Cheng's eigenvalue comparison theorem

In Riemannian geometry, Cheng's eigenvalue comparison theorem generally states that the larger the domain, the smaller the first eigenvalue of the Laplace–Beltrami operator can be. The 1975 theorem is named after S.Y. Cheng and, using geodesic balls, can be generalized to certain tubular domains (Lee 1990).

S.Y. Cheng used Barta's theorem to derive the eigenvalue comparison theorem.

Let N be a Riemannian n-manifold and B_N(p, r) be a geodesic ball centered at p with radius r < inj(p), where "inj" is the injectivity radius. Let c be the least upper bound for all sectional curvatures at B_N(p, r) and let N ⁿ(c) be the simply connected n-space form of constant sectional curvature c. Then λ₁(B_N(p, r)) ≥ λ₁(B_N ⁿ(c)(r)) is Cheng's inequality. In particular, when c = −1 and inj(p) = ∞, Cheng’s inequality becomes λ^*(N) ≥ λ^*(H ⁿ(−1)) which is McKean’s inequality.^[1]

• Comparison theorem
• Eigenvalue comparison theorem

• Bessa, G.P.; Montenegro, J.F. (2008), "On Cheng's eigenvalue comparison theorem", Mathematical proceedings of the Cambridge Philosophical Society, 144 (3): 673–682, ISSN 0305-0041.
• Chavel, Isaac (1984), Eigenvalues in Riemannian geometry, Pure Appl. Math., vol. 115, Academic Press.
• Cheng, S.Y. (1975), "Eigenvalue Comparison Theorems and its Geometric Applications", Math. Z., 143: 289–297.
• Lee, Jeffrey M. (1990), "Eigenvalue Comparison for Tubular Domains", Proceedings of the American Mathematical Society, 109 (3): 843–848.
• McKean, Henry (1970), "An upper bound for the spectrum of △ on a manifold of negative curvature", J. Differ. Geom., 4: 359–366.
• Richardson, Ken (1998), "Riemannian foliations and eigenvalue comparison", Ann. Global Anal. Geom., 16: 497–525/

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