Saved in:
Bibliographic Details
Main Author: Kolonin, Anton
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.15723
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866914164760379392
author Kolonin, Anton
author_facet Kolonin, Anton
contents Quantifying numerical data involves addressing two key challenges: first, determining whether the data can be naturally quantified, and second, identifying the numerical intervals or ranges of values that correspond to specific value classes, referred to as "quantums," which represent statistically meaningful states. If such quantification is feasible, continuous streams of numerical data can be transformed into sequences of "symbols" that reflect the states of the system described by the measured parameter. People often perform this task intuitively, relying on common sense or practical experience, while information theory and computer science offer computable metrics for this purpose. In this study, we assess the applicability of metrics based on information compression and the Silhouette coefficient for quantifying numerical data. We also investigate the extent to which these metrics correlate with one another and with what is commonly referred to as "human intuition." Our findings suggest that the ability to classify numeric data values into distinct categories is associated with a Silhouette coefficient above 0.65 and a Dip Test below 0.5; otherwise, the data can be treated as following a unimodal normal distribution. Furthermore, when quantification is possible, the Silhouette coefficient appears to align more closely with human intuition than the "normalized centroid distance" method derived from information compression perspective.
format Preprint
id arxiv_https___arxiv_org_abs_2511_15723
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Human-aligned Quantification of Numerical Data
Kolonin, Anton
Data Analysis, Statistics and Probability
Human-Computer Interaction
Machine Learning
Numerical Analysis
Quantifying numerical data involves addressing two key challenges: first, determining whether the data can be naturally quantified, and second, identifying the numerical intervals or ranges of values that correspond to specific value classes, referred to as "quantums," which represent statistically meaningful states. If such quantification is feasible, continuous streams of numerical data can be transformed into sequences of "symbols" that reflect the states of the system described by the measured parameter. People often perform this task intuitively, relying on common sense or practical experience, while information theory and computer science offer computable metrics for this purpose. In this study, we assess the applicability of metrics based on information compression and the Silhouette coefficient for quantifying numerical data. We also investigate the extent to which these metrics correlate with one another and with what is commonly referred to as "human intuition." Our findings suggest that the ability to classify numeric data values into distinct categories is associated with a Silhouette coefficient above 0.65 and a Dip Test below 0.5; otherwise, the data can be treated as following a unimodal normal distribution. Furthermore, when quantification is possible, the Silhouette coefficient appears to align more closely with human intuition than the "normalized centroid distance" method derived from information compression perspective.
title Human-aligned Quantification of Numerical Data
topic Data Analysis, Statistics and Probability
Human-Computer Interaction
Machine Learning
Numerical Analysis
url https://arxiv.org/abs/2511.15723