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For an irrational real number$\alpha$ and real number $\gamma$ we consider the inhomogeneous approximation constant $$M(\alpha ,\gamma ):=\underset{\left|n\right|\to \infty }{lim\; inf}\left|n\right|\left|\right|n\alpha -\gamma \left|\right|$$ via the semi-regular negative continued fraction expansion of $\alpha$ $$\alpha =\frac{1}{a_1-\frac{1}{a_2-\frac{1}{a_3-\cdots }}}$$ and an appropriate alpha-expansion of $\gamma$. We give an upper bound on the case of worst inhomogeneous approximation, $$\rho \left(\alpha \right):=\underset{\gamma \notin 𝐙+\alpha 𝐙}{sup}M(\alpha ,\gamma ),$$ which is sharp when the partial quotients ai are almost all even and at least four. When the negative expansion...

For a prime $p$ and positive integers $\ell \<k\<h\<p$ with $d=(h,k,\ell ,p-1)$, we show that $M$, the number of simultaneous solutions $x,y,z,w$ in ${\mathbb{Z}}_p^{*}$ to $x^h+y^h=z^h+w^h$, $x^k+y^k=z^k+w^k$, $x^{\ell }+y^{\ell }=z^{\ell }+w^{\ell }$, satisfies $${\displaystyle M\le 3d^2{(p-1)}^2+25hk\ell (p-1).}$$ When $hk\ell =o\left(p{d}^2\right)$ we obtain a precise asymptotic count on $M$. This leads to the new twisted exponential sum bound $${\displaystyle \left|\sum _{x=1}^{p-1}\chi \left(x\right)e^{2\pi if\left(x\right)/p}\right|\le 3^{\frac{1}{4}}{d}^{\frac{1}{2}}{p}^{\frac{7}{8}}+\sqrt{5}{\left(hk\ell \right)}^{\frac{1}{4}}{p}^{\frac{5}{8}},}$$ for trinomials $f=a{x}^h+b{x}^k+c{x}^{\ell }$, and to results on the average size of such sums.

Let p be a prime, ℤₚ be the finite field in p elements, k be a positive integer, and A be the multiplicative subgroup of nonzero kth powers in ℤₚ. The goal of this paper is to determine, for a given positive integer s, a value tₛ such that if |A| ≫ tₛ then every element of ℤₚ is a sum of s kth powers. We obtain $t₄=p^{22/39+ϵ}$, $t₅=p^{15/29+ϵ}$ and for s ≥ 6, $tₛ=p^{(9s+45)/(29s+33)+ϵ}$. For s ≥ 24 further improvements are made, such as $t_{32}=p^{5/16+ϵ}$ and $t_{128}=p^{1/4}$.