Explicit classification of all finite-dimensional polynomial SH-Lie algebras over R^d or C^d using complete generalized Wronskians of order k as N-ary brackets, together with a factorization formula for the associated generalized Vandermonde determinants.
The Alternating Compositions of Weighted Differential Operators Yield The Weights' Wronskian With Which Constant?
1 Pith paper cite this work. Polarity classification is still indexing.
abstract
The alternated composition of $N=2p$ differential operators $ w_j(x)\,\partial_x^p$ of strict order $p$ on the line $\mathbb{R}\ni x$ is again a differential operator of strict order $p$; its coefficient is the constant $\mathrm{const}(p)$, depending only on the arity $N$, times the Wronskian determinant of the originally taken coefficients $w_1$, $\ldots$, $w_N$. The case $p=1$ of the Lie bracket for two vector fields fixes $\mathrm{const}(1)=1$. When $p=2$, finding $\mathrm{const}(2)=2$ is easy; we obtain $\mathrm{const}(3)=90$. The problem is to know $\mathrm{const}(p\geqslant 4)$. We express the formula of $\mathrm{const}(p)$ in terms of the sum with signs over the much smaller set of 'late-growing' permutations, thus reaching the exact values $c(p=4)= 586\,656$, $c(p=5)\approx 1.9\cdot 10^{12}$, and $c(p=6)\approx 7.9\cdot 10^{21}$; the positive integer sequence $\mathrm{const}(p)$ seems to be new.
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math.RA 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Explicit class of finite-dimensional polynomial algebras with Wronskians over $\mathbb{R}^d$ as $N$-ary Lie brackets: beyond $\mathfrak{sl}(2)$
Explicit classification of all finite-dimensional polynomial SH-Lie algebras over R^d or C^d using complete generalized Wronskians of order k as N-ary brackets, together with a factorization formula for the associated generalized Vandermonde determinants.