Hostname: page-component-848d4c4894-4rdrl Total loading time: 0 Render date: 2024-06-16T07:11:05.206Z Has data issue: false hasContentIssue false
  • English
  • Français

Using Scott Domains to Explicate the Notions of Approximate and Idealized Data

Published online by Cambridge University Press:  01 April 2022

Ronald Laymon
Ronald Laymon*
Affiliation:
Department of Philosophy The Ohio State University
Get access Rights & Permissions [Opens in a new window]

Abstract

This paper utilizes Scott domains (continuous lattices) to provide a mathematical model for the use of idealized and approximately true data in the testing of scientific theories. Key episodes from the history of science can be understood in terms of this model as attempts to demonstrate that theories are monotonic, that is, yield better predictions when fed better or more realistic data. However, as we show, monotonicity and truth of theories are independent notions. A formal description is given of the pragmatic virtues of theories which are monotonic. We also introduce the stronger concept of continuity and show how it relates to the finite nature of scientific computations. Finally, we show that the space of theories also has the structure of a Scott domain. This result provides an analysis of how one theory can be said to approximate another.

Type
Research Article
Information
Philosophy of Science , Volume 54 , Issue 2 , June 1987 , pp. 194 - 221
Copyright
Copyright © The Philosophy of Science Association

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

Many of the ideas presented here were developed while I was a fellow at the Center for the Philosophy of Science at the University of Pittsburgh. I am very grateful to the past and current directors, Larry Laudan and Nicholas Rescher, for arranging my visit and for providing extremely stimulating accommodations. My research was also supported by a National Science Foundation Scholars Award and by faculty development grants from The Ohio State University. I also want to thank Dana Scott, Stephen Brookes, and David McCarty for their friendly assistance with denotational semantics. The basic idea of this paper, that possible data be conceived as having a formal structure of their own, comes from Suppes 1962. Finally, my thanks go to Ron Giere, Clark Glymour, Robert Kraut, Ilkka Niiniluoto, Bill Harper, and John Worrall for their encouragement and critical advice.

References

REFERENCES

Bell, J. and Slomson, A. (1971), Models and Ultraproducts. Amsterdam: North-Holland.Google Scholar
Cartwright, N. (1983), How the Laws of Physics Lie. Oxford: Clarendon Press.CrossRefGoogle Scholar
Cushing, J. T. (1984), “The Spring-Mass System Revisited”, American Journal of Physics 52: 925–933.CrossRefGoogle Scholar
Duhem, P. (1962), The Aim and Structure of Physical Theory. Translated by P. Wiener. New York: Atheneum.Google Scholar
van Fraassen, B. (1970), “On the Extension of Beth's Semantics of Physical Theories”, Philosophy of Science 37: 325–339.CrossRefGoogle Scholar
van Fraassen, B. (1980), The Scientific Image. Oxford: Clarendon Press.CrossRefGoogle Scholar
Glymour, C. (1980), Theory and Evidence. Princeton: Princeton University Press.Google Scholar
Haken, H. (1970), “The Semiclassical and Quantum Theories of the Laser”, S. Kay and A. Maitland (eds.), Quantum Optics. London: Academic Press, pp. 201–321.Google Scholar
Jeans, J. (1940), An Introduction to the Kinetic Theory of Gases. Cambridge: Cambridge University Press.Google Scholar
Laymon, R. (1978a), “Feyerabend, Brownian Motion, and the Hiddenness of Refuting Facts”, Philosophy of Science 44: 225–247.Google Scholar
Laymon, R. (1978b), “Newton's Experimentum Crucis and the Logic of Idealization and Theory Refutation”, Studies in History and Philosophy of Science 9: 5177.CrossRefGoogle Scholar
Laymon, R. (1980), “Independent Testability: The Michelson-Morley and Kennedy-Thorn-dike Experiments”, Philosophy of Science 47: 137.CrossRefGoogle Scholar
Laymon, R. (1982), “Scientific Realism and the Hierarchical Counterfactual Path from Data to Theory”, in Asquith, P. and Nickles, T. (eds.), PSA 1982: Proceedings, Philosophy of Science Association, vol. 1. East Lansing: Philosophy of Science Association, pp. 107–121.Google Scholar
Laymon, R. (1983), “Newton's Demonstration of Universal Gravitation and Philosophical Theories of Confirmation”, in Earman, J. (ed.), Minnesota Studies in the Philosophy of Science, vol. x. Minneapolis: University of Minnesota Press, pp. 179–199.Google Scholar
Laymon, R. (1985), “Idealizations and the Testing of Theories by Experimentation”, in Achinstein, P. and Hannaway, O. (eds.), Observation, Experiment and Hypothesis in Modern Science. Boston: MIT Press and Bradford Books, pp. 147–173.Google Scholar
Levi, I. (1967), Gambling with Truth. New York: Alfred Knopf.Google Scholar
Niiniluoto, I. (1978), “Truthlikeness: Comments on Recent Discussion”, Synthese 38: 281–329.CrossRefGoogle Scholar
Niiniluoto, I. (1985), “The Significance of Verisimilitude”, in Asquith, P. and Kitcher, P. (eds.), PSA 1984: Proceedings of the 1984 Biennial Meeting of the Philosophy of Science Association, vol. 2. East Lansing: Philosophy of Science Association, pp. 591–613.Google Scholar
Scott, D. (1970), Outline of a Mathematical Theory of Computation. Technical Monograph PRG-2, Oxford University Computing Laboratory.Google Scholar
Scott, D. (1976), “Data Types as Lattices”, SIAM Journal on Computing 5: 522–587.CrossRefGoogle Scholar
Scott, D. (1981), Lectures on a Mathematical Theory of Computation. Technical Monograph PRG-19, Oxford University Computing Laboratory.Google Scholar
Scott, D. (1982), “Domains for Denotational Semantics”, in Nielson, M. and Schmidt, E. M. (eds.), Automata, Languages and Programming. New York: Springer-Verlag, pp. 577–613.Google Scholar
Smith, J. (1984), “What is Wrong with Verisimilitude”, Philosophy Research Archives 10: 511–541.CrossRefGoogle Scholar
Stoy, J. (1977), Denotational Semantics: The Scott-Strachey Approach to Programming Language Theory. Cambridge: MIT Press.Google Scholar
Suppes, P. (1962), “Models of Data”, in Nagel, E., Suppes, P., and Tarski, A. (eds.), Logic, Methodology and Philosophy of Science. Stanford: Stanford University Press, pp. 252–261.Google Scholar
Thomson, W. (1901), Baltimore Lectures on Molecular Dynamics and the Wave Theory of Light. London: C. J. Clay.Google Scholar
Worrall, J. (1984), “An Unreal Image”, British Journal for the Philosophy of Science 35: 6580.CrossRefGoogle Scholar