What question did this study set out to answer?

The aim is to establish a geometric proof of the Leibniz formula for π through limits of polygons to circles.

March 21, 2026Open Access

A Geometric Proof of the Leibniz Formula for π via Gibbs Phasor Chain Convergence

Puntos clave

The aim is to establish a geometric proof of the Leibniz formula for π through limits of polygons to circles.
Utilized a phasor chain in the complex plane to represent partial sums of a Fourier series.
Controlled discrete curvature using a single parameter for deformation.
Analyzed the relationship between regular (N+1)-gon and the Leibniz alternating sum.
Established that the limit of the polygon approaches a circle as N increases.
Identified that chords transition into arcs, allowing evaluation of the integral to yield π/4.
Discovered the convergence rates, noting a fast O(1/N²) error and a slow O(1/N) Gibbs tail.

Resumen

A geometric proof of the Leibniz formula π/4 = 1 − 1/3 + 1/5 − 1/7 + ⋯ in which π emerges from the polygon-to-circle limit rather than from any prior analytic identity. The partial sums of a Fourier series are treated as a phasor chain in the complex plane whose discrete curvature is controlled by a single parameter. At one setting the chain folds into a regular (N+1)-gon; at another it collapses to the Leibniz alternating sum. The Dirichlet kernel is the intrinsic velocity of the deformation connecting these two states. In the limit N → ∞ the polygon becomes a circle, chords become arcs, and the integral evaluates to π/4 by the same mechanism as Archimedean exhaustion. The convergence rate decomposes into a fast O(1/N²) polygon-to-circle error and a slow O(1/N) Gibbs tail, explaining geometrically why the series converges so slowly.

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