On the mean square of the error term for the asymmetric two-dimensional divisor problem (I)

Suppose a and b are two fixed positive integers such that (a, b) = 1. In this paper we shall establish an asymptotic formula for the mean square of the error term Δ _a,b (x) of the general two-dimensional divisor problem.     

On the mean square of the error term for the asymmetric two-dimensional divisor problems(II)

Let Δ(a, b; x) denote the error term of the asymmetric two-dimensional divisor problem. In this paper we shall study the relation between the discrete mean value ${\sum_{n\leq T} \Delta^2(a,b;n)}$ and the continuous mean value ${\int_1^T\Delta^2(a,b;x)dx}$ .     

On the mean square of the error term for the asymmetric two-dimensional divisor problems(II)

Let Δ(a, b; x) denote the error term of the asymmetric two-dimensional divisor problem. In this paper we shall study the relation between the discrete mean value ?_{n ￡ T} D²(a,b;n){\sum_{n\leq T} \Delta^2(a,b;n)} and the continuous mean value ò₁^TD²(a,b;x)dx{\int_1^T\Delta^2(a,b;x)dx} .     

On the general asymmetric divisor problem

To ProfessorEkkehard Kr?tzel on his 60^th birthday     

On higher-power moments of the error term for the divisor problem with congruence conditions

For a positive integer n, the divisor function with congruence conditions d(n; l ₁, M ₁, l ₂, M ₂) denotes the number of factorizations n?=?n ₁ n ₂, where each of the factors ${n_i\in\mathbb{N}}$ belongs to a prescribed congruence class l _i modulo M _i ? (i?=?1, 2). In this paper we study the higher power moments of the error term in the asymptotic formula of ${\sum\nolimits_{n\leq M_1M_2x}d(n;l_1,M_1,l_2,M_2)}$ .     

On the average orders of the error term in the Dirichlet divisor problem

Let Δ(x) be the error term in the Dirichlet divisor problem. The purpose of this paper is to study the difference between two kinds of mean value formulas of Δ(x), that is, the mean value formulas and ∑_n?xΔ(n)^k with a natural number k. In particular we study the case k=2 and 3 in detail.     

Higher moments of the error term in the divisor problem

It is proved that, if k ≥ 2 is a fixed integer and 1 ? H ≤ (1/2)X, then $$ \int_{X - H}^{X + H} {\Delta _k^4 \left( x \right) } dx \ll _\varepsilon X^\varepsilon \left( {HX^{{{\left( {2k - 2} \right)} \mathord{\left/ {\vphantom {{\left( {2k - 2} \right)} k}} \right. \kern-\nulldelimiterspace} k}} + H^{{{\left( {2k - 3} \right)} \mathord{\left/ {\vphantom {{\left( {2k - 3} \right)} {\left( {2k + 1} \right)}}} \right. \kern-\nulldelimiterspace} {\left( {2k + 1} \right)}}} X^{{{\left( {8k - 8} \right)} \mathord{\left/ {\vphantom {{\left( {8k - 8} \right)} {\left( {2k + 1} \right)}}} \right. \kern-\nulldelimiterspace} {\left( {2k + 1} \right)}}} } \right), $$ where Δ _k (x) is the error term in the general Dirichlet divisor problem. The proof uses a Voronoï-type formula for Δ _k (x), and the bound of Robert-Sargos for the number of integers when the difference of four kth roots is small. The size of the error term in the asymptotic formula for the mth moment of Δ₂(x) is also investigated.     

除数和函数对平方补数的均值

对于任意正整数n的平方补数c（n）,研究了其除数和函数σ（c（n））均值的渐近性,并利用解析方法得到了一个渐近公式。     

Dirichlet series obtained from the error term in the Dirichlet divisor problem

In this paper we consider the Dirichlet series obtained from the error term in the Dirichlet divisor problem. We shall prove their analytic continuations and determine the locations of poles. We shall also discuss the relation between our results and the conjecture of Lau and Tsang on the mean square estimate of the error term.     

On an asymmetric divisor problem with congruence conditions

For fixed positive integersab, natural numbersl ₁k ₁,l ₂k ₂ andn, denote withd _a,b (l ₁,k ₁;l ₂,k ₂;n) the number of all (,)N² with ^{a b} =n,l ₁(modk ₁),l ₂(modk ₂). In the present paper we establish asymptotic formulas for the Dirichlet summatory function ofd _a,b (l ₁,k ₁;l ₂,k ₂;n) with both upper and lower estimates of the error term, all of them uniform in the moduli.     

Explicit representations of the integral containing the error term in the divisor problem

We shall investigate several properties of the integral $$ \int_1^\infty {t^{ - \theta } \Delta _k \left( t \right) log^j t dt} $$ with a natural number k, a non-negative integer j and a complex variable θ, where Δ _k (x) is the error term in the divisor problem of Dirichlet and Piltz. The main purpose of this paper is to apply the “elementary methods” and the “elementary formulas” to derive convergence properties and explicit representations of this integral with respect to θ for k = 2.     

On the error term in the mean square formula for the Riemann zeta-function in the critical strip

For 1/2<<1 fixed, letE (T) denote the error term in the asymptotic formula for . We obtain some new bounds forE (T), and an _-result which is the analogue of the strongest _-result in the classical Dirichlet divisor problem.     

Recent progress on the Dirichlet divisor problem and the mean square of the Riemann zeta-function

Let Δ(x) and E(t) denote respectively the remainder terms in the Dirichlet divisor problem and the mean square formula for the Riemann zeta-function on the critical line.This article is a survey of recent developments on the research of these famous error terms in number theory.These include upper bounds,Ω-results,sign changes,moments and distribution,etc.A few open problems are also discussed.     

On the Rankin-Selberg problem: higher power moments of the Riesz mean error term

LetΔ_1(x;φ) be the error term of the first Riesz mean of the Rankin-Selberg problem. We study the higher power moments ofΔ_1(x;φ) and derive an asymptotic formula for the 3-rd, 4-th and 5-th power moments by using Ivic's large value arguments and other techniques.     

A two-sided omega-theorem for an asymmetric divisor problem

In this article we study the arithmetic functiond _a,b (l,k;n) which is defined as the number of representationsn=v ^a w ^b withw lying in the residue classl modulok (a,b andl,k fixed positive integers). For the remainder term in the asymptotic formula for Σ_n≤xd_a,b(l,k,;n) we obtain an Ω_± (under a certain restriction onl andk) which is sharper than the known results for the corresponding “unrestricted” problem.     

Tong-type identity and the mean square of the error term for an extended Selberg class

In 1956, Tong established an asymptotic formula for the mean square of the error term of the summatory function of the Piltz divisor function d3(n). The aim of this paper is to generalize Tong's method to a class of Dirichlet series L(s) which satisfies a functional equation. Let a(n) be an arithmetical function related to a Dirichlet series L(s), and let E(x) be the error term of ′n xa(n). In this paper, after introducing a class of Diriclet series with a general functional equation(which contains the well-known Selberg class), we establish a Tong-type identity and a Tong-type truncated formula for the error term of the Riesz mean of the coefficients of this Dirichlet series L(s). This kind of Tong-type truncated formula could be used to study the mean square of E(x) under a certain assumption. In other words, we reduce the mean square of E(x) to the problem of finding a suitable constant σ*which is related to the mean square estimate of L(s). We shall represent some results of functions in the Selberg class of degrees 2–4.     

关于Smarandache LCM函数的一类均方差问题

利用初等及解析方法研究均方差(SL(n)-(Ω)(n)))2的均值分布问题,并获得了一个有趣的渐近公式.     

On the lower bounds for mean square error of empirical bayes estimators

The usual empirical Bayes setting is considered with θ being a shift or a scale parameter. A class of empirical Bayes estimators of a function b(θ) is proposed. The properties of the estimates are studied and mean square errors are calculated. The lower bounds are constructed for mean square errors of the empirical Bayes estimators over the class of all empirical Bayes estimators of b(θ). The results are applied to the case b(θ)=θ. The examples of the upper and lower bounds for mean square error are presented for the most popular families of conditional distributions. Added to the English translaion.