Simpler and faster: an improved heat index.

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Bibliographic Details
Title: Simpler and faster: an improved heat index.
Authors: Lu, Yi-Chuan1,2 (AUTHOR) yclu@berkeley.edu, Goodman, Alex3 (AUTHOR), Kalmus, Peter3 (AUTHOR), Romps, David M.1,2 (AUTHOR)
Source: Journal of Applied Meteorology & Climatology. May2026, Vol. 65 Issue 5, p1-15. 15p.
Subjects: Heat index, Mathematical models, Physiological effects of heat, Optimization algorithms, Thermal tolerance (Physiology), Temperature, Environmental health
Abstract: The existing heat index is complicated and slow. Furthermore, its complexity has obfuscated both mathematical inconsistencies (double values) and physical inconsistencies (supersaturation). This paper presents a simplified heat index that resolves these issues. The new approach results in small changes to the heat index for air temperatures below 300 K, but leaves the heat index unchanged for air temperatures above 300 K, where it is most commonly used. This simplification enhances interpretability, and a refactored algorithm accelerates the computation of the heat index by orders of magnitude. The optimized implementation is freely available in C++, R, and Python. In this article, we also clarify a long-standing ambiguity regarding "compensable" and "uncompensable" heat stress. Historically, "uncompensable" denoted conditions leading to fatal core temperatures. Recent studies, however, have applied the term to any inflection followed by a rise in core temperature. Using the heat index model, we show that such an observation does not necessarily imply lethality, because heat loss increases with core temperature and can yield a stable, non-fatal equilibrium. To avoid ambiguity, we therefore replace compensable/uncompensable with normothermic, hyperthermic, and lethal categories based on the predicted steady-state core temperature. [ABSTRACT FROM AUTHOR]
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Abstract:The existing heat index is complicated and slow. Furthermore, its complexity has obfuscated both mathematical inconsistencies (double values) and physical inconsistencies (supersaturation). This paper presents a simplified heat index that resolves these issues. The new approach results in small changes to the heat index for air temperatures below 300 K, but leaves the heat index unchanged for air temperatures above 300 K, where it is most commonly used. This simplification enhances interpretability, and a refactored algorithm accelerates the computation of the heat index by orders of magnitude. The optimized implementation is freely available in C++, R, and Python. In this article, we also clarify a long-standing ambiguity regarding "compensable" and "uncompensable" heat stress. Historically, "uncompensable" denoted conditions leading to fatal core temperatures. Recent studies, however, have applied the term to any inflection followed by a rise in core temperature. Using the heat index model, we show that such an observation does not necessarily imply lethality, because heat loss increases with core temperature and can yield a stable, non-fatal equilibrium. To avoid ambiguity, we therefore replace compensable/uncompensable with normothermic, hyperthermic, and lethal categories based on the predicted steady-state core temperature. [ABSTRACT FROM AUTHOR]
ISSN:15588424
DOI:10.1175/JAMC-D-25-0067.1