Abstract
We explore the collapse of “wavefunction” and the measurement of entanglement in the superpositions of hyperspace vectors in classical physical instantaneous-noise-based logic (INBL). We find both similarities with and major differences from the related properties of quantum systems. Two search algorithms utilizing the observed features are introduced. For the first one we assume an unsorted names database set up by Alice that is a superposition (unknown by Bob) of up to n = 2N strings; those we call names. Bob has access to the superposition wave and to the 2N reference noises of the INBL system of N noise bits. For Bob, to decide if a given name x is included in the superposition, once the search has begun, it takes N switching operations followed by a single measurement of the superposition wave. Thus, the time and hardware complexity of the search algorithm is O[log(n)], which indicates an exponential speedup compared to Grover’s quantum algorithm in a corresponding setting. An extra advantage is that the error probability of the search is zero. Moreover, the scheme can also check the existence of a fraction of a string, or several separate string fractions embedded in an arbitrarily long, arbitrary string. In the second algorithm, we expand the above scheme to a phonebook with n names and s phone numbers. When the names and numbers have the same bit resolution, once the search has begun, the time and hardware complexity of this search algorithm is O[log(n)]. In the case of one-to-one correspondence between names and phone numbers (n = s), the algorithm offers inverse phonebook search too. The error probability of this search algorithm is also zero.
Highlights
On Noise-Based LogicThe Einstein–Podolsky–Rosen paradox [1] points to a deep feature of quantum physics leading to the notion of entanglement
We address a similar problem in noise-based logic (NBL) [2,3,4,5,6,7,8,9,10,11,12,13,14,15], which is a classical physical scheme where noise-bits carry the same high-dimensional
Some NBL schemes can offer solutions that either reach beyond the abilities of quantum informatics or offer alternative means with identical potential and less cost, to recent achievements by Ewin Tang in classical computing [16,17]
Summary
The Einstein–Podolsky–Rosen paradox [1] points to a deep feature of quantum physics leading to the notion of entanglement. Noise-based logic (NBL) [2,3,4,5,6,7,8,9,10,11,12,13,14,15] is a classical physical computation system using orthogonal stochastic processes to carry and process the logic information. While the explorations of NBL are still taking place, it is already clear that in certain demonstrated cases, the robustness and controllability of classical physical systems and information offer strong advantages [14,15] over quantum informatics. Some NBL schemes can offer solutions that either reach beyond the abilities of quantum informatics or offer alternative means with identical potential and less cost, to recent achievements by Ewin Tang in classical computing [16,17]. The classical statistical physical key exchange scheme, the KLJN system [18], offers the same level of security and it is the only currently known unconditionally secure communication scheme that can be integrated on a chip
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