New noise-based logic representations to avoid some problems with time complexity
Abstract
Instantaneous noise-based logic can avoid time-averaging, which implies significant potential for low-power parallel operations in beyond-Moore-law-chips. However, the universe (uniform superposition) will be zero with high probability (non-zero with exponentially low probability) in the random-telegraph-wave representation thus the operations with the universe would require exponential time-complexity. To fix this deficiency, we modify the amplitudes of the signals of the L and H states and achieve an exponential speedup compared to the old situation. Another improvement concerns the identification of a single product (hyperspace) state. We introduce a time shifted noise-based logic, which is constructed by shifting each reference signal with a small time delay. This modification implies an exponential speedup of single hyperspace vector identification compared to the former case and it requires the same, O(N) complexity as in quantum computing.
Cite
@article{arxiv.1111.3859,
title = {New noise-based logic representations to avoid some problems with time complexity},
author = {H. Wen and L. B. Kish and A. Klappenecker and F. Peper},
journal= {arXiv preprint arXiv:1111.3859},
year = {2013}
}
Comments
submitted for publication