Abstract
The fundamental question "Are sequential data random?" arises in myriad contexts, often with severe data length constraints. Furthermore, there is frequently a critical need to delineate nonrandom sequences in terms of closeness to randomness--e.g., to evaluate the efficacy of therapy in medicine. We address both these issues from a computable framework via a quantification of regularity. ApEn (approximate entropy), defining maximal randomness for sequences of arbitrary length, indicating the applicability to sequences as short as N = 5 points. An infinite sequence formulation of randomness is introduced that retains the operational (and computable) features of the finite case. In the infinite sequence setting, we indicate how the "foundational" definition of independence in probability theory, and the definition of normality in number theory, reduce to limit theorems without rates of convergence, from which we utilize ApEn to address rates of convergence (of a deficit from maximal randomness), refining the aforementioned concepts in a computationally essential manner. Representative applications among many are indicated to assess (i) random number generation output; (ii) well-shuffled arrangements; and (iii) (the quality of) bootstrap replicates.
Keywords
RandomnessClosenessMathematicsLimit (mathematics)Sequence (biology)Entropy (arrow of time)Convergence (economics)Approximate entropyIndependence (probability theory)NormalityAlgorithmRandomness testsComputer scienceApplied mathematicsStatisticsTime seriesMathematical analysis
Affiliated Institutions
Related Publications
Approximate entropy (ApEn) as a complexity measure
Approximate entropy (ApEn) is a recently developed statistic quantifying regularity and complexity, which appears to have potential application to a wide variety of relatively s...
Approximate entropy as a measure of system complexity.
Techniques to determine changing system complexity from data are evaluated. Convergence of a frequently used correlation dimension algorithm to a finite value does not necessari...
Physiological time-series analysis using approximate entropy and sample entropy
Entropy, as it relates to dynamical systems, is the rate of information production. Methods for estimation of the entropy of a system represented by a time series are not, howev...
Entropy measures of heart rate variation in conscious dogs
Our goal was to determine the contributions of sympathetic and parasympathetic activity to entropy measures of heart rate variability (HRV). We compared our results with two com...
Physiological time-series analysis: what does regularity quantify?
Approximate entropy (ApEn) is a recently developed statistic quantifying regularity and complexity that appears to have potential application to a wide variety of physiological ...
Publication Info
- Year
- 1996
- Type
- article
- Volume
- 93
- Issue
- 5
- Pages
- 2083-2088
- Citations
- 490
- Access
- Closed
External Links
Social Impact
Altmetric
PlumX Metrics
Social media, news, blog, policy document mentions
Citation Metrics
490
OpenAlex
Cite This
Steven M. Pincus,
Burton H. Singer
(1996).
Randomness and degrees of irregularity..
Proceedings of the National Academy of Sciences
, 93
(5)
, 2083-2088.
https://doi.org/10.1073/pnas.93.5.2083
Identifiers
- DOI
- 10.1073/pnas.93.5.2083