Near-bipartite Leonard pairs
Abstract: Let $\F$ denote a field, and let $V$ denote a vector space over $\F$ with finite positive dimension. A Leonard pair on $V$ is an ordered pair of diagonalizable $\F$-linear maps $A: V \to V$ and $A* : V \to V$ that each act on an eigenbasis for the other in an irreducible tridiagonal fashion. Let $A,A*$ denote a Leonard pair on $V$. Let ${v_i}{i=0}d$ denote an eigenbasis for $A*$ on which $A$ acts in an irreducible tridiagonal fashion. For $0 \leq i \leq d$ define an $\F$-linear map $E*_i : V \to V$ such that $E*_i v_i = v_i$ and $E*_i v_j = 0$ if $j \neq i$ $(0 \leq j \leq d)$. The map $F = \sum{i=0}d E*_i A E*_i$ is called the flat part of $A$. The Leonard pair $A,A*$ is bipartite whenever $F=0$. The Leonard pair $A,A*$ is said to be near-bipartite whenever the pair $A-F, A*$ is a Leonard pair on $V$. In this case, the Leonard pair $A-F, A*$ is bipartite, and called the bipartite contraction of $A,A*$. Let $B,B*$ denote a bipartite Leonard pair on $V$. By a near-bipartite expansion of $B,B*$ we mean a near-bipartite Leonard pair on $V$ with bipartite contraction $B,B*$. In the present paper we have three goals. Assuming $\F$ is algebraically closed, (i) we classify up to isomorphism the near-bipartite Leonard pairs over $\F$; (ii) for each near-bipartite Leonard pair over $\F$ we describe its bipartite contraction; (iii) for each bipartite Leonard pair over $\F$ we describe its near-bipartite expansions.
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