Objectivity (science)

Objectivity in science is an attempt to uncover truths about the natural world by eliminating personal biases, emotions, and false beliefs.[1] It is often linked to observation as part of the scientific method. It is thus intimately related to the aim of testability and reproducibility. To be considered objective, the results of measurement must be communicated from person to person, and then demonstrated for third parties, as an advance in a collective understanding of the world. Such demonstrable knowledge has ordinarily conferred demonstrable powers of prediction or technology.

The problem of philosophical objectivity is contrasted with personal subjectivity, sometimes exacerbated by the overgeneralization of a hypothesis to the whole. E.g. Newton's law of universal gravitation appears to be the norm for the attraction between celestial bodies, but it was later superseded by the more general theory of relativity.

History

The scientific method was argued for by Enlightenment philosopher Francis Bacon, rose to popularity with the discoveries of Isaac Newton and his followers, and continued into later eras. In the early eighteenth century, there existed an epistemic virtue in science which has been called truth-to-nature.[1]:55–58 This ideal was practiced by Enlightenment naturalists and scientific atlas-makers, and involved active attempts to eliminate any idiosyncrasies in their representations of nature in order to create images thought best to represent "what truly is."[1]:59–60[2]:84–85 Judgment and skill were deemed necessary in order to determine the "typical", "characteristic", "ideal", or "average."[2]:87 In practicing truth-to-nature naturalists did not seek to depict exactly what was seen; rather, they sought a reasoned image.[1]:98

In the latter half of the nineteenth century objectivity in science was born when a new practice of mechanical objectivity appeared.[1]:121 "'Let nature speak for itself' became the watchword of a new brand of scientific objectivity."[2]:81 It was at this time that idealized representations of nature, which were previously seen as a virtue, were now seen as a vice.[1]:120 Scientists began to see it as their duty to actively restrain themselves from imposing their own projections onto nature.[2]:81 The aim was to liberate representations of nature from subjective, human interference and in order to achieve this scientists began using self-registering instruments, cameras, wax molds, and other technological devices.[1]:121

In the twentieth century trained judgment[1]:309 supplemented mechanical objectivity as scientists began to recognize that, in order for images or data to be of any use, scientists needed to be able to see scientifically; that is, to interpret images or data and identify and group them according to particular professional training, rather than to simply depict them mechanically.[1]:311–314 Since the latter half of the nineteenth century, objectivity has come to involve a combination of trained judgment and mechanical objectivity.

Objectivity in measurement

Another methodological aspect is the avoidance of bias, which can involve cognitive bias, cultural bias, or sampling bias. Methods for avoiding or overcoming such biases include random sampling and double-blind trials.[3] However, objectivity in measurement can be unobtainable in certain circumstances. Even the most quantitative social sciences such as economics employ measures that are constructs (conventions, to employ the term coined by Pierre Duhem).

The role of the scientific community

Various scientific processes, such as peer reviews, the discussions at scientific conferences, and other meetings where scientific results are presented, are part of a social process whose purpose is to strengthen the objective aspect of the scientific method.

Next to unintentional and systematic error, there is always the possibility of deliberate misrepresentation of scientific results, whether for gain, fame, or ideological motives. When such cases of scientific fraud come to light, they usually give rise to an academic scandal, but it is unknown how much fraud goes undiscovered. For important results, other groups will try to repeat the experiment. If they consistently fail, they will bring these negative results into the scientific debate.

Critiques of scientific objectivity

A critical argument on scientific objectivity and positivism is that all science has a degree of interpretivism.[4]:29 In the 1920s, Percy Bridgman's The Logic of Modern Physics and the operationalism presented was centered in such recognition.[4]:29

Thomas Kuhn's The Structure of Scientific Revolutions

Based on a historical review of the development of certain scientific theories in his book, The Structure of Scientific Revolutions, scientist and historian Thomas Kuhn raised some philosophical objections to claims of the possibility of scientific understanding being truly objective. In Kuhn's analysis, scientists in different disciplines organise themselves into de facto paradigms within which scientific research is done, junior scientists are educated, and scientific problems are determined.[5]

When observational data arises which appears to contradict or falsify a given scientific paradigm, scientists within that paradigm historically have not immediately rejected it, as Karl Popper's philosophical theory of falsificationism would have them do. Instead they have gone to considerable lengths to resolve the apparent conflict without rejecting the paradigm. Through ad hoc variations to the theory and sympathetic interpretation of the data, supporting scientists will resolve the apparent conundrum. In extreme cases, they may ignore the data altogether. Thus, the failure of a scientific paradigm will go into crisis when a significant portion of scientists working in the field lose confidence in it. The corollary of this observation is that a paradigm is contingent on the social order amongst scientists at the time it gains ascendancy.[5]

Kuhn's theory has been criticised by scientists such as Richard Dawkins and Alan Sokal as presenting a relativist view of scientific progress.[6] [7]In a postscript to the third edition of his book, Kuhn denied being a relativist.

Donna Haraway's Situated Knowledges

In Situated Knowledges: The Science Question in Feminism and the Privilege of Partial Perspective (1988), Donna Haraway argues that objectivity in science and philosophy is traditionally understood as a kind of disembodied and transcendent "conquering gaze from nowhere."[8]:581 She argues that this kind of objectivity, in which the subject is split apart and distanced from the object, is an impossible "illusion, a god trick."[8]:583–587 She demands a re-thinking of objectivity in such a way that, while still striving for "faithful accounts of the real world,"[8]:579 we must also acknowledge our perspective within the world. She calls this new kind of knowledge-making "situated knowledges." Objectivity, she argues, "turns out to be about particular and specific embodiment and ... not about the false vision promising transcendence of all limits and responsibility". This new objectivity, "allows us to become answerable for what we learn how to see."[8]:581–583 Thus, Haraway is not only critiquing the idea that objectivity as we have long understood it is possible; she is also arguing that if we continue to approach knowledge-making in this way, then we wash our hands of any responsibility for our truth claims. In contrast, she argues, approaching knowledge-making from an embodied perspective forces us to take responsibility.

See also

References

  1. Daston, Lorraine; Galison, Peter (2010). Objectivity. Zone Books. ISBN 9781890951795. Archived from the original on 2017-05-22. Retrieved 2015-07-23.
  2. Daston, Lorraine; Galison, Peter (Autumn 1992). "The Image of Objectivity" (PDF). Representations. 0 (40): 81–128. doi:10.2307/2928741. JSTOR 2928741.
  3. O'Leary, Zina (2004-06-09). The Essential Guide to Doing Research. SAGE Publications. ISBN 9780761941996.
  4. Gach, John; Wallace, Edwin R. (2010). History of Psychiatry and Medical Psychology: With an Epilogue on Psychiatry and the Mind-Body Relation. Springer Science & Business Media. ISBN 9780387347080.
  5. Kuhn, Thomas S. (1962), The Structure of Scientific Revolutions (PDF), The University of Chicago Press, archived from the original (PDF) on 20 October 2014, retrieved 14 November 2014
  6. Dawkins, Richard (2000). "Hall Of Mirrors".
  7. Sokal, Alan; Bricmont, Jean (1999). "Intermezzo: Epistemic Relativism in The Philosophy of Science". Fashionable Nonsense: Postmodern Intellectuals' Abuse of Science. USA: Picador USA. ISBN 0312204078.
  8. Haraway, Donna (Autumn 1988). "Situated Knowledges: The Science Question in Feminism and the Privilege of Partial Perspective" (PDF). Feminist Studies. 14 (3): 575–599. doi:10.2307/3178066. JSTOR 3178066. Archived from the original (PDF) on 2017-08-29. Retrieved 2015-07-23.

Sources

  • Dawkins, Richard. (2003). A Devil's Chaplain: Selected essays. Phoenix.
  • Kuhn, Thomas. (1962). The structure of scientific revolutions. University of Chicago Press, 3rd Ed., 1996.
  • Latour, Bruno. (1987). Science in Action. Cambridge, Mass: Harvard University Press.
  • Polanyi, M. (1958). Personal knowledge, towards a post-critical philosophy. London: Routledge.
  • Sokal, Alan & Bricmont, Jean. (1999). Intellectual Impostures: Postmodern philosophers' abuse of science. London: Profile Books.

Further reading

  • Gaukroger, S. (2001). Objectivity, History of. IN: Smelser, N. J. & Baltes, P. B. (eds.) International Encyclopedia of the Social and Behavioral Sciences. Oxford. (pp. 10785–10789).
  • Porter, Theodore M. (1995). Trust in Numbers: The Pursuit of Objectivity in Science and Public Life. Princeton University Press.
  • Restivo, Sal. (20XX). Science, Society, and Values: Toward a Sociology of Objectivity. Lehigh University Press.
  • Reiss, Julian; Sprenger, Jan (6 November 2017) [First published 25 August 2014]. "Scientific Objectivity". In Zalta, Edward N. (ed.). Stanford Encyclopedia of Philosophy (Winter 2017 ed.). Stanford University: The Metaphysics Research Lab. ISSN 1095-5054. Retrieved 31 May 2018.
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