Showing total 4,306 results

101. Global attractivity in a non-monotone age-structured model with age-dependent diffusion and death rates

Author

M. Al-Jararha

Subjects

Homogeneous equilibrium solution, Global attractivity, Age-structured model, Non-monotone birth function, Age-dependent death rate, Age-dependent diffusion rate, Mathematics, QA1-939

Abstract

Abstract In this paper, the global attractivity of the homogeneous equilibrium solution for the diffusive age-structured model {∂u∂t+∂u∂a=D(a)∂2u∂x2−d(a)u,t≥t0≥Al>0,a≥0,00,00,00,a≥0, $$ \textstyle\begin{cases} \frac{\partial u}{\partial t}+\frac{\partial u}{\partial a}=D(a)\frac{ \partial^{2}{u}}{\partial x^{2}}-d(a)u, & t\geq t_{0}\geq A_{l}>0, a \geq 0, 0< x< \pi , \\ w(t,x)= \int_{\tau }^{A_{l}}u(t,a,x)\,da,& t\geq t_{0}\geq A_{l}>0, 0< x< \pi ,\tau \geq 0, \\ u(t,0,x)=f(w(t,x)), & t\geq t_{0}\geq A_{l}>0, 0< x< \pi ,\\ u_{x}(t,a,0)=u_{x}(t,a,\pi )=0, & t\geq t_{0}\geq A_{l}>0, a \geq 0, \end{cases} $$ is established when the diffusion and death rates, D(a) $D(a)$ and d(a) $d(a)$, respectively, are age dependent during the whole life of the species, and when the birth function f(w) $f(w)$ is nonmonotone. In the paper, we also present some demonstrative examples.

Published

2018

102. Uniqueness theorem on meromorphic functions and their difference operators

Author

Dan Liu, Bingmao Deng, and Mingliang Fang

Subjects

Uniqueness, Meromorphic functions, Difference operators, Mathematics, QA1-939

Abstract

Abstract In this paper, we study the uniqueness problems of meromorphic functions and their difference operators. Our main result is a difference analogue of a result of Jank–Mues–Volkmann, which is concerned with the uniqueness of an entire function sharing one finite value with its derivatives. Some recent papers studied the case of entire functions of finite order sharing a periodic small function to f. We consider the case of meromorphic functions of finite order sharing a polynomial, which is a more popular case. Examples are provided for our results.

Published

2018

103. Finite difference approach for variable order reaction–subdiffusion equations

Author

M. Adel

Subjects

Weighted average finite difference approximations, Variable order linear and nonlinear reaction–subdiffusion equation, Stability analysis, Numerical example, Mathematics, QA1-939

Abstract

Abstract The fractional reaction–subdiffusion equation is one of the most famous subdiffusion equations. These equations are widely used in recent years to simulate many physical phenomena. In this paper, we consider a new version of such equations, namely the variable order linear and nonlinear reaction–subdiffusion equation. A numerical study is introduced using the weighted average methods for the variable order linear and nonlinear reaction–subdiffusion equations. A stability analysis of the proposed method is given by a recently proposed procedure similar to the standard John von Neumann stability analysis. The paper is ended with the results of numerical examples that support the theoretical analysis.

Published

2018

104. Complete-closed time scales under shifts and related functions

Author

Chao Wang, Ravi P. Agarwal, Donal O’Regan, and Gaston M. N’Guérékata

Subjects

Time scales, Complete-closed, Shift functions, Mathematics, QA1-939

Abstract

Abstract In this paper, we introduce the concept of complete-closed time scales under translational and non-translational shifts and propose new definitions of special functions arising from dynamic equations on time scales including the concepts of almost periodic functions, almost automorphic functions and Stepanov almost automorphic functions. All the functions introduced in the paper are not only effective on periodic time scales under translations but are also valid on irregular time scales like qZ‾ $\overline{q^{\mathbb{Z}}}$, (−q)Z‾ $\overline{(-q)^{\mathbb{Z}}}$ and N±12 $\mathbb{N}^{\frac{1}{2}}_{\pm }$, etc.

Published

2018

105. On the difference equation xn+1=axn−l+bxn−k+f(xn−l,xn−k) $x_{n+1}=ax_{n-l}+bx_{n-k}+f ( x_{n-l},x_{n-k} )$

Author

Mahmoud A. E. Abdelrahman, George E. Chatzarakis, Tongxing Li, and Osama Moaaz

Subjects

Difference equation, Equilibrium point, Local stability, Periodic solution, Mathematics, QA1-939

Abstract

Abstract In this paper, we study the asymptotic behavior of the solutions of a new class of difference equations xn+1=axn−l+bxn−k+f(xn−l,xn−k), $$x_{n+1}=ax_{n-l}+bx_{n-k}+f ( x_{n-l},x_{n-k} ), $$ where l and k are nonnegative integers, a and b are nonnegative real numbers, the initial values x−s,x−s+1,…,x0 $x_{-s}, x_{-s+1},\ldots, x_{0}$ are positive real numbers, s=max{l,k} $s=\max\{l,k\}$, and f(u,v):(0,∞)2→(0,∞) $f (u,v ): ( 0,\infty ) ^{2}\rightarrow ( 0,\infty ) $ is a continuous and homogeneous real function of degree zero. We consider the stability, boundedness, and periodicity of the solutions of this equation which is the most general form of linear difference equations. Thus, the results in this paper apply to several other equations that are special cases of the studied equation. Moreover, we present a new method to study periodic solutions of period two.

Published

2018

106. Distributed constrained optimization via continuous-time mirror design

Author

Rui Sheng and Wei Ni

Subjects

Distributed convex optimization, Mirror descent, Multiagent, Constrained optimization, Mathematics, QA1-939

Abstract

Abstract Recently, distributed convex optimization using a multiagent system has received much attention by many researchers. This problem is frequently approached by combing the consensus algorithms in the multiagent literature and the gradient algorithms in the convex optimization literature. Compared with unconstrained distributed optimization, the constrained case is more challenging, and it is usually tackled by the projected gradient method. However, the projected gradient algorithm involves projection nonlinearity and thus is hard to analyze. To avoid gradient projection, in this paper, we present a novel distributed convex optimization algorithm in continuous time by using mirror design. The resulting optimization dynamics is smooth without using gradient projection and is designed in a primal-dual framework, where the primal and dual dynamics are respectively aided by the mirror descent and the mirror ascent. As for the merit of mirror design in our paper, it avoids gradient projection in the optimization dynamics design and removes the difficulty of analyzing projection nonlinearity. Furthermore, the mirror base primal-dual optimization dynamics facilitates more convenience construction of Lyapunov functions in the stability analysis.

Published

2018

107. Finite-time synchronization control relationship analysis for two classes of Markovian jump complex networks under feedback control

Author

Xin Wang, Kun Gao, Gang Chen, and Yuhua Xu

Subjects

Synchronization, Complex network, Time delay, Markovian jump, Control rule, Mathematics, QA1-939

Abstract

Abstract In this paper, finite-time synchronization problems for a class of nonlinear coupled Markovian jump delay time complex networks (NCMJDTCNs) with stochastic noises and a class of linear coupled Markovian jump delay time complex networks (LCMJDTCNs) with stochastic noises are investigated. Compared to the existing works [Li and Yang in IEEE Trans. Cybern. 46(1):171–180, 2016; Zhang et al. in Physica A 494:251–264, 2018; Liu and Chen in IEEE Trans. Neural Netw. Learn. Syst. 26(1):113–126, 2015; Jin et al. in IEEE Trans. Neural Netw. Learn. Syst. 23(9):1345–1355, 2012; Feng et al. in IEEE Access, 2018, https://doi.org/10.1109/ACCESS.2018.2836142; Tseng in Neural Netw. 86:18–31, 2017; Lei et al. in Neurocomputing 230:390–396, 2017; Cui et al. in J. Franklin Inst. 351:2543–2561, 2014; Wang et al. in Nonlinear Dyn. 79:47–61, 2015; Liu et al. in Neurocomputing 153:148–158, 2015], the main contribution of this paper consists of two new ideas which are applied to analyze a nonlinear coupling affecting synchronization dynamics of the NCMJDTCNs.

Published

2018

108. Random non-autonomous second order linear differential equations: mean square analytic solutions and their statistical properties

Author

J. Calatayud, J.-C. Cortés, M. Jornet, and L. Villafuerte

Subjects

Random second order linear difference and differential equation, Analytic second order stochastic process, L p ( Ω ) $\mathrm {L}^{p}(\Omega)$ random calculus, Uncertainty quantification, Mathematical modelling and stochastic computation, Mathematics, QA1-939

Abstract

Abstract In this paper we study random non-autonomous second order linear differential equations by taking advantage of the powerful theory of random difference equations. The coefficients are assumed to be stochastic processes, and the initial conditions are random variables both defined in a common underlying complete probability space. Under appropriate assumptions established on the data stochastic processes and on the random initial conditions, and using key results on difference equations, we prove the existence of an analytic stochastic process solution in the random mean square sense. Truncating the random series that defines the solution process, we are able to approximate the main statistical properties of the solution, such as the expectation and the variance. We also obtain error a priori bounds to construct reliable approximations of both statistical moments. We include a set of numerical examples to illustrate the main theoretical results established throughout the paper. We finish with an example where our findings are combined with Monte Carlo simulations to model uncertainty using real data.

Published

2018

109. Stability analysis of a two-patch predator–prey model with two dispersal delays

Author

Guowei Sun and Ali Mai

Subjects

Dispersal, Delay, Stability, Bifurcation, Predator–prey model, Mathematics, QA1-939

Abstract

Abstract This paper deals with a predator–prey model with both species in the delayed-dispersal case in a two-patch environment. The purpose of this paper is to study the effect of two dispersal delays on the stability of three equilibria. It turns out that the stability of the trivial equilibrium and the boundary equilibrium is delay-independent. However, the stability of the coexistence equilibrium is delay-dependent. Numerical simulations are performed to demonstrate the obtained results.

Published

2018

110. Dissipativity analysis and stabilization for discontinuous delayed complex-valued networks via matrix measure method

Author

Zengyun Wang, Jinde Cao, and Zhenyuan Guo

Subjects

Complex-valued networks, Dissipativity analysis, Differential inclusion, Matrix measure method, Generalized Halanay inequality, Mathematics, QA1-939

Abstract

Abstract In this paper, we discuss the dissipativity and stabilization problems via matrix measure strategy. First, we propose a way to construct complex-valued set-valued maps and give the basic framework of complex-valued differential inclusions. In addition, based on matrix measure strategy and the generalized Halanay inequality, we analyze the dissipativity of the addressed discontinuous complex-valued neural networks by using two different ways. Furthermore, we design a set of controllers to guarantee the exponential stability of the studied networks. The main contribution of this paper is an extension of the dissipativity results of traditional neural networks to discontinuous ones. Finally, we give numerical examples to substantiate the merits of the obtained results.

Published

2018

111. Calibration of the exponential Ornstein–Uhlenbeck process when spot prices are visible through the maximum log-likelihood method. Example with gold prices

Author

Carlos Armando Mejía Vega

Subjects

Commodities, Commodity modelling, Stochastic process, Exponential Ornstein–Uhlenbeck process, Maximum log-likelihood method, Parameters estimation, Mathematics, QA1-939

Abstract

Abstract The purpose of this paper is to present a methodological procedure to estimate the parameters of the exponential Ornstein–Uhlenbeck process, also known as the Schwartz (J. Finance 52(3):923–973, 1997) one-factor model, in situations where the spot price of the commodity is observable. The proposal consists of looking at the probability function of the process as a function of the unknown parameters in discrete time, known as the likelihood function. Then the logarithm of that expression is calculated as it is easier to work with it. Finally, the problem of determining the values of the parameters that maximize the sum of the individual log-likelihoods (joint log-likelihood function) is solved to obtain the estimation equations explicitly. In that sense, this work is relevant because as spot prices are available, it is possible to estimate the parameters directly without the necessity of using more elaborate approaches like the Kalman filter. Finally, the paper applies this methodology to the concrete case of one precious metal that has an observable spot price and for which some empirical and theoretical studies suggest that it presents a mean-reverting pattern, gold. The estimated parameters are consistent with previous works and with the original data and the least squares method.

Published

2018

112. On segmentation model for vector valued images and fast iterative solvers

Author

Noor Badshah, Fahim Ullah, and Matiullah

Subjects

Active contours, Vector valued images, Level sets, Partial differential equations, AOS method, MG method, Mathematics, QA1-939

Abstract

Abstract In this paper, we propose a new convex variational model for segmentation of vector valued images. The data term of the proposed model is based on the coefficient of variation, which works well in vector valued images having intensity inhomogeneity. Due to convexity of the model, it is independent of the placement of initial contour. Better performance of the proposed model can be seen from experimental results qualitatively and quantitatively. Images in practice are of large sizes, which makes numerical methods more important. In this paper, we also develop fast and stable numerical methods for solution of partial differential equation arisen from the minimization of the proposed model. We have developed a novel multigrid method based on a locally supported smoother. The proposed method is compared with the existing methods in terms of iterations and CPU time for vector valued images having large sizes.

Published

2018

113. The effect of parameters on positive solutions and asymptotic behavior of an unstirred chemostat model with B–D functional response

Author

Xiaozhou Feng, Suping Sun, Tongqian Zhang, and Xiaomin An

Subjects

Chemostat, Positive solutions, The fixed point index theory, Multiplicity, Mathematics, QA1-939

Abstract

Abstract This paper deals with the effect of parameters on properties of positive solutions and asymptotic behavior of an unstirred chemostat model with the Beddington–DeAngelis (denote by B–D) functional response under the Robin boundary condition. Firstly, we establish some a priori estimates and a sufficient condition for the existence of positive solutions (see (Feng et al. in J. Inequal. Appl. 2016(1):294, 2016)). Secondly, we study the effect of the small parameter k1 $k_{1}$ and sufficiently large k2 $k_{2}$ in B–D functional response, which shows that the model has at least two positive solutions. Thirdly, we investigate the case of sufficiently large k1 $k_{1}$. The results show that if k1 $k_{1}$ is sufficiently large, then the positive solution of this model is determined by a limiting equation. Finally, we present an asymptotic behavior of solutions depending on time. The main methods used in this paper include the fixed point index theory, bifurcation theory, perturbation technique, comparison principle, and persistence theorem.

Published

2018

114. Adaptive finite-time tracking control for nonlinear systems with unmodeled dynamics using neural networks

Author

Wenshun Lv, Fang Wang, and Yan Li

Subjects

Nonlinear systems, Unmodeled dynamics, Adaptive control, Backstepping, Radial basis function neural networks, Finite-time stability, Mathematics, QA1-939

Abstract

Abstract This paper presents a novel adaptive finite-time tracking control scheme for nonlinear systems. During the design process of control scheme, the unmodeled dynamics in nonlinear systems are taken into account. The radial basis function neural networks (RBFNNs) are adopted to approximate the unknown nonlinear functions. Meanwhile, based on RBFNNs, the assumptions with respect to unmodeled dynamics are also relaxed. This paper provides a new finite-time stability criterion, making the adaptive tracking control scheme more suitable in the practice than traditional methods. Combining RBFNNs and the backstepping technique, a novel adaptive controller is designed. Under the presented controller, the desired system performance is realized in finite time. Finally, a numerical example is presented to demonstrate the effectiveness of the proposed control method.

Published

2018

115. Adaptive neural network synchronization for uncertain strick-feedback chaotic systems subject to dead-zone input

Author

Guanjun Li

Subjects

Neural network, Chaos synchronization, Dead-zone, Mathematics, QA1-939

Abstract

Abstract In this paper, an adaptive neural network (NN) synchronization controller is designed for two identical strict-feedback chaotic systems (SFCSs) subject to dead-zone input. The dead-zone models together with the system uncertainties are approximated by NNs. The dynamic surface control (DSC) approach is applied in the synchronization controller design, and the traditional problem of “explosion of complexity” that usually occurs in the backstepping design can be avoided. The proposed synchronization method guarantees the synchronization errors tend to an arbitrarily small region. Finally, this paper presents two simulation examples to confirm the effectiveness and the robustness of the proposed control method.

Published

2018

116. On a kind of time optimal control problem of the heat equation

Author

Yifan Zhang

Subjects

Heat equation, Time-varying, Bang–bang property, Time optimal control problem, Mathematics, QA1-939

Abstract

Abstract In this paper, we consider a kind of time-varying bang–bang property of time optimal boundary controls for the heat equation. The time-varying bang–bang property in the interior domain has been considered in some papers, but regarding the time optimal boundary control problem it is still unsolved. In this paper, we determine that there exists at least one solution to the time optimal boundary control problem with time-varying controls.

Published

2018

117. Stability and bifurcation analysis for a single-species discrete model with stage structure

Author

Daiyong Wu, Min Zhao, and Hai Zhang

Subjects

Discrete model, Stage structure, Flip bifurcation, Non-hyperbolic, Mathematics, QA1-939

Abstract

Abstract In this paper, a single-species discrete model with stage structure is investigated. By analyzing the corresponding characteristic equations, the local asymptotic stability of non-negative equilibrium points and the existence of flip bifurcation are discussed. Using the center manifold theory, the stability of the non-hyperbolic equilibrium point is obtained. Based on bifurcation theory, we obtain the direction and the stability of a flip bifurcation at the positive equilibrium with the birth rate as the bifurcation parameter. Finally, some numerical simulations, including phase portraits, chaotic bands with period windows, and Lyapunov exponent methods, are performed to validate the theoretical results, which extends the results in previous papers.

Published

2018

118. Application of stochastic inequalities to global analysis of a nonlinear stochastic SIRS epidemic model with saturated treatment function

Author

Shengqiang Zhang, Xinzhu Meng, and Xinzeng Wang

Subjects

Stochastic SIRS epidemic model, Stochastic inequality, Saturated treatment, Standard incidence rate, Permanence in mean, Mathematics, QA1-939

Abstract

Abstract In this paper, we propose a new nonlinear stochastic SIRS epidemic model with standard incidence rate and saturated treatment function. The main purpose of this paper is to investigate the threshold dynamics of the nonlinear stochastic SIRS epidemic model by making use of stochastic inequality techniques. By using Lyapunov methods and Itô’s formula, we first prove the existence and uniqueness of a global positive solution for the corresponding limiting system. Furthermore, we obtain sufficient conditions for the extinction and persistence in mean of the nonlinear stochastic SIRS epidemic model by using the techniques of a series of stochastic inequalities. Finally, we provide some numerical simulations to illustrate the performance of our theoretical findings.

Published

2018

119. Well-posedness of a class of two-point boundary value problems associated with ordinary differential equations

Author

Ruyi Liu and Zhen Wu

Subjects

Ordinary differential equations, Two-point boundary value problems, Regular decoupling field, Monotonicity conditions, Linear transformation, Optimal control theory, Mathematics, QA1-939

Abstract

Abstract This paper introduces the regular decoupling field to study the existence and uniqueness of solutions of two-point boundary value problems for a class of ordinary differential equations which can be derived from the maximum principle in optimal control theory. The monotonicity conditions used to guarantee the existence and uniqueness of such equations are initially a special case of the regular decoupling field method. More generally, in case of the homogeneous equations, this paper generalizes the application scope of the monotonicity conditions method by using the linear transformation method. In addition, the linear transformation method can be used to handle the situation where the monotonicity conditions and regular decoupling field method cannot be directly applied. These two methods overall develop the well-posedness theory of two-point boundary value problems which has potential applications in optimal control and partial differential equation theory.

Published

2018

120. Almost periodic and asymptotically almost periodic functions: part I

Author

Dhaou Lassoued, Rahim Shah, and Tongxing Li

Subjects

almost periodic function, asymptotically almost periodic function, Mathematics, QA1-939

Abstract

Abstract In this paper, we review indispensable properties and characterizations of almost periodic functions and asymptotically almost periodic functions in Banach spaces. Special accent is put on the Stepanov generalizations of almost periodic functions and asymptotically almost periodic functions. We also recollect some basic results regarding equi-Weyl-almost periodic functions and Weyl-almost periodic functions. The class of asymptotically Weyl-almost periodic functions, introduced in this work, seems to be not considered elsewhere even in the scalar-valued case. We actually introduce eight new classes of asymptotically almost periodic functions and analyze relations between them. In order to make a picture as complete and clear as possible, several illustrating examples and counter-examples are given. It is worth noting that the topics dealt with in this paper seem to be of an intrinsic connection with the problem of existence and uniqueness of solutions of differential and difference equations, in both determinist and stochastic cases.

Published

2018

121. Coexistence of identical synchronization, antiphase synchronization and inverse full state hybrid projective synchronization in different dimensional fractional-order chaotic systems

Author

Adel Ouannas, Xiong Wang, Viet-Thanh Pham, Giuseppe Grassi, and Toufik Ziar

Subjects

coexistence of synchronization types, fractional-order systems, chaos synchronization, commensurate and incommensurate systems, nonidentical systems, Mathematics, QA1-939

Abstract

Abstract The topic related to the coexistence of different synchronization types between fractional-order chaotic systems is almost unexplored in the literature. Referring to commensurate and incommensurate fractional systems, this paper presents a new approach to rigorously study the coexistence of some synchronization types between nonidentical systems characterized by different dimensions and different orders. In particular, the paper shows that identical synchronization (IS), antiphase synchronization (AS), and inverse full state hybrid projective synchronization (IFSHPS) coexist when synchronizing a three-dimensional master system with a fourth-dimensional slave system. The approach, which can be applied to a wide class of chaotic/hyperchaotic fractional-order systems in the master-slave configuration, is based on two new theorems involving the fractional Lyapunov method and stability theory of linear fractional systems. Two examples are provided to highlight the capability of the conceived method. In particular, referring to commensurate systems, the coexistence of IS, AS, and IFSHPS is successfully achieved between the chaotic three-dimensional Rössler system of order 2.7 and the hyperchaotic four-dimensional Chen system of order 3.84. Finally, referring to incommensurate systems, the coexistence of IS, AS, and IFSHPS is successfully achieved between the chaotic three-dimensional Lü system of order 2.955 and the hyperchaotic four-dimensional Lorenz system of order 3.86.

Published

2018

122. Sandwich synchronization of memristor-based hyperchaos systems with time delays

Author

Hongjuan Wu, Jiang Xiong, Xiang Hu, Yuming Feng, and Liangliang Li

Subjects

memristor-based, hyperchaotic system, time delays, synchronization, sandwich control, Mathematics, QA1-939

Abstract

Abstract In this paper, a memristor-based hyperchaotic system is introduced. Considering time delays between the drive system and the response system in the process of synchronization, this paper designs one kind of flexible sandwich controller, which includes a rest in the sandwich structure, to realize the synchronization between two memristor-based hyperchaotic systems. Based on Lyapunov stability theory, matrix inequality, sandwich control and considering time delays, the exponential synchronization conditions for the memristor-based hyperchaotic systems with time delays via sandwich control are given. Finally, simulation results are displayed to verify the effectiveness and feasibility of this method.

Published

2018

123. Analysis of the equilibrium points of background neural networks with uniform firing rate

Author

Fang Xu, Lingling Liu, and Jianying Xiao

Subjects

equilibrium point, Rolle’s theorem, background neural networks, Mathematics, QA1-939

Abstract

Abstract In this paper, we give a complete analysis of the equilibrium points of background neural networks with uniform firing rates. By using continuity, monotonicity of some functions and Rolle’s theorem, the number of equilibrium points and their locations are obtained. Moreover, some novel sufficient conditions are given to guarantee the stability of the equilibrium points for the network model by utilizing Taylor’s theorem. A simulation example is conducted to illustrate the theories developed in this paper.

Published

2017

124. Enhanced robust finite-time passivity for Markovian jumping discrete-time BAM neural networks with leakage delay

Author

C Sowmiya, R Raja, Jinde Cao, G Rajchakit, and Ahmed Alsaedi

Subjects

LMIs, Markovian jumping systems, leakage delay, bidirectional associative memory, discrete-time neural networks, passivity and stability analysis, Mathematics, QA1-939

Abstract

Abstract This paper is concerned with the problem of enhanced results on robust finite-time passivity for uncertain discrete-time Markovian jumping BAM delayed neural networks with leakage delay. By implementing a proper Lyapunov-Krasovskii functional candidate, the reciprocally convex combination method together with linear matrix inequality technique, several sufficient conditions are derived for varying the passivity of discrete-time BAM neural networks. An important feature presented in our paper is that we utilize the reciprocally convex combination lemma in the main section and the relevance of that lemma arises from the derivation of stability by using Jensen’s inequality. Further, the zero inequalities help to propose the sufficient conditions for finite-time boundedness and passivity for uncertainties. Finally, the enhancement of the feasible region of the proposed criteria is shown via numerical examples with simulation to illustrate the applicability and usefulness of the proposed method.

Published

2017

125. A matched space for time scales and applications to the study on functions

Author

Chao Wang, Ravi P Agarwal, and Donal O’Regan

Subjects

time scales, matched space, periodic functions, almost periodic functions, almost automorphic functions, solutions for dynamic equations, Mathematics, QA1-939

Abstract

Abstract In this paper, using the algebraic structure of the Abelian group, we introduce the concept of a matched space for time scales, and we construct the algebraic structure of matched spaces to solve the closedness of time scales under non-translational shifts. Using a matched space for time scales, a new concept of periodic time scales is introduced. Based on it, new concepts of periodic functions, almost periodic functions and almost automorphic functions whose concepts were defined on translations of their arguments are proposed through non-translational shifts. The results in this paper provide new methods to consider periodic solution, almost periodic solution and almost automorphic solutions for q-difference equations and others on irregular time scales via the background of the algebraic structure.

Published

2017

126. Qualitative behaviors of the high-order Lorenz-Stenflo chaotic system arising in mathematical physics describing the atmospheric acoustic-gravity waves

Author

Guangyun Zhang, Fuchen Zhang, and Min Xiao

Subjects

High-order Lorenz-Stenflo system, Lyapunov exponents, Lyapunov stability, domain of attraction, nonlinear dynamics, Mathematics, QA1-939

Abstract

Abstract The boundedness of chaotic systems plays an important role in investigating the stability of the equilibrium, estimating the Lyapunov dimension of attractors, the Hausdorff dimension of attractors, the existence of periodic solutions, chaos control, and chaos synchronization. However, as far as the authors know, there are only a few papers dealing with bounds of high-order chaotic systems due to their complex algebraic structure. To sort this out, in this paper, we study the bounds of a high-order Lorenz-Stenflo system arising in mathematical physics. Based on Lyapunov stability theory, we show that there exists a globally exponential attractive set for this system. The innovation of the paper is that we not only prove that this system is globally bounded for all the parameters, but also give a family of mathematical expressions of global exponential attractive sets of this system with respect to its parameters. We also study some other dynamical characteristics of this chaotic system such as invariant sets and chaotic behaviors. To justify the theoretical analysis, we carry out detailed numerical simulations.

Published

2017

127. Robust stabilization of hybrid uncertain stochastic systems with time-varying delay by discrete-time feedback control

Author

Yuyuan Li and Chunhai Kou

Subjects

hybrid uncertain stochastic systems, robust stabilization, time-varying delay, discrete-time feedback control, Razumikhin technique, Mathematics, QA1-939

Abstract

Abstract This paper is concerned with the robust stabilization problem for a class of continuous-time hybrid uncertain stochastic systems with time-varying delay. Our attention is focused on the design of a feedback controller based on discrete-time state observations such that, for all admissible uncertainties, the closed-loop system is robustly exponentially stable in the mean square, independent of the time delay. By employing the Razumikhin technique, sufficient conditions are firstly established to guarantee the existence of the desired robust controller; they are given in terms of linear matrix inequalities (LMIs). It should be pointed out that in this paper the time-varying delay is just required to be a bounded function rather than a bounded differentiable one as in most existing results. The developed theory is illustrated by a numerical example.

Published

2017

128. Finite-time anti-synchronization of time-varying delayed neural networks via feedback control with intermittent adjustment

Author

Xin Sui, Yongqing Yang, Fei Wang, and Lingzhong Zhang

Subjects

finite-time anti-synchronization, intermittent adjustment feedback control, Lyapunov functional, Mathematics, QA1-939

Abstract

Abstract This paper investigates the finite-time anti-synchronization of time-varying delayed neural networks. A simple intermittent adjustment feedback controller is designed to ensure the drive-response systems realize anti-synchronization in a finite time. By employing some differential inequalities and finite-time stability theory, some novel and effective finite-time anti-synchronization criteria are derived based on the Lyapunov functional method. This paper extends some traditional anti-synchronization criteria by using intermittent adjustment feedback control. Finally, two numerical examples are given to show the effectiveness of the proposed method.

Published

2017

129. Existence and multiplicity of weak solutions for a nonlinear impulsive ( q , p ) $(q,p)$ -Laplacian dynamical system

Author

Xiaoxia Yang

Subjects

( q , p ) $(q,p)$ -Laplacian, existence, multiplicity, nontrivial solution, variational methods, Mathematics, QA1-939

Abstract

Abstract In this paper, we investigate the existence and multiplicity of nontrivial weak solutions for a class of nonlinear impulsive ( q , p ) $(q,p)$ -Laplacian dynamical systems. The key contributions of this paper lie in (i) Exploiting the least action principle, we deduce that the system we are interested in has at least one weak solution if the potential function has sub- ( q , p ) $(q,p)$ growth or ( q , p ) $(q,p)$ growth; (ii) Employing a critical point theorem due to Ding (Nonlinear Anal. 25(11):1095-1113, 1995), we derive that the system involved has infinitely many weak solutions provided that the potential function is even.

Published

2017

130. Controllability for a new class of fractional neutral integro-differential evolution equations with infinite delay and nonlocal conditions

Author

Jun Du, Wei Jiang, Denghao Pang, and Azmat Ullah Khan Niazi

Subjects

controllability, fractional integro-differential equations, neutral evolution equations, infinite delay, nonlocal conditions, fixed point theorem, Mathematics, QA1-939

Abstract

Abstract In this paper, we apply the fractional calculus and a suitable fixed point theorem with the measure of noncompactness to give the sufficient conditions of the controllability for a new class of fractional neutral integro-differential evolution systems with infinite delay and nonlocal conditions. The results are obtained here under some weakly noncompactness conditions. Thus they improve and generalize many well-known results. At the end of this paper, two examples are given to explain our abstract conclusions.

Published

2017

131. Multi-Lah numbers and multi-Stirling numbers of the first kind

Author

Seongho Park, Hye Kyung Kim, Taekyun Kim, Dae San Kim, and Hyunseok Lee

Subjects

Pure mathematics, Algebra and Number Theory, Partial differential equation, Recurrence relation, Mathematics - Number Theory, Logarithm, Multiple logarithm, Applied Mathematics, Stirling numbers of the first kind, Multi-Lah numbers, Multi-Bernoulli numbers, Lah number, 11B68, 11B73, 11B83, Multi-Stirling numbers of the first kind, Ordinary differential equation, FOS: Mathematics, QA1-939, Number Theory (math.NT), Analysis, Mathematics

Abstract

In this paper, we introduce multi-Lah numbers and multi-Stirling numbers of the first kind and recall multi-Bernoulli numbers, all of whose generating functions are given with the help of multiple logarithm. The aim of this paper is to study several relations among those three numbers. In more detail, we represent the multi-Bernoulli numbers in terms of the multi-Stirling numbers of the first kind and vice versa, and the multi-Lah numbers in terms of multi-Stirling numbers. In addition, we deduce a recurrence relation for multi-Lah numbers, Comment: 8 pages

Published

2021

132. On generalized Bessel–Maitland function

Author

H. M. Zayed

Subjects

Monotonicity, Algebra and Number Theory, Functional analysis, Applied Mathematics, Order (ring theory), Function (mathematics), Lambda, Combinatorics, symbols.namesake, Multiplication theorem, symbols, Differential properties, QA1-939, Integral representation, Generalized Bessel–Maitland and Struve functions, Beta function, Analysis, Bessel function, Quotient, Mellin–Barnes integral representation, Mathematics

Abstract

An approach to the generalized Bessel–Maitland function is proposed in the present paper. It is denoted by$\mathcal{J}_{\nu , \lambda }^{\mu }$Jν,λμ, where$\mu >0$μ>0and$\lambda ,\nu \in \mathbb{C\ }$λ,ν∈Cget increasing interest from both theoretical mathematicians and applied scientists. The main objective is to establish the integral representation of$\mathcal{J}_{\nu ,\lambda }^{\mu }$Jν,λμby applying Gauss’s multiplication theorem and the representation for the beta function as well as Mellin–Barnes representation using the residue theorem. Moreover, themth derivative of$\mathcal{J}_{\nu ,\lambda }^{\mu }$Jν,λμis considered, and it turns out that it is expressed as the Fox–Wright function. In addition, the recurrence formulae and other identities involving the derivatives are derived. Finally, the monotonicity of the ratio between two modified Bessel–Maitland functions$\mathcal{I}_{\nu ,\lambda }^{\mu }$Iν,λμdefined by$\mathcal{I}_{\nu ,\lambda }^{\mu }(z)=i^{-2\lambda -\nu }\mathcal{J}_{ \nu ,\lambda }^{\mu }(iz)$Iν,λμ(z)=i−2λ−νJν,λμ(iz)of a different order, the ratio between modified Bessel–Maitland and hyperbolic functions, and some monotonicity results for$\mathcal{I}_{\nu ,\lambda }^{\mu }(z)$Iν,λμ(z)are obtained where the main idea of the proofs comes from the monotonicity of the quotient of two Maclaurin series. As an application, some inequalities (like Turán-type inequalities and their reverse) are proved. Further investigations on this function are underway and will be reported in a forthcoming paper.

Published

2021

133. An uncertain SIR rumor spreading model

Author

Qing Cui, Hang Sun, and Yuhong Sheng

Subjects

Computer Science::Computer Science and Game Theory, Rumor spreading, Picard–Lindelöf theorem, Uncertainty theory, Differential equation, Stability (learning theory), 02 engineering and technology, 01 natural sciences, Existence and uniqueness, 010305 fluids & plasmas, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, QA1-939, Applied mathematics, Computer Science::Data Structures and Algorithms, Mathematics, Algebra and Number Theory, Partial differential equation, Applied Mathematics, Computer Science::Social and Information Networks, Liu process, Rumor, Ordinary differential equation, 020201 artificial intelligence & image processing, Stability, Analysis

Abstract

In this paper, an uncertain SIR (spreader, ignorant, stifler) rumor spreading model driven by one Liu process is formulated to investigate the influence of perturbation in the transmission mechanism of rumor spreading. The deduced process of the uncertain SIR rumor spreading model is presented. Then an existence and uniqueness theorem concerning the solution is proved. Moreover, the stability of uncertain SIR rumor spreading differential equation is proved. In addition, the influence of different parameters on rumor spreading is analyzed through numerical simulation. This paper also presents a paradox of stochastic SIR rumor spreading model.

Published

2021

134. Fractional isospectral and non-isospectral AKNS hierarchies and their analytic methods for N-fractal solutions with Mittag-Leffler functions

Author

Sheng Zhang, Bo Xu, and Yufeng Zhang

Subjects

Pure mathematics, N-fractal solutions with Mittag-Leffler functions, 020209 energy, Local fractional order partial derivative, 02 engineering and technology, Bilinear form, 01 natural sciences, 0202 electrical engineering, electronic engineering, information engineering, QA1-939, 0101 mathematics, Nonlinear Sciences::Pattern Formation and Solitons, Mathematics, Algebra and Number Theory, Partial differential equation, Inverse scattering transform, Hirota bilinear method, Applied Mathematics, Fractional order isospectral AKNS hierarchy, Fractional order non-isospectral AKNS hierarchy, 010101 applied mathematics, Nonlinear system, Isospectral, Nonlinear Sciences::Exactly Solvable and Integrable Systems, Ordinary differential equation, Partial derivative, Soliton, Analysis

Abstract

Ablowitz–Kaup–Newell–Segur (AKNS) linear spectral problem gives birth to many important nonlinear mathematical physics equations including nonlocal ones. This paper derives two fractional order AKNS hierarchies which have not been reported in the literature by equipping the AKNS spectral problem and its adjoint equations with local fractional order partial derivative for the first time. One is the space-time fractional order isospectral AKNS (stfisAKNS) hierarchy, three reductions of which generate the fractional order local and nonlocal nonlinear Schrödinger (flnNLS) and modified Kortweg–de Vries (fmKdV) hierarchies as well as reverse-t NLS (frtNLS) hierarchy, and the other is the time-fractional order non-isospectral AKNS (tfnisAKNS) hierarchy. By transforming the stfisAKNS hierarchy into two fractional bilinear forms and reconstructing the potentials from fractional scattering data corresponding to the tfnisAKNS hierarchy, three pairs of uniform formulas of novel N-fractal solutions with Mittag-Leffler functions are obtained through the Hirota bilinear method (HBM) and the inverse scattering transform (IST). Restricted to the Cantor set, some obtained continuous everywhere but nondifferentiable one- and two-fractal solutions are shown by figures directly. More meaningfully, the problems worth exploring of constructing N-fractal solutions of soliton equation hierarchies by HBM and IST are solved, taking stfisAKNS and tfnisAKNS hierarchies as examples, from the point of view of local fractional order derivatives. Furthermore, this paper shows that HBM and IST can be used to construct some N-fractal solutions of other soliton equation hierarchies.

Published

2021

135. A new generalization of some quantum integral inequalities for quantum differentiable convex functions

Author

Hüseyin Budak, Yi-Xia Li, Mujahid Abbas, Yu-Ming Chu, Muhammad Ali, and [Belirlenecek]

Subjects

Midpoint inequalities, Inequality, Generalization, media_common.quotation_subject, Mathematics::Classical Analysis and ODEs, Identity (mathematics), Hadamard inequality, QA1-939, Applied mathematics, Differentiable function, Quantum, Mathematics, media_common, Quantum calculus, Algebra and Number Theory, Partial differential equation, Convex functions, Applied Mathematics, Hermite&#8211, Trapezoid inequalities, Hermite–Hadamard inequality, Ordinary differential equation, Hermite-Hadamard Inequalities, Convex function, Analysis

Abstract

In this paper, we offer a new quantum integral identity, the result is then used to obtain some new estimates of Hermite-Hadamard inequalities for quantum integrals. The results presented in this paper are generalizations of the comparable results in the literature on Hermite-Hadamard inequalities. Several inequalities, such as the midpoint-like integral inequality, the Simpson-like integral inequality, the averaged midpoint-trapezoid-like integral inequality, and the trapezoid-like integral inequality, are obtained as special cases of our main results. Natural Science Foundation of ChinaNational Natural Science Foundation of China (NSFC) [61673169, 11301127, 11701176, 11626101, 11601485, 11971241] The work was supported by the Natural Science Foundation of China (Grant Nos. 61673169, 11301127, 11701176, 11626101, 11601485, 11971241). WOS:000646075900002 2-s2.0-85105001243

Published

2021

136. Generalized degenerate Bernoulli numbers and polynomials arising from Gauss hypergeometric function

Author

Taekyun Kim, Han-Young Kim, Lee-Chae Jang, Dae San Kim, and Hyunseok Lee

Subjects

Pure mathematics, Generalized degenerate Bernoulli polynomials, Algebra and Number Theory, Mathematics::Combinatorics, Mathematics - Number Theory, Applied Mathematics, lcsh:Mathematics, Degenerate energy levels, 11B68, 11B73, 11B83, 33C05, Stirling numbers of the second kind, lcsh:QA1-939, Bernoulli polynomials, Generalized degenerate Bernoulli numbers, symbols.namesake, Number theory, Ordinary differential equation, Degenerate type Eulerian numbers, FOS: Mathematics, symbols, Number Theory (math.NT), Stirling polynomials, Bernoulli number, Analysis, Mathematics, Unit interval

Abstract

In a previous paper, Rahmani introduced a new family of p-Bernoulli numbers and polynomials by means of the Gauss hypergeometric function. Motivated by this paper and as a degenerate version of those numbers and polynomials, we introduce the generalized degenerate Bernoulli numbers and polynomials again by using the Gauss hypergeometric function. In addition, we introduce the degenerate type Eulerian numbers as a degenerate version of Eulerian numbers. For the generalized degenerate Bernoulli numbers, we express them in terms of the degenerate Stirling numbers of the second kind, of the degenerate type Eulerian numbers, of the degenerate $p$-Stirling numbers of the second kind and of an integral on the unit interval. As to the generalized degenerate Bernoulli polynomials, we represent them in terms of the degenerate Stirling polynomials of the second kind., 11 pages

Published

2021

137. A predator–prey model involving variable-order fractional differential equations with Mittag-Leffler kernel

Author

Zareen A. Khan, José Francisco Gómez-Aguilar, Guillermo Fernández-Anaya, Aziz Khan, and Hashim M. Alshehri

Subjects

Fixed-point theorem, 01 natural sciences, 010305 fluids & plasmas, Mittag-Leffler kernel, 0103 physical sciences, Applied mathematics, Quantitative Biology::Populations and Evolution, Uniqueness, 0101 mathematics, Adams–Bashforth–Moulton scheme, Mathematics, Atangana–Baleanu FO derivative, Algebra and Number Theory, Partial differential equation, Applied Mathematics, Numerical analysis, lcsh:Mathematics, Function (mathematics), lcsh:QA1-939, 010101 applied mathematics, Variable-order FO derivative, Predator–prey model, Kernel (statistics), Ordinary differential equation, Constant (mathematics), Analysis

Abstract

This paper is about to formulate a design of predator–prey model with constant and time fractional variable order. The predator and prey act as agents in an ecosystem in this simulation. We focus on a time fractional order Atangana–Baleanu operator in the sense of Liouville–Caputo. Due to the nonlocality of the method, the predator–prey model is generated by using another FO derivative developed as a kernel based on the generalized Mittag-Leffler function. Two fractional-order systems are assumed, with and without delay. For the numerical solution of the models, we not only employ the Adams–Bashforth–Moulton method but also explore the existence and uniqueness of these schemes. We use the fixed point theorem which is useful in describing the existence of a new approach with a particular set of solutions. For the illustration, several numerical examples are added to the paper to show the effectiveness of the numerical method.

Published

2021

138. Stable weak solutions to weighted Kirchhoff equations of Lane–Emden type

Author

Hongwang Yu, Hongwei Yang, and Yunfeng Wei

Subjects

Weighted Kirchhoff equations, Lane–Emden nonlinearity, Algebra and Number Theory, Functional analysis, Applied Mathematics, lcsh:Mathematics, 010102 general mathematics, Zero (complex analysis), Type (model theory), lcsh:QA1-939, 01 natural sciences, Kirchhoff equations, 010101 applied mathematics, Combinatorics, Grushin operator, Liouville type theorem, Stable weak solutions, Nabla symbol, 0101 mathematics, Analysis, Mathematics

Abstract

This paper is concerned with the Liouville type theorem for stable weak solutions to the following weighted Kirchhoff equations: $$\begin{aligned}& -M \biggl( \int_{\mathbb{R}^{N}}\xi(z) \vert \nabla_{G}u \vert ^{2}\,dz \biggr){ \operatorname{div}}_{G} \bigl(\xi(z) \nabla_{G}u \bigr) \\& \quad=\eta(z) \vert u \vert ^{p-1}u,\quad z=(x,y) \in \mathbb{R}^{N}=\mathbb{R}^{N_{1}}\times\mathbb{R}^{N_{2}}, \end{aligned}$$ − M ( ∫ R N ξ ( z ) | ∇ G u | 2 d z ) div G ( ξ ( z ) ∇ G u ) = η ( z ) | u | p − 1 u , z = ( x , y ) ∈ R N = R N 1 × R N 2 , where $M(t)=a+bt^{k}$ M ( t ) = a + b t k , $t\geq0$ t ≥ 0 , with $a,b,k\geq0$ a , b , k ≥ 0 , $a+b>0$ a + b > 0 , $k=0$ k = 0 if and only if $b=0$ b = 0 . Let $N=N_{1}+N_{2}\geq2$ N = N 1 + N 2 ≥ 2 , $p>1+2k$ p > 1 + 2 k and $\xi(z),\eta(z)\in L^{1}_{\mathrm{loc}}(\mathbb{R}^{N})\setminus\{ 0\}$ ξ ( z ) , η ( z ) ∈ L loc 1 ( R N ) ∖ { 0 } be nonnegative functions such that $\xi(z)\leq C\|z\|_{G}^{\theta}$ ξ ( z ) ≤ C ∥ z ∥ G θ and $\eta(z)\geq C'\|z\|_{G}^{d}$ η ( z ) ≥ C ′ ∥ z ∥ G d for large $\|z\|_{G}$ ∥ z ∥ G with $d>\theta-2$ d > θ − 2 . Here $\alpha\geq0$ α ≥ 0 and $\|z\|_{G}=(|x|^{2(1+\alpha)}+|y|^{2})^{\frac{1}{2(1+\alpha)}}$ ∥ z ∥ G = ( | x | 2 ( 1 + α ) + | y | 2 ) 1 2 ( 1 + α ) . $\operatorname{div}_{G}$ div G (resp., $\nabla_{G}$ ∇ G ) is Grushin divergence (resp., Grushin gradient). Under some appropriate assumptions on k, θ, d, and $N_{\alpha}=N_{1}+(1+\alpha)N_{2}$ N α = N 1 + ( 1 + α ) N 2 , the nonexistence of stable weak solutions to the problem is obtained. A distinguished feature of this paper is that the Kirchhoff function M could be zero, which implies that the above problem is degenerate.

Published

2021

139. On nonlinear pantograph fractional differential equations with Atangana–Baleanu–Caputo derivative

Author

Saeed M. Ali, Mohammed S. Abdo, Manar A. Alqudah, Kishor D. Kucche, Thabet Abdeljawad, and Mdi Begum Jeelani

Subjects

Algebra and Number Theory, Partial differential equation, Fixed point theorem, Applied Mathematics, lcsh:Mathematics, 010102 general mathematics, Fixed-point theorem, ABC-Caputo pantograph fractional differential equation, Differential operator, lcsh:QA1-939, 01 natural sciences, Integral equation, Generalized Gronwall inequality, 010305 fluids & plasmas, Nonlinear system, Ordinary differential equation, 0103 physical sciences, Applied mathematics, Uniqueness, Nonlocal conditions, 0101 mathematics, Contraction principle, Analysis, Mathematics

Abstract

In this paper, we obtain sufficient conditions for the existence and uniqueness results of the pantograph fractional differential equations (FDEs) with nonlocal conditions involving Atangana–Baleanu–Caputo (ABC) derivative operator with fractional orders. Our approach is based on the reduction of FDEs to fractional integral equations and on some fixed point theorems such as Banach’s contraction principle and the fixed point theorem of Krasnoselskii. Further, Gronwall’s inequality in the frame of the Atangana–Baleanu fractional integral operator is applied to develop adequate results for different kinds of Ulam–Hyers stabilities. Lastly, the paper includes an example to substantiate the validity of the results.

Published

2021

140. On fractional boundary value problems involving fractional derivatives with Mittag-Leffler kernel and nonlinear integral conditions

Author

Mohammed S. Abdo, Thabet Abdeljawad, Kamal Shah, and Saeed M. Ali

Subjects

Algebra and Number Theory, Partial differential equation, Differential equation, Integral conditions, Applied Mathematics, lcsh:Mathematics, 010102 general mathematics, Fixed-point theorem, Fixed point theorems, lcsh:QA1-939, 01 natural sciences, Integral equation, 010305 fluids & plasmas, Fractional calculus, Nonlinear system, Ordinary differential equation, 0103 physical sciences, Applied mathematics, Boundary value problem, Atangana–Baleanu–Caputo fractional derivative, 0101 mathematics, Implicit fractional differential equations, Analysis, Mathematics

Abstract

In this paper, we consider two classes of boundary value problems for nonlinear implicit differential equations with nonlinear integral conditions involving Atangana–Baleanu–Caputo fractional derivatives of orders$00<ϑ≤1and$11<ϑ≤2. We structure the equivalent fractional integral equations of the proposed problems. Further, the existence and uniqueness theorems are proved with the aid of fixed point theorems of Krasnoselskii and Banach. Lastly, the paper includes pertinent examples to justify the validity of the results.

Published

2021

141. Source degenerate identification problems with smoothing overdetermination.

Author

Awawdeh, Fadi, Alomari, AK, and Abu-Falahah, Ibraheem

Subjects

IDENTIFICATION, HYPOTHESIS, PHYSICS, MATHEMATICS, DIFFERENTIAL equations

Abstract

We consider degenerate identification problems with smoothing overdetermination in abstract spaces. We establish an identifiability result using a projection method and suitable hypotheses on the operators involved and develop an identification method by reformulating the problem into a nondegenerate problem. Then we use perturbation results for linear operators to solve the regular problem. The introduced identification method permits one to solve the problems under the minimum restrictions on the input data. Finally, we provide applications to degenerate differential equations that appear in mathematical physics to support the theoretical results. [ABSTRACT FROM AUTHOR]

Published

2017

142. The composition of extended Mittag-Leffler functions with pathway integral operator.

Author

Rahman, G, Ghaffar, A, Mubeen, S, Arshad, M, and Khan, SU

Subjects

*MATHEMATICAL functions, *INTEGRAL operators, *MATHEMATICAL formulas, *OPERATOR theory, *MATHEMATICS

Abstract

In this paper, we present certain composition formulae of the pathway fractional integral operators associated with two extended Mittag-Leffler functions. Here, we find out the relevant connections of some particular cases of the main results with those earlier ones. [ABSTRACT FROM AUTHOR]

Published

2017

143. Analytical properties of the Hurwitz–Lerch zeta function.

Author

Nadeem, Raghib, Usman, Talha, Nisar, Kottakkaran Sooppy, and Baleanu, Dumitru

Subjects

MELLIN transform, INTEGRAL transforms, ZETA functions, BETA functions, GENERATING functions, MATHEMATICS

Abstract

In the present paper, we aim to extend the Hurwitz–Lerch zeta function Φ δ , ς ; γ (ξ , s , υ ; p) involving the extension of the beta function (Choi et al. in Honam Math. J. 36(2):357–385, 2014). We also study the basic properties of this extended Hurwitz–Lerch zeta function which comprises various integral formulas, a derivative formula, the Mellin transform, and the generating relation. The fractional kinetic equation for an extended Hurwitz–Lerch zeta function is also obtained from an application point of view. Furthermore, we obtain certain interesting relations in the form of particular cases. [ABSTRACT FROM AUTHOR]

Published

2020

144. Alternating double t-values and T-values.

Author

Quan, Junjie

Subjects

NUMBER theory, ODD numbers, MATHEMATICS

Abstract

Recently, Hoffman (Commun. Number Theory Phys. 13:529–567, 2019), Kaneko and Tsumura (Tsukuba J. Math. (in press), 2020) introduced and systematically studied two variants of multiple zeta values of level two, i.e., multiple t-values and multiple T-values, respectively. In this paper, by the contour integration and residue theorem, we establish two general identities, which further reduce to the expressions of the alternating double t-values and T-values. Some examples are also provided. [ABSTRACT FROM AUTHOR]

Published

2020

145. On the weighted fractional Pólya–Szegö and Chebyshev-types integral inequalities concerning another function

Author

Muhammad Samraiz, Kottakkaran Sooppy Nisar, Sajid Iqbal, Dumitru Baleanu, and Gauhar Rahman

Subjects

Pure mathematics, Algebra and Number Theory, Partial differential equation, Chebyshev functional, Applied Mathematics, lcsh:Mathematics, Fractional integrals, Function (mathematics), Type (model theory), lcsh:QA1-939, Chebyshev filter, Kernel (algebra), Cover (topology), Bounded function, Ordinary differential equation, Weighted fractional integrals, Inequalities, Analysis, Mathematics

Abstract

The primary objective of this present paper is to establish certain new weighted fractional Pólya–Szegö and Chebyshev type integral inequalities by employing the generalized weighted fractional integral involving another function Ψ in the kernel. The inequalities presented in this paper cover some new inequalities involving all other type weighted fractional integrals by applying certain conditions on $\omega (\theta )$ ω ( θ ) and $\Psi (\theta )$ Ψ ( θ ) . Also, the Pólya–Szegö and Chebyshev type integral inequalities for all other type fractional integrals, such as the Katugampola fractional integrals, generalized Riemann–Liouville fractional integral, conformable fractional integral, and Hadamard fractional integral, are the special cases of our main results with certain choices of $\omega (\theta )$ ω ( θ ) and $\Psi (\theta )$ Ψ ( θ ) . Additionally, examples of constructing bounded functions are also presented in the paper.

Published

2020

146. On a Kirchhoff diffusion equation with integral condition

Author

Dumitru Baleanu, Nguyen Hoang Luc, Nguyen Huu Can, and Danh Hua Quoc Nam

Subjects

Algebra and Number Theory, Partial differential equation, Diffusion equation, Functional analysis, Banach fixed-point theorem, Applied Mathematics, lcsh:Mathematics, 010102 general mathematics, Mathematical analysis, Order (ring theory), lcsh:QA1-939, 01 natural sciences, 010101 applied mathematics, Sobolev space, Well-posedness, Hadamard transform, Ordinary differential equation, Regularization, 0101 mathematics, Nonlocal problem, Analysis, Mathematics, Kirchhoff-type problems

Abstract

This paper is devoted to Kirchhoff-type parabolic problem with nonlocal integral condition. Our problem has many applications in modeling physical and biological phenomena. The first part of our paper concerns the local existence of the mild solution in Hilbert scales. Our results can be studied into two cases: homogeneous case and inhomogeneous case. In order to overcome difficulties, we applied Banach fixed point theorem and some new techniques on Sobolev spaces. The second part of the paper is to derive the ill-posedness of the mild solution in the sense of Hadamard.

Published

2020

147. Some expansion formulas for incomplete H- and H̅-functions involving Bessel functions

Author

Sanjay Bhatter, Sunil Dutt Purohit, Sapna Meena, and Kamlesh Jangid

Subjects

Pure mathematics, Incomplete H̅-functions, 02 engineering and technology, 01 natural sciences, Fox’s H-function, Incomplete H-functions, symbols.namesake, 0202 electrical engineering, electronic engineering, information engineering, 0101 mathematics, Bessel function, Mathematics, Algebra and Number Theory, Partial differential equation, Functional analysis, Applied Mathematics, lcsh:Mathematics, 010102 general mathematics, Function (mathematics), lcsh:QA1-939, Mellin–Barnes contour integral, Hypergeometric distribution, Ordinary differential equation, symbols, 020201 artificial intelligence & image processing, Analysis

Abstract

In this paper, we assess an integral containing incomplete H-functions and utilize it to build up an expansion formula for the incomplete H-functions including the Bessel function. Next, we evaluate an integral containing incomplete H̅-functions and use it to develop an expansion formula for the incomplete H̅-functions including the Bessel function. The outcomes introduced in this paper are general in nature, and several particular cases can be acquired by giving specific values to the parameters engaged with the principle results. As particular cases, we derive expansions for the incomplete Meijer ${}^{(\Gamma )}G$ G ( Γ ) -function, Fox–Wright ${}_{p}\Psi _{q}^{(\Gamma )}$ Ψ q ( Γ ) p -function, and generalized hypergeometric ${}_{p}\Gamma _{q}$ Γ q p function.

Published

2020

148. On generalized fractional integral inequalities for the monotone weighted Chebyshev functionals

Author

Thabet Abdeljawad, Gauhar Rahman, Behzad Ghanbari, and Kottakkaran Sooppy Nisar

Subjects

Pure mathematics, The Chebyshev functional, Algebra and Number Theory, Partial differential equation, Measurable function, Computer Science::Information Retrieval, Applied Mathematics, lcsh:Mathematics, Fractional integrals, Fractional integral inequalities, Function (mathematics), The generalized fractional integrals, Type (model theory), lcsh:QA1-939, Chebyshev filter, Monotone polygon, Ordinary differential equation, Analysis, Mathematics

Abstract

In this paper, we establish the generalized Riemann–Liouville (RL) fractional integrals in the sense of another increasing, positive, monotone, and measurable function Ψ. We determine certain new double-weighted type fractional integral inequalities by utilizing the said integrals. We also give some of the new particular inequalities of the main result. Note that we can form various types of new inequalities of fractional integrals by employing conditions on the function Ψ given in the paper. We present some corollaries as particular cases of the main results.

Published

2020

149. On a unified integral operator for φ-convex functions

Author

Moquddsa Zahra, Ghulam Farid, Shin Min Kang, Young Chel Kwun, and Saira Zainab

Subjects

Integral operators, Pure mathematics, Algebra and Number Theory, Partial differential equation, Functional analysis, Applied Mathematics, lcsh:Mathematics, φ-convex function, Fractional integrals, Hadamard inequality, Conformable matrix, lcsh:QA1-939, Upper and lower bounds, Operator (computer programming), Convex function, Bounds, Ordinary differential equation, Analysis, Conformable fractional integrals, Mathematics

Abstract

Integral operators have a very vital role in diverse fields of science and engineering. In this paper, we use φ-convex functions for unified integral operators to obtain their upper bounds and upper and lower bounds for symmetric φ-convex functions in the form of a Hadamard inequality. Also, for φ-convex functions, we obtain bounds of different known fractional and conformable fractional integrals. The results of this paper are applicable to convex functions.

Published

2020

150. Existence of solutions of infinite system of nonlinear sequential fractional differential equations

Author

Shapour Heidarkhani, Rahmatollah Lashkaripour, Zahra Ahmadi, Hamid Baghani, and Giuseppe Caristi

Subjects

Sequence, Measure of noncompactness, Algebra and Number Theory, Partial differential equation, Functional analysis, Applied Mathematics, lcsh:Mathematics, 010102 general mathematics, Fixed-point theorem, Fixed point, Sequential fractional differential equation, lcsh:QA1-939, 01 natural sciences, 010101 applied mathematics, Nonlinear system, Infinite system, Ordinary differential equation, The Banach fixed point theorem, Applied mathematics, Uniqueness, 0101 mathematics, Fractional differential, Analysis, Mathematics

Abstract

In a recent paper (Filomat 32:4577–4586, 2018) the authors have investigated the existence and uniqueness of a solution for a nonlinear sequential fractional differential equation. To present an analytical improvement for Fazli–Nieto’s results with some conditions removed based on a new technique is the main objective of this paper. In addition, we introduce an infinite system of nonlinear sequential fractional differential equations and discuss the existence of a solution for them in the classical Banach sequence spaces $c_{0}$c0 and $\ell_{p}$ℓp by applying the Darbo fixed point theorem. Moreover, the proposed method is applied to several examples to show the clarity and effectiveness.

Published

2020