English

Interpolation Macdonald polynomials and Cauchy-type identities

Combinatorics 2019-08-12 v2 Mathematical Physics math.MP Quantum Algebra

Abstract

Let Sym denote the algebra of symmetric functions and Pμ(;q,t)P_\mu(\,\cdot\,;q,t) and Qμ(;q,t)Q_\mu(\,\cdot\,;q,t) be the Macdonald symmetric functions (recall that they differ by scalar factors only). The (q,t)(q,t)-Cauchy identity μPμ(x1,x2,;q,t)Qμ(y1,y2,;q,t)=i,j=1(xiyjt;q)(xiyj;q) \sum_\mu P_\mu(x_1,x_2,\dots;q,t)Q_\mu(y_1,y_2,\dots;q,t)=\prod_{i,j=1}^\infty\frac{(x_iy_jt;q)_\infty}{(x_iy_j;q)_\infty} expresses the fact that the Pμ(;q,t)P_\mu(\,\cdot\,;q,t)'s form an orthogonal basis in Sym with respect to a special scalar product ,q,t\langle\,\cdot\,,\,\cdot\,\rangle_{q,t}. The present paper deals with the inhomogeneous \emph{interpolation} Macdonald symmetric functions Iμ(x1,x2,;q,t)=Pμ(x1,x2,;q,t)+lower degree terms. I_\mu(x_1,x_2,\dots;q,t)=P_\mu(x_1,x_2,\dots;q,t)+\text{lower degree terms}. These functions come from the NN-variate interpolation Macdonald polynomials, extensively studied in the 90's by Knop, Okounkov, and Sahi. The goal of the paper is to construct symmetric functions Jμ(;q,t)J_\mu(\,\cdot\,;q,t) with the biorthogonality property Iμ(;q,t),Jν(;q,t)q,t=δμν. \langle I_\mu(\,\cdot\,;q,t), J_\nu(\,\cdot\,;q,t)\rangle_{q,t}=\delta_{\mu\nu}. These new functions live in a natural completion of the algebra Sym. As a corollary one obtains a new Cauchy-type identity in which the interpolation Macdonald polynomials are paired with certain multivariate rational symmetric functions. The degeneration of this identity in the Jack limit is also described.

Keywords

Cite

@article{arxiv.1712.08018,
  title  = {Interpolation Macdonald polynomials and Cauchy-type identities},
  author = {Grigori Olshanski},
  journal= {arXiv preprint arXiv:1712.08018},
  year   = {2019}
}

Comments

v2: the notation of dual functions changed in accordance with reviewer's suggestion; a few typos fixed; three unnecessary references deleted from the list; to appear in J. Combin. Theory Ser. A

R2 v1 2026-06-22T23:26:07.268Z