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Abstract

An infinite 3-parametric family of superintegrable and exactly-solvable quantum models on a plane, admitting separation of variables in polar coordinates, marked by integer index $k$ was introduced in Journ Phys A 42 (2009) 242001 and was called in literature the TTW system. In this paper it is conjectured that the Hamiltonian and both integrals of TTW system have hidden algebra $g^{(k)}$ - it was checked for $k=1,2,3,4$ - having its finite-dimensional representation spaces as the invariant subspaces. It is checked that for $k=1,2,3,4$ that the Hamiltonian $H$, two integrals ${\cal I}_{1,2}$ and their commutator ${\cal I}_{12} = [{\cal I}_1,{\cal I}_2]$ are four generating elements of the polynomial algebra of integrals of the order $(k+1)$: $[{\cal I}_1,{\cal I}_{12}] = P_{k+1}(H, {\cal I}_{1,2},{\cal I}_{12})$, $[{\cal I}_2,{\cal I}_{12}] = Q_{k+1}(H, {\cal I}_{1,2},{\cal I}_{12})$, where $P_{k+1},Q_{k+1}$ are polynomials of degree $(k+1)$ written in terms of ordered monomials of $H, {\cal I}_{1,2},{\cal I}_{12}$. This implies that polynomial algebra of integrals is subalgebra of $g^{(k)}$. It is conjectured that all is true for any integer $k$.