I recently investigated $\textrm{Discriminant}_u(\omega P(u) +(z-u)P'(u))$, where $P(u) := u^3 + au + b$ and $\omega$ is a real parameter (with $\omega\in(0,1)\cup(1,3)$) associated with the order of a fractional derivative. (This is a special case of the problem previously discussed here.) In doing so, I came across the following expression (plus some additional terms) that looks quite striking, but I haven't been able to place it:
$$\frac{3a(b-z^3)}{(\omega-1)\,\lambda} + \frac{z}{\lambda^3}\left(a^2\lambda\left(1-\frac{1}{(\omega-1)^2}\right)-3bz\right)$$
Here $\lambda:= \sqrt[3]{\omega-3}.$ I'm wondering if anyone has seen this expression, or something sufficiently similar to it, in any other context.
Due to a natural change of variables used to arrive at the above expression (which reduces the constant part of the above discriminant to the discriminant of the polynomial $\widetilde{P}(u)$ below), the expression should possibly be thought of as the “image” of the polynomial
$$\widetilde{P}(u) := u^3 + \frac{a}{(\omega-1)\sqrt[3]{\omega-3}}u + \frac{b}{\omega(\omega-3)}$$
under some discriminant-like “function”.
Does the expression above look familiar, or is it perhaps some determinant involving the coefficients in $\widetilde{P}(u)$, and $z$? Alternatively, do you see some way to attack $\textrm{Discriminant}_u(\omega P(u) +(z-u)P'(u))$ directly?
with(RootFinding[Parametric]):DiscriminantVariety([3*a*z^3 + 3*b*omega*z^2 - a^2*(omega*(omega - 2) - 2)*z - 3*a*b*omega*(omega - 3) = 0], [z])outputs $[[a],[4\,{a}^{6}{\omega}^{6}-24\,{a}^{6}{\omega}^{5}+3\,{a}^{3}{b}^{2} {\omega}^{6}+24\,{a}^{6}{\omega}^{4}+150\,{a}^{3}{b}^{2}{\omega}^{5}+ 64\,{a}^{6}{\omega}^{3}-1539\,{a}^{3}{b}^{2}{\omega}^{4}+108\,{b}^{4}{ \omega}^{5}-48\,{a}^{6}{\omega}^{2}+5046\,{a}^{3}{b}^{2}{\omega}^{3}- 324\,{b}^{4}{\omega}^{4}-96\,{a}^{6}\omega-5577\,{a}^{3}{b}^{2}{\omega }^{2}-32\,{a}^{6}]] $. $\endgroup$