Natural halting probabilities, partial randomness, and zeta functions
We introduce the zeta number, natural halting probability, and natural complexity of a Turing
machine and we relate them to Chaitin's Omega number, halting probability, and program-
size complexity. A classification of Turing machines according to their zeta numbers is
proposed: divergent, convergent, and tuatara. We prove the existence of universal
convergent and tuatara machines. Various results on (algorithmic) randomness and partial
randomness are proved. For example, we show that the zeta number of a universal tuatara …
machine and we relate them to Chaitin's Omega number, halting probability, and program-
size complexity. A classification of Turing machines according to their zeta numbers is
proposed: divergent, convergent, and tuatara. We prove the existence of universal
convergent and tuatara machines. Various results on (algorithmic) randomness and partial
randomness are proved. For example, we show that the zeta number of a universal tuatara …
We introduce the zeta number, natural halting probability, and natural complexity of a Turing machine and we relate them to Chaitin’s Omega number, halting probability, and program-size complexity. A classification of Turing machines according to their zeta numbers is proposed: divergent, convergent, and tuatara. We prove the existence of universal convergent and tuatara machines. Various results on (algorithmic) randomness and partial randomness are proved. For example, we show that the zeta number of a universal tuatara machine is c.e. and random. A new type of partial randomness, asymptotic randomness, is introduced. Finally we show that in contrast to classical (algorithmic) randomness—which cannot be naturally characterised in terms of plain complexity—asymptotic randomness admits such a characterisation.
Elsevier