Abstract
We investigate notions of randomness in the space \({{\mathcal C}(2^{\mathbb N})}\) of continuous functions on \({2^{\mathbb N}}\). A probability measure is given and a version of the Martin-Löf test for randomness is defined. Random \({\Delta^0_2}\) continuous functions exist, but no computable function can be random and no random function can map a computable real to a computable real. The image of a random continuous function is always a perfect set and hence uncountable. For any \({y \in 2^{\mathbb N}}\), there exists a random continuous function F with y in the image of F. Thus the image of a random continuous function need not be a random closed set. The set of zeroes of a random continuous function is always a random closed set.
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Research partially supported by the National Science Foundation grants DMS 0532644 and 0554841 and 00652732. Thanks also to the American Institute of Mathematics for support during 2006 Effective Randomness Workshop; Remmel partially supported by NSF grant 0400307; Weber partially supported by NSF grant 0652326. Preliminary version published in the Third International Conference on Computability and Complexity in Analysis, Springer Electronic Notes in Computer Science, 2006.
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Barmpalias, G., Brodhead, P., Cenzer, D. et al. Algorithmic randomness of continuous functions. Arch. Math. Logic 46, 533–546 (2008). https://doi.org/10.1007/s00153-007-0060-4
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DOI: https://doi.org/10.1007/s00153-007-0060-4