Elliptic integral identities derived from Coxeter's integrals
Abstract
We revisit the classical integrals introduced by Coxeter, not to recalculate their well-known exact values, but to use them as a tool to derive elliptic integral identities. By embedding Coxeter's first integral into a one-parameter family I(λ)=∫0π/2 \!(θ1+λθ)\,dθ, and differentiating with respect to the parameter \(λ\), we show that the derivative I'(λ) can be expressed as an elliptic-type integral. Integrating I'(λ) between 0 and 2 yields the identity ∫02 ∫0π/2 2θ (1+sθ)(1+sθ)2-2θ \,dθ\, ds=A-B=π212, where A and B are the first two so-called Coxeter integrals A = ∫0π/2 \!(θ1+2θ) dθ, and B = ∫0π/2 \!(11+2θ) dθ. The derivative I'(λ) can be expressed in terms of incomplete elliptic integrals of the first kind F and of the third kind . This approach establishes a direct connection between classical Coxeter integrals and elliptic functions. The method highlights how well-known trigonometric integrals can serve as a bridge to explore properties and relations of elliptic integrals, offering new analytic insights beyond the original Coxeter evaluations.
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