Lower bounds on the redundancy in computations from random oracles via betting strategies with restricted wagers

Abstract

The Kucera-G\'acs theorem is a landmark result in algorithmic randomness asserting that every real is computable from a Martin-L\"of random real. If the computation of the first n bits of a sequence requires n+h(n) bits of the random oracle, then h is the redundancy of the computation. Kucera implicitly achieved redundancy n n while G\'acs used a more elaborate coding procedure which achieves redundancy n n. A similar upper bound is implicit in the later proof by Merkle and Mihailovi\'c. In this paper we obtain strict optimal lower bounds on the redundancy in computations from Martin-L\"of random oracles. We show that any nondecreasing computable function g such that Σn 2-g(n)=∞ is not a general upper bound on the redundancy in computations from Martin-L\"of random oracles. In fact, there exists a real X such that the redundancy g of any computation of X from a Martin-L\"of random oracle satisfies Σn 2-g(n)<∞. Moreover, the class of such reals is comeager and includes a 02 real as well as all weakly 2-generic reals. This excludes many slow growing functions such as n from bounding the redundancy in computations from random oracles for a large class of reals. On the other hand it was recently shown that if Σn 2-g(n)<∞ then g is a general upper bound for the redundancy in computations of any real from some Martin-L\"of random oracle. Our results are obtained as an application of a theory of effective betting strategies with restricted wagers which we develop.