English

$C^*$-isomorphisms associated with two projections on a Hilbert $C^*$-module

Operator Algebras 2022-03-03 v1

Abstract

Motivated by two norm equations used to characterize the Friedrichs angle, this paper studies CC^*-isomorphisms associated with two projections by introducing the matched triple and the semi-harmonious pair of projections. A triple (P,Q,H)(P,Q,H) is said to be matched if HH is a Hilbert CC^*-module, PP and QQ are projections on HH such that their infimum PQP\wedge Q exists as an element of L(H)\mathcal{L}(H), where L(H)\mathcal{L}(H) denotes the set of all adjointable operators on HH. The CC^*-subalgebras of L(H)\mathcal{L}(H) generated by elements in {PPQ,QPQ,I}\{P-P\wedge Q, Q-P\wedge Q, I\} and {P,Q,PQ,I}\{P,Q,P\wedge Q,I\} are denoted by i(P,Q,H)i(P,Q,H) and o(P,Q,H)o(P,Q,H), respectively. It is proved that each faithful representation (π,X)(\pi, X) of o(P,Q,H)o(P,Q,H) can induce a faithful representation (π~,X)(\widetilde{\pi}, X) of i(P,Q,H)i(P,Q,H) such that \begin{align*}&\widetilde{\pi}(P-P\wedge Q)=\pi(P)-\pi(P)\wedge \pi(Q),\\ &\widetilde{\pi}(Q-P\wedge Q)=\pi(Q)-\pi(P)\wedge \pi(Q). \end{align*} When (P,Q)(P,Q) is semi-harmonious, that is, R(P+Q)\overline{\mathcal{R}(P+Q)} and R(2IPQ)\overline{\mathcal{R}(2I-P-Q)} are both orthogonally complemented in HH, it is shown that i(P,Q,H)i(P,Q,H) and i(IQ,IP,H)i(I-Q,I-P,H) are unitarily equivalent via a unitary operator in L(H)\mathcal{L}(H). A counterexample is constructed, which shows that the same may be not true when (P,Q)(P,Q) fails to be semi-harmonious. Likewise, a counterexample is constructed such that (P,Q)(P,Q) is semi-harmonious, whereas (P,IQ)(P,I-Q) is not semi-harmonious. Some additional examples indicating new phenomena of adjointable operators acting on Hilbert CC^*-modules are also provided.

Keywords

Cite

@article{arxiv.2203.00827,
  title  = {$C^*$-isomorphisms associated with two projections on a Hilbert $C^*$-module},
  author = {Chunhong Fu and Qingxiang Xu and Guanjie Yan},
  journal= {arXiv preprint arXiv:2203.00827},
  year   = {2022}
}
R2 v1 2026-06-24T09:58:43.176Z