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The polynomial $f_{2n}(x)=1+x+cdots+x^{2n}$ and its minimizer on the real line $x_{2n}=operatorname{arg,inf} f_{2n}(x)$ for $ninBbb N$ are studied. Results show that $x_{2n}$ exists, is unique, corresponds to $partial_x f_{2n}(x)=0$, and resides on the interval $[-1,-1/2]$ for all $n$. It is further shown that $inf f_{2n}(x)=(1+2n)/(1+2n(1-x_{2n}))$ and $inf f_{2n}(x)in[1/2,3/4]$ for all $n$ with an exact solution for $x_{2n}$ given in the form of a finite sum of hypergeometric functions of unity argument. Perturbation theory is applied to generate rapidly converging and asymptotically exact approximations to $x_{2n}$. Numerical studies are carried out to show how many terms of the perturbation expansion for $x_{2n}$ are needed to obtain suitably accurate approximations to the exact value.
This paper does exactly what the title says it does. It expands the given series to arrive at the familiar pentagonal number expansion, also known as the pentagonal number theorem, and recalls its application to partition numbers. The paper is translated from Eulers Latin original into German.
Note that the family of closed curves C_N={(x,y)in R^2;x^(2N)+y^(2N)=1} for N=1,2,3,... approaches the boundary of [-1,1]^2 as N to infty. In this paper we exhibit a natural parameterization of these curves and generalize to a larger class of equations.
We show that all meromorphic solutions of the stationary reduction of the real cubic Swift-Hohenberg equation are elliptic or degenerate elliptic. We then obtain them all explicitly by the subequation method, and one of them appears to be a new elliptic solution.
We find exact solutions describing bidirectional pulses propagating in fiber Bragg gratings. They are derived by solving the coupled-mode theory equations and are expressed in terms of products of modified Bessel functions with algebraic functions. D
In an earlier article together with Carlos DAndrea [BDKSV2017], we described explicit expressions for the coefficients of the order-$d$ polynomial subresultant of $(x-alpha)^m$ and $(x-beta)^n $ with respect to Bernsteins set of polynomials ${(x-alph