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Let $$h_n(x)=(-1)^n\gamma_ne^{x^2/2} \frac{d^n}{dx^n}e^{-x^2}$$ where $\gamma_n=\pi^{-1/4}2^{-n/2}(n!)^{-1/2}$ be a Hermite function.

Consider $$k_n(x,y)=\frac{h_{n+1}(x)h_n(y)-h_{n+1}(y)h_n(x)}{y-x}$$ such that there exists a positive constant $\Gamma$ such that for any $n$ and for all $x$ $$\int_{-\infty}^{-1}(k_n(x,y))^2dy< \frac{2\Gamma^2}{n+1}, \quad \int_{1}^{\infty}(k_n(x,y))^2dy< \frac{2\Gamma^2}{n+1}$$ I am wondering if one can tell something about constant $\Gamma$, i.e. how small it can be?

Thank you for your help.

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    +1 I guess your question is how small $\Gamma^2$ could be. Could you please provide some context to your question too, if possible.2012-06-01
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    Yes, you are right. How small it can be. I wanted to use Uspensky result http://www.jstor.org/discover/10.2307/1968401?uid=3739448&uid=2129&uid=2&uid=70&uid=3737720&uid=4&sid=562230692032012-06-01
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    for the prolate spheroidal function instead of f(x) in the Uspensky theorem.2012-06-01
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    Your $k_n(x,y)$ looks awfully like the Christoffel-Darboux expression for the Hermite polynomials...2012-06-09

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