Abstract
‘Temporal betweenness’ in space-time is defined solely in terms of light sigrfals, using a signalling relation that does not distinguish between the sender and the receiver of a light signal. Special relativity and general relativity are considered separately, because the latter can be treated only locally. We conclude that the (local) coherence of time can be described if we know only which pairs of space-time points are light-connected. Other consequences in the case of special relativity: (1) a categorical axiom system exists in terms of nondirected light connection alone, with neither ‘particle’ nor ‘time order’ as a primitive concept, though we do not actually present the axioms; (2) any concept definable by coordinates is also definable in terms of nondirected light signals if and only if it is invariant under Lorentz transformations, translations, dilations, space reflections, and time reflections; and (3) any transformation of space-time (not necessarily continuous) which preserves nondirected light connection is a product of transformations just listed above. The bulk of the paper is devoted to proving that the definitions we give correspond to their intended interpretations in the usual space-time continua.
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© 1972 Robert W. Latzer, Stanford
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Latzer, R.W. (1972). Nondirected Light Signals and the Structure of Time. In: Suppes, P. (eds) Space, Time and Geometry. Synthese Library, vol 56. Springer, Dordrecht. https://doi.org/10.1007/978-94-010-2650-5_15
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DOI: https://doi.org/10.1007/978-94-010-2650-5_15
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