Admissible Fundamental Operators and Models for E(3; 3; 1, 1, 1)-contraction and E(3; 2; 1, 2)-contraction
Abstract
We show that for a given pure contraction T7 acting on a Hilbert space H, if (F1, …, F6) ∈ B(DT*7) with [Fi, Fj] = 0, [F*i, F7-j] = [F*j, F7-i],w(F*i + F7-iz) ≤slant 1 and these operators satisfy \[(F*i + F7-iz)T7(z) = T7(z)(Fi + F*7-iz) \,\, for all \,\, z ∈ D\] for 1 ≤slant i, j ≤slant 6 for some (F1, …, F6) ∈ B(DT7) with w(F*i + F7-iz) ≤slant 1 for 1 ≤slant i ≤slant 6, then there exists a E(3; 3; 1, 1, 1)-contraction (T1, …, T7) such that F1, …, F6 are the fundamental operators of (T1, …, T7) and F1, …, F6 are the fundamental operators of (T*1, …, T*7). We also prove similar type of result for pure E(3; 2; 1, 2)-contraction. We explicitly construct a E(3; 3; 1, 1, 1)-unitary (respectively, a E(3; 2; 1, 2)-unitary) starting from a E(3; 3; 1, 1, 1)-contraction (respectively, a E(3; 2; 1, 2)-contraction). Further, we develop functional models for general E(3; 3; 1, 1, 1)-isometries (respectively, E(3; 2; 1, 2)-isometries). In particular, we construct Douglas-type and Sz.-Nazy-Foias-type models for E(3; 3; 1, 1, 1)-contractions (respectively, E(3; 2; 1, 2)-contractions). Finally, we present a Schaffer-type model for the E(3; 3; 1, 1, 1)-isometric dilation (respectively, the E(3; 2; 1, 2)-isometric dilation).
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