We research the relationship between the probability functions of the twofold hyperbolic universe, consisting of the logarithmic (real) and harmonic (rational) worlds. Within the logarithmic realm, we study the connection between the Gauss- Kuzmin distribution and Newcomb-Benford law and prove that they are fundamentally equivalent; the former corresponds to the probability decrements of the latter, i.e., log(2,1+1/(k(k+2))) is the difference between the function log(2,1+1/n) evaluated at n=k and n=k+1, where k is the index of a coefficient of a real number’s regular continued fraction expansion and n is a positive numeral written in positional notation. Thus, the binary Newcomb-Benford probability of n=1 is the sum of all the Gauss-Kuzmin masses, of n=2, is the sum of all the Gauss-Kuzmin masses minus the Gauss-Kuzmin mass at k=1, and of n=m, is the sum of all the Gauss-Kuzmin masses minus the sum of the first m-1 ones. Besides, the extrapolation of the Gauss-Kuzmin measure outside the unit interval subsumes Newcomb-Benford’s cumulative distribution function. These findings lead to the Gauss-Benford law, which specifies that the occurrence possibility of a positive real number represented in positional notation is log(2,1+x) (i.e., the Gauss-Kuzmin measure) if x is within the unit interval and log(2,1+1/x) if x is outside. Geometrically, these possibilities indicate proximity to 1. The map between both domain partitions is a sheer inversion, the unique conformal transformation that fixes one and respects the minimum information principle. Moreover, we introduce the Gauss-Benford measure, log(1+1/x,1+y), as the probability of a random variable accumulated between x-1 and x, with density 1/((1+y)ln(1+1/x)), where 0≤x-1
| Published in | Mathematics Letters (Volume 10, Issue 3) |
| DOI | 10.11648/j.ml.20241003.11 |
| Page(s) | 24-35 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Gauss-Kuzmin Distribution, Regular Continued Fraction, Positional Notation, Newcomb-Benford Law, Gauss-Benford Law, Smallness, Harmonic Scale, Logarithmic Scale
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APA Style
Rives, J. (2024). Gauss-Benford Rules and Their Harmonic Peers. Mathematics Letters, 10(3), 24-35. https://doi.org/10.11648/j.ml.20241003.11
ACS Style
Rives, J. Gauss-Benford Rules and Their Harmonic Peers. Math. Lett. 2024, 10(3), 24-35. doi: 10.11648/j.ml.20241003.11
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Download@article{10.11648/j.ml.20241003.11,
author = {Julio Rives},
title = {Gauss-Benford Rules and Their Harmonic Peers},
journal = {Mathematics Letters},
volume = {10},
number = {3},
pages = {24-35},
doi = {10.11648/j.ml.20241003.11},
url = {https://doi.org/10.11648/j.ml.20241003.11},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ml.20241003.11},
abstract = {We research the relationship between the probability functions of the twofold hyperbolic universe, consisting of the logarithmic (real) and harmonic (rational) worlds. Within the logarithmic realm, we study the connection between the Gauss- Kuzmin distribution and Newcomb-Benford law and prove that they are fundamentally equivalent; the former corresponds to the probability decrements of the latter, i.e., log(2,1+1/(k(k+2))) is the difference between the function log(2,1+1/n) evaluated at n=k and n=k+1, where k is the index of a coefficient of a real number’s regular continued fraction expansion and n is a positive numeral written in positional notation. Thus, the binary Newcomb-Benford probability of n=1 is the sum of all the Gauss-Kuzmin masses, of n=2, is the sum of all the Gauss-Kuzmin masses minus the Gauss-Kuzmin mass at k=1, and of n=m, is the sum of all the Gauss-Kuzmin masses minus the sum of the first m-1 ones. Besides, the extrapolation of the Gauss-Kuzmin measure outside the unit interval subsumes Newcomb-Benford’s cumulative distribution function. These findings lead to the Gauss-Benford law, which specifies that the occurrence possibility of a positive real number represented in positional notation is log(2,1+x) (i.e., the Gauss-Kuzmin measure) if x is within the unit interval and log(2,1+1/x) if x is outside. Geometrically, these possibilities indicate proximity to 1. The map between both domain partitions is a sheer inversion, the unique conformal transformation that fixes one and respects the minimum information principle. Moreover, we introduce the Gauss-Benford measure, log(1+1/x,1+y), as the probability of a random variable accumulated between x-1 and x, with density 1/((1+y)ln(1+1/x)), where 0≤x-1
