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Modular Welch Bounds with Applications

Operator Algebras 2022-01-04 v1 Functional Analysis

Abstract

We prove the following two results. \begin{enumerate} \item Let A\mathcal{A} be a unital commutative C*-algebra and Ad\mathcal{A}^d be the standard Hilbert C*-module over A\mathcal{A}. Let ndn\geq d. If {τj}j=1n\{\tau_j\}_{j=1}^n is any collection of vectors in Ad\mathcal{A}^d such that τj,τj=1\langle \tau_j, \tau_j \rangle =1, 1jn\forall 1\leq j \leq n, then \begin{align*} \max _{1\leq j,k \leq n, j\neq k}\|\langle \tau_j, \tau_k\rangle ||^{2m}\geq \frac{1}{n-1}\left[\frac{n}{{d+m-1\choose m}}-1\right], \quad \forall m \in \mathbb{N}. \end{align*} \item Let A\mathcal{A} be a σ\sigma-finite commutative W*-algebra or a commutative AW*-algebra and E\mathcal{E} be a rank d Hilbert C*-module over A\mathcal{A}. Let ndn\geq d. If {τj}j=1n\{\tau_j\}_{j=1}^n is any collection of vectors in E\mathcal{E} such that τj,τj=1\langle \tau_j, \tau_j \rangle =1, 1jn\forall 1\leq j \leq n, then \begin{align*} \max _{1\leq j,k \leq n, j\neq k}\|\langle \tau_j, \tau_k\rangle ||^{2m}\geq \frac{1}{n-1}\left[\frac{n}{{d+m-1\choose m}}-1\right], \quad \forall m \in \mathbb{N}. \end{align*} \end{enumerate} Results (1) and (2) reduce to the famous result of Welch [\textit{IEEE Transactions on Information Theory, 1974}] obtained 48 years ago. We introduce the notions of modular frame potential, modular equiangular frames and modular Grassmannian frames. We formulate Zauner's conjecture for Hilbert C*-modules.

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Cite

@article{arxiv.2201.00319,
  title  = {Modular Welch Bounds with Applications},
  author = {K. Mahesh Krishna},
  journal= {arXiv preprint arXiv:2201.00319},
  year   = {2022}
}

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R2 v1 2026-06-24T08:37:52.184Z