dynamics which are not due to its "preferred conceptual strawman: technological determinism." The core disagreement lies in the fact that Winner is a ''technological determinist'', whose concerns are the inverse of social constructivists, namely: how the realization of technological possibilities transform society? Other critics include Stewart Russell with his letter in the journal " Social Studies Of Science " titled "The Social Construction of Artefacts: A Response to Pinch and Bijker" REFERENCES
SEE ALSO
EXTERNAL LINKS |
|
|