A Scaling-Parameter Framework for Perimeter and Area in Self-Similar Planar Fractals

Abstract

The Koch snowflake is a classical example of a planar curve with infinite perimeter enclosing a finite, positive area. Although such examples are well known individually, classical treatments typically analyze each construction in isolation and classify them by similarity dimension. This paper develops a unified parameter-space representation for a class of self-similar planar constructions, organized by two integers -- the number of self-similar pieces N and the inverse linear scale factor r -- together with two derived growth ratios α= N/r and β= N/r2, governing perimeter and area scaling respectively. The (N,r) parameter space is partitioned into three regimes -- N r, r < N < r2, and N r2 -- corresponding to qualitatively distinct asymptotic behaviors of perimeter and area jointly. Within the intermediate regime r < N < r2, a construction-class refinement distinguishes additive constructions (region bounded by the iterated curve), which yield positive finite asymptotic area under a stated non-overlap assumption, from subtractive constructions (iterated set itself), which yield zero asymptotic area. This records a structural non-equivalence inside the same dimension class that is not visible from D = N / r alone. Four worked examples illustrate the framework -- the Sierpinski triangle, Sierpinski carpet, Koch snowflake, and a Koch-style construction on a square invented by the author -- and four further constructions are analyzed predictively to demonstrate that diagnostic outputs follow from (N, r, construction class) without re-derivation. The contribution lies in formulation and synthesis: the paper consolidates several classical results into a single diagnostic representation in which, given (N, r) and construction class, the asymptotic behavior of perimeter and area can be inferred directly.