The Principle of Similitude in Biology: From Allometry to the Formulation of Dimensionally Homogenous `Laws'

TL;DR

This paper applies the principle of similitude and dimensional homogeneity to allometric laws in biology, deriving a unified, dimensionally consistent formula for metabolic rates that explains variations across species and conditions.

Contribution

It introduces a dimensionally homogeneous equation for metabolic rates, unifying diverse allometric relationships and resolving inconsistencies caused by incommensurable quantities.

Findings

Derived a unique homogeneous equation for metabolic rates

Explained variations in allometric exponents across species and conditions

Unified different allometric laws into a single, consistent formulation

Abstract

Meaningful laws of nature must be independent of the units employed to measure the variables. The principle of similitude (Rayleigh 1915) or dimensional homogeneity, states that only commensurable quantities (ones having the same dimension) may be compared, therefore, meaningful laws of nature must be homogeneous equations in their various units of measurement, a result which was formalized in the $\rm \Pi$ theorem (Vaschy 1892; Buckingham 1914). However, most relations in allometry do not satisfy this basic requirement, including the `3/4 Law' (Kleiber 1932) that relates the basal metabolic rate and body mass, which it is sometimes claimed to be the most fundamental biological rate (Brown et al. 2004) and the closest to a law in life sciences (West \& Brown 2004). Using the $\rm \Pi$ theorem, here we show that it is possible to construct a unique homogeneous equation for the metabolic rates, in agreement with data in the literature. We find that the variations in the dependence of the metabolic rates on body mass are secondary, coming from variations in the allometric dependence of the heart frequencies. This includes not only different classes of animals (mammals, birds, invertebrates) but also different exercise conditions (basal and maximal). Our results demonstrate that most of the differences found in the allometric exponents (White et al. 2007) are due to compare incommensurable quantities and that our dimensionally homogenous formula, unify these differences into a single formulation. We discuss the ecological implications of this new formulation in the context of the Malthusian's, Fenchel's and the total energy consumed in a lifespan relations.