Probabilistic Computers (So Quantum Computers) Are More Rigorously Powerful Than Traditional Computers, and Derandomization

Abstract

In this paper, we extend the techniques used in our previous work to show that there exists a probabilistic Turing machine running within time O(nk) for all k∈N1 accepting a language Ld that is different from any language in P, and then further to prove that Ld∈BPP, thus separating the complexity class BPP from the class P (i.e., P⊂neqqBPP). Since the complexity class BQP of bounded error quantum polynomial-time contains the complexity class BPP (i.e., BPP⊂eqBQP), we thus confirm the widespread-belief conjecture that quantum computers are rigorously more powerful than traditional computers (i.e., P⊂neqqBQP). As an important consequence of the above results, we disprove the Extended Church-Turing Thesis. Furthermore, we also show that (1): P⊂neqqRP; (2): P⊂neqq co-RP; (3): P⊂neqqZPP. Previously, whether the above relations hold or not were long-standing open questions in complexity theory. Meanwhile, the result of P⊂neqqBPP shows that randomness plays an essential role in probabilistic algorithm design. In particular, we go further to show that (4): The number of random bits used by any probabilistic algorithm that accepts the language Ld can not be reduced to O( n); (5): There exists no efficient (complexity-theoretic) pseudorandom generator (PRG). G:\0,1\O( n)→ \0,1\n; (6): There exists no quick HSG H:k(n)→ n such that k(n)=O( n).