Theory and Modern Applications
From: Construction of a new family of Fubini-type polynomials and its applications
Generating function | \((\frac{2^{\upsilon }}{(2-e^{t})^{2\upsilon }} ) (\frac{e^{xt}}{1-yt^{s}} ) \cos (zt)= \sum_{n=0}^{\infty } {}_{e^{(s)}}\mathit{F}^{(c,\upsilon )}_{n}(x,y,z) \frac{ t^{n}}{n!} \) |
Multiplicative and derivative operators | \(\hat{M}_{TE\mathit{F}c}=x+\frac{syD_{x}^{s-1}}{1-yD_{x}^{s}}+\frac{2\upsilon e^{D_{x}}}{2-e^{D_{x}}}-z \tan (zD_{x})\), \(\hat{P}_{TE\mathit{F}c}:= D_{x}\) |
Differential equation | \((xD_{x}+\frac{syD_{x}^{s}}{1-yD_{x}^{s}}+\frac{2\upsilon e^{D_{x}}}{2-e^{D_{x}}}D_{x}-z \tan (zD_{x})D_{x}-n ){}_{e^{(s)}}\mathit{F}^{(c,\upsilon )}_{n}(x,y,z)=0\) |
Identities and relations | \({}_{e^{(s)}}\mathit{F}^{(c,\upsilon )}_{n}(x,y,z)=\sum_{\kappa =0}^{n} \binom{n }{\kappa } \mathit{F}^{(c,\upsilon )}_{n-\kappa }(z) e^{(s)}_{\kappa }(x,y)\) |
\({}_{e^{(s)}}\mathit{F}^{(c,\upsilon )}_{n}(x+u,y,z)=\sum_{\kappa =0}^{n} \binom{n }{\kappa } {}_{e^{(s)}}\mathit{F}^{(c,\upsilon )}_{n-\kappa }(x,y,z) u^{\kappa }\) | |
\({}_{e^{(s)}}\mathit{F}^{(c,\upsilon )}_{n+\kappa }(\omega ,y,z)=\sum_{l=0}^{n}\sum_{m=0}^{\kappa } \binom{n }{l} \binom{\kappa }{m} (\omega -x)^{l+m} {}_{e^{(s)}}\mathit{F}^{(c,\upsilon )}_{n+\kappa -l-m}(x,y,z)\) | |
\({}_{e^{(s)}}\mathit{F}^{(c,\upsilon +\sigma )}_{n}(x,y,z)=\sum_{\kappa =0}^{n} \binom{n }{\kappa } \mathit{F}^{(\upsilon )}_{\kappa } {}_{e^{(s)}}\mathit{F}^{(c,\sigma )}_{n-\kappa }(x,y,z)\) | |
\((\frac{x^{n}}{1-yt^{s}} ) \cos (zt)=\sum_{\delta =0}^{2\upsilon }\sum_{\kappa =0}^{n}(-1)^{\delta } \binom{2\upsilon }{\delta }\binom{n }{\kappa }2^{\upsilon -\delta } \delta ^{n-\kappa } {}_{e^{(s)}}\mathit{F}^{(c,\upsilon )}_{\kappa }(x,y,z)\) | |
Partial derivatives equations | \(\frac{\partial ^{m}}{\partial x^{m}} \lbrace {}_{e^{(s)}}\mathit{F}^{(c,\upsilon )}_{n}(x,y,z) \rbrace =2^{-\frac{3\delta }{2}} \sum_{\kappa =0}^{n}m! \binom{n }{\kappa }\binom{n-\kappa }{m} \mathcal{E}^{(\delta )}_{\kappa } (-\frac{1}{2} ) {}_{e^{(s)}}\mathit{F}^{ (c,\upsilon -\frac{\delta }{2} )}_{n-\kappa -m}(x,y,z)\) |
\(\frac{\partial ^{m}}{\partial u^{m}} \lbrace {}_{e^{(s)}}\mathit{F}^{(c,\upsilon +\sigma )}_{n}(x+u,y,z) \rbrace = \frac{n!}{2^{\upsilon } (n+2\upsilon )!} \sum_{\kappa =0}^{n+2\upsilon }m! \binom{n+2\upsilon }{\kappa }\binom{\kappa }{m} \mathfrak{B}^{(2\upsilon )}_{\kappa -m} (x,\frac{1}{2} ) {}_{e^{(s)}}\mathit{F}^{(c,\sigma )}_{n+2\upsilon -\kappa }(u,y,z)\) | |
\(\frac{\partial }{\partial x} \lbrace {}_{e^{(s)}}\mathit{F}^{(c,\upsilon )}_{n}(x,y,z) \rbrace =\frac{1}{2^{3\delta }} \sum_{\kappa =0}^{n}(n-\kappa )\binom{n }{\kappa } \mathcal{E}^{(2\delta )}_{\kappa } (-\frac{1}{2} ) {}_{e^{(s)}}\mathit{F}^{(c,\upsilon -\delta )}_{n-\kappa -1}(x,y,z)\) |