Showing total 212 results

1. Mathematical and Numerical Modeling of Flow and Transport 2012.

Author

Sun, Shuyu, El-Amin, Mohamed Fathy, Chen, Zhangxing, and Kanayama, Hiroshi

Subjects

EDITORIALS, MATHEMATICAL models, TRANSPORT theory, NUMERICAL analysis, COMPUTER simulation, LOGICAL prediction

Published

2012

2. The Dynamics of a Tritrophic Leslie-Gower Food-Web System with the Effect of Fear.

Author

Maghool, Firas Hussean and Naji, Raid Kamel

Subjects

BIOLOGICAL extinction, PREDATION, LYAPUNOV functions, BIOMASS, COMPUTER simulation

Abstract

The avoidance strategy of prey to predation and the predation strategy for predators are important topics in evolutionary biology. Both prey and predators adjust their behaviors in order to obtain the maximal benefits and to raise their biomass for each. Therefore, this paper is aimed at studying the impact of prey's fear and group defense against predation on the dynamics of the food-web model. Consequently, in this paper, a mathematical model that describes a tritrophic Leslie-Gower food-web system is formulated. Sokol-Howell type of function response is adapted to describe the predation process due to the prey's group defensive capability. The effects of fear due to the predation process are considered in the first two levels. It is assumed that the generalist predator grows logistically using the Leslie-Gower type of growth function. All the solution properties of the model are studied. Local dynamics behaviors are investigated. The basin of attraction for each equilibrium is determined using the Lyapunov function. The conditions of persistence of the model are specified. The study of local bifurcation in the model is done. Numerical simulations are implemented to show the obtained results. It is watched that the system is wealthy in its dynamics including chaos. The fear factor works as a stabilizing factor in the system up to a specific level; otherwise, it leads to the extinction of the predator. However, increasing the prey's group defense leads to extinction in predator species. [ABSTRACT FROM AUTHOR]

Published

2021

3. The Dynamics of a Delayed Ecoepidemiological Model with Nonlinear Incidence Rate.

Author

Hussien, Reem Mudar and Naji, Raid Kamel

Subjects

HOPF bifurcations, INFECTIOUS disease transmission, COMPUTER simulation

Abstract

In this paper, the general framework for calculating the stability of equilibria, Hopf bifurcation of a delayed prey-predator system with an SI type of disease in the prey population, is investigated. The impact of the incubation period delay on disease transmission utilizing a nonlinear incidence rate was taken into account. For the purpose of explaining the predation process, a modified Holling type II functional response was used. First, the existence, uniform boundedness, and positivity of the solutions of the considered model system, along with the behavior of equilibria and the existence of Hopf bifurcation, are studied. The critical values of the delay parameter for which stability switches and the nature of the Hopf bifurcation by using normal form theory and center manifold theorem are identified. Additionally, using numerical simulations and a hypothetical dataset, various dynamic characteristics are discovered, including stability switches, chaos, and Hopf bifurcation scenarios. [ABSTRACT FROM AUTHOR]

Published

2023

4. The Impact of Random Noise on the Dynamics of COVID-19 Epidemic Model.

Author

El Koufi, Amine, El Koufi, Nouhaila, Bennar, Abdelkrim, and Rao, Namana Seshagiri

Subjects

COVID-19 pandemic, COVID-19, MATHEMATICAL models, HUMAN beings, COMPUTER simulation

Abstract

At the end of 2019, the world knew the propagation of a new pandemic named COVID-19. This disease harmed the exercises of humankind and changed our way of life. For modeling and studying infectious illness transmission, mathematical models are helpful tools. Thus, in this paper, taking into account the effect of the intensity of the noises, we define a threshold value Π s of the model, which determines the extinction and persistence of the COVID-19 pandemic. We give numerical simulations to illustrate the analytical results. [ABSTRACT FROM AUTHOR]

Published

2022

5. Analytical Synthesis of Regulators for Nonlinear Systems with a Terminal State Method on Examples of Motion Control of a Wheeled Robot and a Vessel.

Author

Shushlyapin, E. A. and Bezuglaya, A. E.

Subjects

NONLINEAR systems, MOTION control devices, ROBOTS, MATHEMATICAL models, COMPUTER simulation

Abstract

The paper is devoted to several examples of control algorithm development for two-wheeled double-track robot and low-tonnage vessel-catamaran with two Azipods that show practical aspects of the application of one nonlinear system control method — terminal state method. This method, developed by the authors of the present paper, belongs to the class of methods for inverse dynamics problem solving. Mathematical models of control objects in the form of normal systems of third-order nonlinear differential equations for the wheeled robot and seventh-order ones for the vessel are presented. Design formulas of the method in general form for terminal and stabilizing controls are shown. A routine of obtaining calculation expressions for control actions is shown. Results of computer simulation of bringing the robot to a given point in a given time, as well as bringing the vessel to a given course during a "strong" maneuver, are described. [ABSTRACT FROM AUTHOR]

Published

2018

6. HIV/AIDS-Pneumonia Coinfection Model with Treatment at Each Infection Stage: Mathematical Analysis and Numerical Simulation.

Author

Teklu, Shewafera Wondimagegnhu and Mekonnen, Temesgen Tibebu

Subjects

BASIC reproduction number, NUMERICAL analysis, MATHEMATICAL analysis, HIV infections, COMPUTER simulation, MIXED infections, HIV infection transmission

Abstract

In the paper, we have considered a nonlinear compartmental mathematical model that assesses the effect of treatment on the dynamics of HIV/AIDS and pneumonia coinfection in a human population at different infection stages. Our model revealed that the disease-free equilibrium points of the HIV/AIDS and pneumonia submodels are both locally and globally asymptotically stable whenever the associated basic reproduction numbers ( R H and R P ) are less than unity. Both the submodel endemic equilibrium points are locally and globally asymptotically stable whenever the associated basic reproduction numbers ( R P and R H ) are greater than unity. The full HIV/AIDS-pneumonia coinfection model has both locally and globally asymptotically stable disease-free equilibrium points whenever the basic reproduction number of the coinfection model R H P is less than unity. Using standard values of parameters collected from different kinds of literature, we found that the numerical values of the basic reproduction numbers of the HIV/AIDS-only submodel and pneumonia-only submodel are 17 and 7, respectively, and the basic reproduction number of the HIV/AIDS-pneumonia coinfection model is max 7 , 17 = 17. Applying sensitive analysis, we identified the most influential parameters to change the behavior of the solution of the considered coinfection dynamical system are the HIV/AIDS and pneumonia transmission rates β 1 and β 2 , respectively. The coinfection model was numerically simulated to investigate the stability of the coinfection endemic equilibrium point, the impacts of transmission rates, and treatment strategies for HIV/AIDS-only, pneumonia-only, and HIV/AIDS-pneumonia coinfected individuals. Finally, we observed that numerical simulations indicate that treatment against infection at every stage lowers the rate of infection or disease prevalence. [ABSTRACT FROM AUTHOR]

Published

2021

7. Bioeconomic-Epidemiological Model of Scomber colias Population in the Moroccan Coasts.

Author

Baba, Nossaiba, Agmour, Imane, El Foutayeni, Yousef, and Achtaich, Naceur

Subjects

BLUEFIN tuna, CONTINUOUS time models, COASTS, COMPUTER simulation

Abstract

In this paper, we develop and study a mathematical model for the dynamics of Scomber colias and Thunnus thynnus prey-predator with parasitic helminths. We search to analyze a bioeconomic model in which both susceptible and infected prey populations Scomber colias are exposed to the predator Thunnus thynnus, with varying degrees of exposure. However, the predator feeds preferentially on the most numerous prey types. This implies a kind of switching from the susceptible class to the infected class, and vice versa, as these two types of prey change in numerical superiority. So, the positivity, boundedness, equilibria, stability, and bioeconomic equilibrium are studied. Some numerical simulation of stability is cited. For giving a high yield and keeping the Scomber colias and Thunnus thynnus populations away from extension, we use the Maximum Principle of Pontryagin. [ABSTRACT FROM AUTHOR]

Published

2021

8. Optimal Results and Numerical Simulations for Flow Shop Scheduling Problems.

Author

Tao Ren, Yuandong Diao, and Xiaochuan Luo

Subjects

OPTIMAL control theory, COMPUTER simulation, QUADRATIC equations, PERFORMANCE evaluation, HEURISTIC algorithms, COMPUTER scheduling

Abstract

This paper considers the m-machine flow shop problem with two objectives: makespan with release dates and total quadratic completion time, respectively. For Fm|rj|Cmax, we prove the asymptotic optimality for any dense scheduling when the problem scale is large enough. For Fm||SC2j, improvement strategy with local search is presented to promote the performance of the classical SPT heuristic. At the end of the paper, simulations show the effectiveness of the improvement strategy. [ABSTRACT FROM AUTHOR]

Published

2012

9. Application of Piecewise Successive Linearization Method for the Solutions of the Chen Chaotic System.

Author

Motsa, S. S., Khan, Y., and Shateyi, S.

Subjects

PIECEWISE linear approximation, CHAOS theory, COMPUTER simulation, RUNGE-Kutta formulas, DYNAMICAL systems, MATHEMATICAL analysis

Abstract

This paper centres on the application of the new piecewise successive linearization method (PSLM) in solving the chaotic and nonchaotic Chen system. Numerical simulations are presented graphically and comparison is made between the PSLM and Runge-Kutta-based methods. The work shows that the proposed method provides good accuracy and can be easily extended to other dynamical systems including those that are chaotic in nature. [ABSTRACT FROM AUTHOR]

Published

2012

10. Order and Chaos in a Prey-Predator Model Incorporating Refuge, Disease, and Harvesting.

Author

Bahlool, Dahlia Khaled, Satar, Huda Abdul, and Ibrahim, Hiba Abdullah

Subjects

PREDATION, HARVESTING, COMMUNICABLE diseases, COMPUTER simulation, MATHEMATICAL models

Abstract

In this paper, a mathematical model consisting of a prey-predator system incorporating infectious disease in the prey has been proposed and analyzed. It is assumed that the predator preys upon the nonrefugees prey only according to the modified Holling type-II functional response. There is a harvesting process from the predator. The existence and uniqueness of the solution in addition to their bounded are discussed. The stability analysis of the model around all possible equilibrium points is investigated. The persistence conditions of the system are established. Local bifurcation analysis in view of the Sotomayor theorem is carried out. Numerical simulation has been applied to investigate the global dynamics and specify the effect of varying the parameters. It is observed that the system has a chaotic dynamics. [ABSTRACT FROM AUTHOR]

Published

2020

11. Bridging the Gap between Economic Modelling and Simulation: A Simple Dynamic Aggregate Demand-Aggregate Supply Model with Matlab.

Author

Gaspar, José M.

Subjects

ECONOMIC models, COMPUTER simulation, AGGREGATE demand, AGGREGATE supply (Economics), PRICE inflation

Abstract

This paper aims to connect the bridge between analytical results and the use of the computer for numerical simulations in economics. We address the analytical properties of a simple dynamic aggregate demand and aggregate supply (AD-AS) model and solve it numerically. The model undergoes a bifurcation as its steady state smoothly interchanges stability depending on the relationship between the impact of real interest rate on demand for liquidity and how fast agents revise their expectations on inflation. Using code embedded into a unique function in Matlab, we plot the numerical solutions of the model and simulate different dynamic adjustments using different parameter values. The same function also accommodates the analysis of the impacts of fiscal and monetary policy and supplies side shocks on the steady state and the transition dynamics of the model. [ABSTRACT FROM AUTHOR]

Published

2018

12. Distributed Containment Control of Networked Fractional-Order Systems with Delay-Dependent Communications.

Author

Xueliang Liu, Bugong Xu, and Lihua Xie

Subjects

DISTRIBUTION (Probability theory), FRACTIONAL calculus, CONTROL theory (Engineering), TIME delay systems, GRAPH theory, CONVEX domains, TOPOLOGY, COMPUTER simulation

Abstract

This paper is concerned with a containment problem of networked fractional-order system with multiple leaders under a fixed directed interaction graph. Based on the neighbor rule, a distributed protocol is proposed in delayed communication channels. By employing the algebraic graph theory, matrix theory, Nyquist stability theorem, and frequency domain method, it is analytically proved that the whole follower agents will flock to the convex hull which is formed by the leaders. Furthermore, a tight upper bound on the communication time-delay that can be tolerated in the dynamic network is obtained. As a special case, the interconnection topology under the undirected case is also discussed. Finally, some numerical exampleswith simulations are presented to demonstrate the effectiveness and correctness of the theoretical results. [ABSTRACT FROM AUTHOR]

Published

2012

13. Wigner-Ville Distribution Associated with the Linear Canonical Transform.

Author

Bai, Rui-Feng, Li, Bing-Zhao, and Cheng, Qi-Yuan

Subjects

WIGNER distribution, CONTACT transformations, SIGNAL detection, FREQUENCY modulation detectors, SIGNAL processing, COMPUTER simulation

Abstract

The linear canonical transform is shown to be one of the most powerful tools for nonstationary signal processing. Based on the properties of the linear canonical transform and the classical Wigner-Ville transform, this paper investigates the Wigner-Ville distribution in the linear canonical transform domain. Firstly, unlike the classical Wigner-Ville transform, a new definition of Wigner- Ville distribution associated with the linear canonical transform is given. Then, the main properties of the newly defined Wigner-Ville transform are investigated in detail. Finally, the applications of the newly defined Wigner-Ville transform in the linear-frequency-modulated signal detection are proposed, and the simulation results are also given to verify the derived theory. [ABSTRACT FROM AUTHOR]

Published

2012

14. Stability Analysis of Predator-Prey System with Fuzzy Impulsive Control.

Author

Yuangan Wang

Subjects

STABILITY theory, PREDATION, FUZZY control systems, MATHEMATICAL models, LOTKA-Volterra equations, EXPONENTIAL stability, COMPUTER simulation

Abstract

Having attracted much attention in the past few years, predator-prey system provides a good mathematical model to present the correlation between predators and preys. This paper focuses on the robust stability of Lotka-Volterra predator-prey system with the fuzzy impulsive control model, and Takagi-Sugeno (T-S) fuzzy impulsive control model as well. Via the T-S model and the Lyapunov method, the controlling conditions of the asymptotical stability and exponential stability are established. Furthermore, the numerical simulation for the Lotka-Volterra predatorprey system with impulsive effects verifies the effectiveness of the proposed methods. [ABSTRACT FROM AUTHOR]

Published

2012

15. System Identification Using Multilayer Differential Neural Networks: A New Result.

Author

Pérez-Cruz, J. Humberto, Alanis, A. Y., de Jesús Rubio, José, and Pacheco, Jaime

Subjects

SYSTEM identification, ARTIFICIAL neural networks, DYNAMICAL systems, LYAPUNOV functions, MATHEMATICAL bounds, COMPUTER simulation, ERROR analysis in mathematics

Abstract

In previous works, a learning law with a dead zone function was developed for multilayer differential neural networks. This scheme requires strictly a priori knowledge of an upper bound for the unmodeled dynamics. In this paper, the learning law is modified in such a way that this condition is relaxed. By this modification, the tuning process is simpler and the dead-zone function is not required anymore. On the basis of this modification and by using a Lyapunov-like analysis, a stronger result is here demonstrated: the exponential convergence of the identification error to a bounded zone. Besides, a value for upper bound of such zone is provided. The workability of this approach is tested by a simulation example. [ABSTRACT FROM AUTHOR]

Published

2012

16. Synchronization of Two Rank-One Chaotic Systems without and with Delay via Linear Delayed Feedback Control.

Author

Hui Fang

Subjects

SYNCHRONIZATION, TIME delay systems, FEEDBACK control systems, LYAPUNOV functions, COMPUTER simulation, LINEAR systems

Abstract

This paper illustrates the presence of chaos in rank-one chaotic systems with delay via a binary test called 0-1 test( for chaos. Chaotic synchronization between two rank-one chaotic systems without and with delay is achieved by means of Lyapunov functional and linear delayed feedback control method. Numerical simulations are implemented to verify the effectiveness of the proposed chaos synchronization scheme. [ABSTRACT FROM AUTHOR]

Published

2012

17. Three-Step Epipolar-Based Visual Servoing for Nonholonomic Robot with FOV Constraint.

Author

Yang Xu, Jun Peng, Wentao Yu, Yuan Fang, and Weirong Liu

Subjects

*HOLONOMIC constraints, *MOBILE robots, *COMPUTER simulation, *ARTIFICIAL intelligence, *STOCHASTIC analysis

Abstract

Image-based visual servoing for nonholonomic mobile robots using epipolar geometry is an efficient technology for visual servoing problem. An improved visual servoing strategy, namely, three-step epipolar-based visual servoing, is developed for the nonholonomic robot in this paper. The proposed strategy can keep the robot meeting FOV constraint without any 3D reconstruction. Moreover, the trajectory planned by this strategy is shorter than the existing strategies. The mobile robot can reach the desired configuration with exponential converge. The control scheme in this paper is divided into three steps. Firstly, by using the difference of epipoles as feedback, the robot rotates to make the current configuration and desired configuration in the same orientation. Then, by using a linear input-output feedback, the epipoles are zeroed so as to align the robot with the goal. Finally, by using the difference of feature points, the robot reaches the desired configuration. Simulation results and experimental results are given to illustrate the effectiveness of the proposed control scheme. [ABSTRACT FROM AUTHOR]

Published

2014

18. A Fractal and Numerical Simulation Coupled Study of Fracture Network during Coal Mining Excavation.

Author

Yanan Gao, Feng Gao, and Man-chu Ronald Yeung

Subjects

*FRACTAL dimensions, *COMPUTER simulation, *COAL mining, *EXCAVATION, *DEFORMATION potential, *STRAINS & stresses (Mechanics)

Abstract

This paper features a numerical study that is carried out by using discontinuous deformation method (DDA) and fractal geometry. The configurations of rock strata calculated by DDA were imported into a code that is written by using VC++ called "Fractal" to calculate the fractal dimension of the rock strata. As illustrated, a long wall mining case in China was presented. The relationship of the fractal dimension, excavation length, stress, and movement of strata were discussed. The evolution of fractal dimension can be considered as an index of instability or failure. The method proposed in this paper can be employed to predict the period weighting in long wall mining engineering. [ABSTRACT FROM AUTHOR]

Published

2014

19. CSR Impact on Hospital Duopoly with Price and Quality Competition.

Author

Youguang Xu

Subjects

*SOCIAL responsibility of business, *DUOPOLIES, *ECONOMIC competition, *PRIVATIZATION, *HOSPITALS, *COMPUTER simulation

Abstract

This paper investigates the impact of corporate social responsibility (CSR) on hospital duopoly with price and quality competition. A CSR hospital is defined in this paper that cares about not only the profit but also the patient benefit. We start our analysis by establishing a two-stage Hotelling model with and without CSR. Results indicate that privatization mechanism may not be the best way of improving medical quality. Competition between hospitals with zero-CSR would lower the equilibriumqualities compared to the first-best level. So the coexistence of a public (more accurately, partial public) and a private hospital might be more efficient than a private-private hospital duopoly. During the competition with CSR in price and quality, social welfare level acts in accordance with an inverted U-shaped trajectory as CSR degree increases. Themain reason lies in the fact that optimal degree of CSR is determined by the trade-off between the benefit of quality improvement and the cost of quality investment. Numerical simulation shows that the optimal degree of CSR is less than a third. [ABSTRACT FROM AUTHOR]

Published

2014

20. Optimal Research and Numerical Simulation for Scheduling No-Wait Flow Shop in Steel Production.

Author

Huawei Yuan, Yuanwei Jing, Jinping Huang, and Tao Ren

Subjects

*COMPUTER simulation, *FLOW shop scheduling, *STEEL manufacture, *PRODUCTION scheduling, *ALGORITHMS, *MATHEMATICAL bounds, *APPLIED mathematics

Abstract

This paper considers the m-machine flow shop scheduling problem with the no-wait constraint to minimize total completion time which is the typical model in steel production. First, the asymptotic optimality of the Shortest Processing Time (SPT) first rule is proven for this problem. To further evaluate the performance of the algorithm, a new lower bound with performance guarantee is designed. At the end of the paper, numerical simulations show the effectiveness of the proposed algorithm and lower bound. [ABSTRACT FROM AUTHOR]

Published

2013

21. Consensus Analysis of Second-Order Multiagent Systems with General Topology and Time Delay.

Author

Bo Liu, Guangming Xie, Yanping Gao, Jiaxi Wu, Jianguo Zhang, and Wenguang Luo

Subjects

*MULTIAGENT systems, *TOPOLOGY, *TIME delay systems, *LAPLACE transformation, *LAPLACIAN matrices, *EIGENVALUES, *COMPUTER simulation

Abstract

This paper addresses the consensus of second-order multiagent systems with general topology and time delay based on the nearest neighbor rule. By using the Laplace transform technique, it is proved that the second-order multi-agent system in the presence of time-delay can reach consensus if the network topology contains a globally reachable node and time delay is bounded. The bound of time-delay only depends on eigenvalues of the Laplacian matrix of the system. The main contribution of this paper is that the accurate state of the consensus center and the upper bound of the communication delay to make the agents reach consensus are given. Some numerical simulations are given to illustrate the theoretical results. [ABSTRACT FROM AUTHOR]

Published

2013

22. Cluster Synchronization of Time-Varying Delays Coupled Complex Networks with Nonidentical Dynamical Nodes.

Author

Shuguo Wang, Hongxing Yao, and Mingping Sun

Subjects

SYNCHRONIZATION, TIME-varying systems, GRAPH theory, NONLINEAR theories, COMPUTER simulation, MATHEMATICAL models

Abstract

This paper investigates a new cluster synchronization scheme in the nonlinear coupled complex dynamical networks with nonidentical nodes. The controllers are designed based on the community structure of the networks; some sufficient criteria are derived to ensure cluster synchronization of the network model. Particularly, the weight configuration matrix is not assumed to be symmetric, irreducible. The numerical simulations are performed to verify the effectiveness of the theoretical results. [ABSTRACT FROM AUTHOR]

Published

2012

23. Presentation of Malaria Epidemics Using Multiple Optimal Controls.

Author

Lashari, Abid Ali, Aly, Shaban, Hattaf, Khalid, Zaman, Gul, Il Hyo Jung, and Li, Xue-Zhi

Subjects

OPTIMAL control theory, ANTIMALARIALS, MALARIA treatment, UNIQUENESS (Mathematics), EXISTENCE theorems, COMPUTER simulation

Abstract

An existing model is extended to assess the impact of some antimalaria control measures, by reformulating the model as an optimal control problem. This paper investigates the fundamental role of three type of controls, personal protection, treatment, and mosquito reduction strategies in controlling the malaria. We work in the nonlinear optimal control framework. The existence and the uniqueness results of the solution are discussed. A characterization of the optimal control via adjoint variables is established. The optimality system is solved numerically by a competitive Gauss-Seidel-like implicit difference method. Finally, numerical simulations of the optimal control problem, using a set of reasonable parameter values, are carried out to investigate the effectiveness of the proposed control measures. [ABSTRACT FROM AUTHOR]

Published

2012

24. Study on the Dependence of Reverse Simulation for Identifying a Pollutant Source on Grid Resolution and Filter Width in Cavity Flow.

Author

Abe, Satoshi, Kato, Shinsuke, Hamba, Fujihiro, and Kitazawa, Daisuke

Subjects

DEPENDENCE (Statistics), COMPUTER simulation, POLLUTANTS, PROBABILITY theory, HEAT equation, DIGITAL filters (Mathematics), STABILITY theory

Abstract

When a hazardous substance is diffused, it is necessary to identify the pollutant source and respond immediately. However, there are many cases in which damage is caused without a clear understanding of where the pollutant source is located. There are three groups of identifying pollutant source information (Liu and Zhai, 2007): the probability method, forward method, and backward method. In our previous study, we proposed reverse simulation, which is categorized as a backwardmethod (Abe and Kato, 2011). Numerical instability by negative diffusion is a principal problem in the backward method. In order to improve the problem, we applied a low-pass filter operation to the concentration flux in the RANS analysis. The simulation secured the numerical stability. However, reverse simulation accuracy is expected to depend on the grid resolution and filter width. In this paper, we introduce reverse simulation results in cavity flow. In particular, we survey the dependence of reverse simulation accuracy on the grid resolution and filter width. Moreover, we discuss the dependence of reverse simulation on the grid resolution and filter width with a one-dimensional diffusion equation. As a result, we found that the simulated negative diffusion varies greatly among the grid resolution and filter width. [ABSTRACT FROM AUTHOR]

Published

2012

25. The Dynamics of an Eco-Epidemiological Model with Nonlinear Incidence Rate.

Author

Naji, Raid Kamel and Mustafa, Arkan N.

Subjects

EPIDEMIOLOGICAL models, NONLINEAR theories, DYNAMIC models, EXISTENCE theorems, COMPUTER simulation, HOPF bifurcations, LOTKA-Volterra equations

Abstract

This paper treats the dynamical behavior of eco-epidemiological model with nonlinear incidence rate. A Holling type-II prey-predator model with SI- type of disease in prey has been proposed and analyzed. The existence, uniqueness, and boundedness of the solution of the system are studied. The local and global dynamical behaviors are investigated. The conditions, which guarantee the occurring of Hopf bifurcation of the system, are established. Finally, further investigations for the global dynamics of the proposed system are carried out with the help of numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2012

26. A Novel Four-Dimensional Energy-Saving and Emission-Reduction System and Its Linear Feedback Control.

Author

Minggang Wang and Hua Xu

Subjects

ENERGY conservation, ECONOMIC development, EMISSION control, LYAPUNOV exponents, FEEDBACK control systems, COMPUTER simulation, CHAOS theory

Abstract

This paper reports a new four-dimensional energy-saving and emission-reduction chaotic system. The system is obtained in accordance with the complicated relationship between energy saving and emission reduction, carbon emission, economic growth, and new energy development. The dynamics behavior of the system will be analyzed by means of Lyapunov exponents and equilibrium points. Linear feedback control methods are used to suppress chaos to unstable equilibrium. Numerical simulations are presented to show these results. [ABSTRACT FROM AUTHOR]

Published

2012

27. A Dynamic Model for Fishery Resource with Reserve Area and Taxation.

Author

Huo, Hai-Feng, Jiang, Hui-Min, and Meng, Xin-You

Subjects

COMPUTER simulation, DYNAMIC models, EXISTENCE theorems, NATURE reserves, FISHERY resources, STABILITY theory, PONTRYAGIN'S minimum principle, TAXATION

Abstract

The present paper deals with a dynamic reaction model of a fishery. The dynamics of a fishery resource system in an aquatic environment consists of two zones: a free fishing zone and a reserve zone. To protect fish population from over exploitation, a control instrument tax is imposed. The existence of its steady states and their stability are studied. The optimal harvest policy is discussed next with the help of Pontryagin's maximum principle. Our theoretical results are confirmed by numerical simulation. [ABSTRACT FROM AUTHOR]

Published

2012

28. The Technique of MIEELDLD in Computational Aeroacoustics.

Author

Appadu, A. R.

Subjects

COMPUTATIONAL fluid dynamics, AEROACOUSTICS, COMPUTER simulation, ENERGY dissipation, ADVECTION-diffusion equations, PARAMETER estimation, ERROR analysis in mathematics

Abstract

The numerical simulation of aeroacoustic phenomena requires high-order accurate numerical schemes with low dispersion and low dissipation errors. A technique has recently been devised in a Computational Fluid Dynamics framework which enables optimal parameters to be chosen so as to better control the grade and balance of dispersion and dissipation in numerical schemes (Appadu and Dauhoo, 2011; Appadu, 2012a; Appadu, 2012b; Appadu, 2012c). This technique has been baptised as the Minimized Integrated Exponential Error for Low Dispersion and Low Dissipation (MIEELDLD) and has successfully been applied to numerical schemes discretising the 1-D, 2-D, and 3-D advection equations. In this paper, we extend the technique of MIEELDLD to the field of computational aeroacoustics and have been able to construct high-order methodswith Low Dispersion and Low Dissipation properties which approximate the 1-D linear advection equation. Modifications to the spatial discretization schemes designed by Tam and Webb (1993), Lockard et al. (1995), Zingg et al. (1996), Zhuang and Chen (2002), and Bogey and Bailly (2004) have been obtained, and also a modification to the temporal scheme developed by Tam et al. (1993) has been obtained. These novel methods obtained using MIEELDLD have in general better dispersive properties as compared to the existing optimised methods. [ABSTRACT FROM AUTHOR]

Published

2012

29. Inverse Projective Synchronization between Two Different Hyperchaotic Systems with Fractional Order.

Author

Yi Chai, Liping Chen, and Ranchao Wu

Subjects

SYNCHRONIZATION, FRACTIONAL calculus, CHAOS theory, COMPUTER simulation, LYAPUNOV functions, NUMERICAL solutions to differential equations, CONTROL theory (Engineering)

Abstract

This paper mainly investigates a novel inverse projective synchronization between two different fractional-order hyperchaotic systems, that is, the fractional-order hyperchaotic Lorenz system and the fractional-order hyperchaotic Chen system. By using the stability theory of fractionalorder differential equations and Lyapunov equations for fractional-order systems, two kinds of suitable controllers for achieving inverse projective synchronization are designed, in which the generalized synchronization, antisynchronization, and projective synchronization of fractionalorder hyperchaotic Lorenz system and fractional-order hyperchaotic Chen system are also successfully achieved, respectively. Finally, simulations are presented to demonstrate the validity and feasibility of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2012

30. Analysis of a HBV Model with Diffusion and Time Delay.

Author

Noé Chan Chí, Vales, Eric Ávila, and Almeida, Gerardo Garcı

Subjects

HEPATITIS B virus, VIRUS diseases, DISEASE incidence, BIOLOGICAL transport, VIRAL replication, TIME delay systems, MATHEMATICAL models, COMPUTER simulation

Abstract

This paper discussed a hepatitis B virus infection with delay, spatial diffusion, and standard incidence function. The local stability of equilibrium is obtained via characteristic equations. By using comparison arguments, it is proved that if the basic reproduction number is less than unity, the infection-free equilibrium is globally asymptotically stable. If the basic reproductive number is greater than unity, by means of an iteration technique, sufficiently conditions are obtained for the global asymptotic stability of the infected steady state. Numerical simulations are carried out to illustrate our findings. [ABSTRACT FROM AUTHOR]

Published

2012

31. On Nonlinear Simulation Methods and Tools for Evaluating the Performance of Ships and Offshore Structures in Waves.

Author

Liu, Shukui and Papanikolaou, Apostolos

Subjects

NONLINEAR systems, COMPUTER simulation, PERFORMANCE evaluation, OFFSHORE structures, THEORY of wave motion, POTENTIAL theory (Mathematics), HYDRODYNAMICS

Abstract

This paper describes the development of alternative time domain numerical simulation methods for predicting large amplitude motions of ships and floating structures in response to incoming waves in the frame of potential theory. The developed alternative set of time domain methods simulate the hydrodynamic forces acting on ships advancing in waves with constant speed. For motions' simulation, the diffraction forces and radiation forces are calculated up to the mean wetted surface, while the Froude-Krylov forces and hydrostatic restoring forces are calculated up to the undisturbed incident wave surface in case of large incident wave amplitude. This enables the study of the above waterline hull form effect. Characteristic case studies on simulating the hydrodynamic forces and motions of standard type of ships have been conducted for validation purpose. Good agreement with other numerical codes and experimental data has been observed. Furthermore, the added resistance of ships in waves can be calculated by the presented methods. This capability supports the increased demand of this type of tools for the proper selection of engine/propulsion systems accounting for ship's performance in realistic sea conditions, or when optimizing ship's sailing route for minimum fuel consumption and toxic gas emissions. [ABSTRACT FROM AUTHOR]

Published

2012

32. Radio Frequency Numerical Simulation Techniques Based on Multirate Runge-Kutta Schemes.

Author

Oliveira, Jorge F. and Pedro, José C.

Subjects

RADIO frequency, COMPUTER simulation, RUNGE-Kutta formulas, ELECTRONIC circuits, TELECOMMUNICATION, SIGNAL processing, MICROWAVES

Abstract

Electronic circuit simulation, especially for radio frequency RF( and microwave telecommunications, is being challenged by increasingly complex applications presenting signals of very different nature and evolving on widely separated time scales. In this paper, we will briefly review some recently developed ways to address these challenges, by describing some advanced numerical simulation techniques based on multirate Runge-Kutta schemes, which operate in the one-dimensional time and also within multidimensional frameworks. [ABSTRACT FROM AUTHOR]

Published

2012

33. Numerical Simulation of Solitary Wave Induced Flow Motion around a Permeable Submerged Breakwater.

Author

Jisheng Zhang, Jinhai Zheng, Jeng, Dong-Sheng, and Gang Wang

Subjects

COMPUTER simulation, SOLITONS, BREAKWATERS, MATHEMATICAL models, NAVIER-Stokes equations, POROUS materials, THEORY of wave motion

Abstract

This paper presents a numerical model for the simulation of solitary wave transformation around a permeable submerged breakwater. The wave-structure interaction is obtained by solving the Volume-Averaged Reynolds-Averaged Navier-Stokes governing equations (VARANS) and volume of fluid (VOF) theory. This model is applied to understand the effects of porosity, equivalent mean diameter of porous media, structure height, and structure width on the propagation of a solitary wave in the vicinity of a permeable submerged structure. The results show that solitary wave propagation around a permeable breakwater is essentially different from that around impermeable one. It is also found that the structure porosity has more impact than equivalent mean diameter on the wave transformation and flow structure. After interacting with the higher structure, thewave has smallerwave height behind the structurewith a lower travelling speed. When the wave propagates over the breakwater with longer width, the wave travelling speed is obviously reduced with more wave energy dissipated inside porous structure. [ABSTRACT FROM AUTHOR]

Published

2012

34. Robust Adaptive Switching Control for Markovian Jump Nonlinear Systems via Backstepping Technique.

Author

Jin Zhu, Hongsheng Xi, Qiang Ling, and Wanqing Xie

Subjects

ROBUST control, SWITCHING theory, MARKOVIAN jump linear systems, DYNAMICAL systems, LYAPUNOV stability, PARAMETER estimation, COMPUTER simulation

Abstract

This paper investigates robust adaptive switching controller design for Markovian jump nonlinear systems with unmodeled dynamics and Wiener noise. The concerned system is of strict-feedback form, and the statistics information of noise is unknown due to practical limitation. With the ordinary input-to-state stability ISS( extended to jump case, stochastic Lyapunov stability criterion is proposed. By using backstepping technique and stochastic small-gain theorem, a switching controller is designed such that stochastic stability is ensured. Also system states will converge to an attractive region whose radius can be made as small as possible with appropriate control parameters chosen. A simulation example illustrates the validity of this method. [ABSTRACT FROM AUTHOR]

Published

2012

35. Direct Simulation of Low-Re Flow around a Square Cylinder by Numerical Manifold Method for Navier-Stokes Equations.

Author

Zhengrong Zhang and Xiangwei Zhang

Subjects

COMPUTER simulation, NUMERICAL solutions to Navier-Stokes equations, MANIFOLDS (Mathematics), GALERKIN methods, POLYNOMIALS, LINEAR systems, FINITE element method

Abstract

Numerical manifold method was applied to directly solve Navier-Stokes (N-S) equations for incompressible viscous flow in this paper, and numerical manifold schemes for N-S equations coupled velocity and pressure were derived based on Galerkin weighted residuals method as well. Mixed cover with linear polynomial function for velocity and constant function for pressure was employed in finite element cover system. As an application, mixed cover 4-node rectangular manifold element has been used to simulate the incompressible viscous flow around a square cylinder in a channel. Numerical tests illustrate that NMM is an effective and high-order accurate numerical method for incompressible viscous flow N-S equations. [ABSTRACT FROM AUTHOR]

Published

2012

36. Modified Firefly Algorithm.

Author

Surafel Luleseged Tilahun and Hong Choon Ong

Subjects

METAHEURISTIC algorithms, MATHEMATICAL optimization, PERFORMANCE evaluation, GEOMETRICAL constructions, MATHEMATICAL functions, COMPUTER simulation, CENTRAL processing units

Abstract

Firefly algorithm is one of the new metaheuristic algorithms for optimization problems. The algorithm is inspired by the flashing behavior of fireflies. In the algorithm, randomly generated solutionswill be considered as fireflies, and brightness is assigned depending on their performance on the objective function. One of the rules used to construct the algorithm is, a firefly will be attracted to a brighter firefly, and if there is no brighter firefly, it will move randomly. In this paper we modify this random movement of the brighter firefly by generating random directions in order to determine the best direction in which the brightness increases. If such a direction is not generated, it will remain in its current position. Furthermore the assignment of attractiveness is modified in such a way that the effect of the objective function is magnified. From the simulation result it is shown that the modified firefly algorithm performs better than the standard one in finding the best solution with smaller CPU time. [ABSTRACT FROM AUTHOR]

Published

2012

37. Evaluation of Congestion Relief Proposals in a Capital City.

Author

Fowdur, Sudhir C. and Rughooputh, Soonil D. D. V.

Subjects

TRAFFIC congestion, STREET railroads, BELTWAYS, PERFORMANCE evaluation, COMPUTER simulation

Abstract

This paper aims at analyzing three different solutions suggested for traffic congestion relief in Port Louis, the busiest city of Mauritius. It evaluates the impact of the three alternatives which are the use of Light Rail Transit (LRT) as an alternative mode of transport, the construction of a Ring road around Port Louis, and the upgrading of the current bus network into a Bus Rapid Transit (BRT) system. The impact of these three solutions has been evaluated by performing Traffic Cellular Automata (TCA) simulations. Our studies reveal that the Ring road will lead to more congestion while introducing the LRT or upgrading the current bus network will reduce congestion significantly. [ABSTRACT FROM AUTHOR]

Published

2012

38. Multi-State Dependent Impulsive Control for Pest Management.

Author

Huidong Cheng, Fang Wang, and Tongqian Zhang

Subjects

INTEGRATED pest control, DIFFERENTIAL equations, GEOMETRY, EXISTENCE theorems, COMPUTER simulation, DEPENDENCE (Statistics)

Abstract

According to the integrated pest management strategies, we propose a model for pest control which adopts different control methods at different thresholds. By using differential equation geometry theory and the method of successor functions, we prove the existence of order one periodic solution of such system, and further, the attractiveness of the order one periodic solution by sequence convergence rules and qualitative analysis. Numerical simulations are carried out to illustrate the feasibility of our main results. Our results show that our method used in this paper is more efficient and easier than the existing ones for proving the existence of order one periodic solution. [ABSTRACT FROM AUTHOR]

Published

2012

39. Numerical Simulation of Sloshing Phenomena in Cubic Tank with Multiple Baffles.

Author

Xue, Mi-An, Zheng, Jinhai, and Lin, Pengzhi

Subjects

COMPUTER simulation, BAFFLES (Mechanical device), NUMERICAL solutions to Navier-Stokes equations, TWO-phase flow, MATHEMATICAL models, HARMONIC motion, TIME series analysis

Abstract

A two-phase fluid flow model solving Navier-Stokes equations was employed in this paper to investigate liquid sloshing phenomena in cubic tank with horizontal baffle, perforated vertical baffle, and their combinatorial configurations under the harmonic motion excitation. Laboratory experiment of liquid sloshing in cubic tank with perforated vertical baffle was carried out to validate the present numerical model. Fairly good agreements were obtained from the comparisons between the present numerical results and the present experimental data, available numerical data. Liquid sloshing in cubic tank with multiple baffles was investigated numerically in detail under different external excitation frequencies. Power spectrumof the time series of free surface elevation was presented with the aid of fast Fourier transform technique. The dynamic impact pressures acting on the normal and parallel sidewalls were discussed in detail. [ABSTRACT FROM AUTHOR]

Published

2012

40. Stationary Distribution and Dynamic Behaviour of a Stochastic SIVR Epidemic Model with Imperfect Vaccine.

Author

Kiouach, Driss and Boulaasair, Lahcen

Subjects

VACCINATION, ERGODIC theory, COMPUTER simulation, EPIDEMICS, COMMUNICABLE diseases

Abstract

We consider a stochastic SIVR (susceptible-infected-vaccinated-recovered) epidemic model with imperfect vaccine. First, we obtain critical condition under which the disease is persistent in the mean. Second, we establish sufficient conditions for the existence of an ergodic stationary distribution to the model. Third, we study the extinction of the disease. Finally, numerical simulations are given to support the analytical results. [ABSTRACT FROM AUTHOR]

Published

2018

41. Self-Triggered Model Predictive Control for Linear Systems Based on Transmission of Control Input Sequences.

Author

Kobayashi, Koichi

Subjects

*PREDICTIVE control systems, *MATHEMATICAL models, *LINEAR systems, *DISCRETE-time systems, *COMPUTER simulation

Abstract

A networked control system (NCS) is a control system where components such as plants and controllers are connected through communication networks. Self-triggered control is well known as one of the control methods in NCSs and is a control method that for sampled-data control systems both the control input and the aperiodic sampling interval (i.e., the transmission interval) are computed simultaneously. In this paper, a self-triggered model predictive control (MPC) method for discrete-time linear systems with disturbances is proposed. In the conventional MPC method, the first one of the control input sequence obtained by solving the finite-time optimal control problem is sent and applied to the plant. In the proposed method, the first some elements of the control input sequence obtained are sent to the plant, and each element is sequentially applied to the plant. The number of elements is decided according to the effect of disturbances. In other words, transmission intervals can be controlled. Finally, the effectiveness of the proposed method is shown by numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2016

42. Noise Folding in Completely Perturbed Compressed Sensing.

Author

Zhou, Limin, Niu, Xinxin, and Yuan, Jing

Subjects

*NOISE measurement, *COMPRESSED sensing, *PERTURBATION theory, *MATRICES (Mathematics), *RESTRICTED isometry property, *COMPUTER simulation

Abstract

This paper first presents a new generally perturbed compressed sensing (CS) model y=(A+E)(x+u)+e, which incorporated a general nonzero perturbation E into sensing matrix A and a noise u into signal x simultaneously based on the standard CS model y=Ax+e and is called noise folding in completely perturbed CS model. Our construction mainly will whiten the new proposed CS model and explore in restricted isometry property (RIP) and coherence of the new CS model under some conditions. Finally, we use OMP to give a numerical simulation which shows that our model is feasible although the recovered value of signal is not exact compared with original signal because of measurement noise e, signal noise u, and perturbation E involved. [ABSTRACT FROM AUTHOR]

Published

2016

43. Adaptive Time-Stepping Using Control Theory for the Chemical Langevin Equation.

Author

Ilie, Silvana and Morshed, Monjur

Subjects

*CONTROL theory (Engineering), *STOCHASTIC models, *CHEMOTAXONOMY, *DIMERIZATION, *COMPUTER simulation

Abstract

Stochastic modeling of biochemical systems has been the subject of intense research in recent years due to the large number of important applications of these systems. A critical stochastic model of well-stirred biochemical systems in the regime of relatively large molecular numbers, far from the thermodynamic limit, is the chemical Langevin equation. This model is represented as a system of stochastic differential equations, with multiplicative and noncommutative noise. Often biochemical systems in applications evolve on multiple time-scales; examples include slow transcription and fast dimerization reactions. The existence of multiple time-scales leads to mathematical stiffness, which is a major challenge for the numerical simulation. Consequently, there is a demand for efficient and accurate numerical methods to approximate the solution of these models. In this paper, we design an adaptive time-stepping method, based on control theory, for the numerical solution of the chemical Langevin equation. The underlying approximation method is the Milstein scheme. The adaptive strategy is tested on several models of interest and is shown to have improved efficiency and accuracy compared with the existing variable and constant-step methods. [ABSTRACT FROM AUTHOR]

Published

2015

44. Adaptive Synchronization of Complex Networks with Mixed Probabilistic Coupling Delays via Pinning Control.

Author

Jian-An Wang

Subjects

*PROBABILITY theory, *MATRICES (Mathematics), *MATHEMATICAL symmetry, *COMPUTER simulation, *FEEDBACK control systems

Abstract

The problem of synchronization for a class of complex networks with probabilistic time-varying coupling delay and distributed time-varying coupling delay (mixed probabilistic time-varying coupling delays) using pinning control is investigated in this paper. The coupling configuration matrices are not assumed to be symmetric or irreducible. By adding adaptive feedback controllers to a small fraction of network nodes, a low-dimensional pinning sufficient condition is obtained, which can guarantee that the network asymptotically synchronizes to a homogenous trajectory inmean square sense. Simultaneously, two simple pinning synchronization criteria are derived from the proposed condition. Numerical simulation is provided to verify the effectiveness of the theoretical results. [ABSTRACT FROM AUTHOR]

Published

2014

45. A New Subband Adaptive Filtering Algorithm for Sparse System Identification with Impulsive Noise.

Author

Young-Seok Choi

Subjects

*ADAPTIVE filters, *MATHEMATICAL optimization, *ROBUST control, *COMPUTER simulation, *STOCHASTIC convergence

Abstract

This paper presents a novel subband adaptive filter (SAF) for systemidentificationwhere an impulse response is sparse and disturbed with an impulsive noise. Benefiting from the uses of l1-norm optimization and l0-norm penalty of the weight vector in the cost function, the proposed l0-norm sign SAF (l0-SSAF) achieves both robustness against impulsive noise and remarkably improved convergence behavior more than the classical adaptive filters. Simulation results in the system identification scenario confirm that the proposed l0-norm SSAF is not only more robust but also faster and more accurate than its counterparts in the sparse system identification in the presence of impulsive noise. [ABSTRACT FROM AUTHOR]

Published

2014

46. Dynamic Sliding Mode Evolution PWM Controller for a Novel High-Gain Interleaved DC-DC Converter in PV System.

Author

Taizhou Bei, Ping Wang, Liu Yang, and Zhe Zhou

Subjects

*SLIDING mode control, *DC-to-DC converters, *HIGH voltages, *COMPUTER simulation, *STABILITY theory

Abstract

Considering the disadvantages of the traditional high-gain DC-DC converter such as big size, high voltage stress of switches, and large input current ripple, a novel high-gain interleaved boost converter with coupled-inductor and switched-capacitor was proposed correspondingly and the operation principle together with the steady-state analysis of this converter was also described. Besides, a new control approach-dynamic sliding mode evolution PWM controller (DSME PWM) for the novel topological converter based on both dynamic evolution and sliding mode control was also presented. From the simulation results and experimental validation the proposed converter can fulfill high-gain boost, low ripple of both the input current and the output voltage. Furthermore, MPPT technique can be also achieved in a short time by simulation. The efficiency and stability of the converter proposed in this paper can be improved. [ABSTRACT FROM AUTHOR]

Published

2014

47. Numerical Investigation of Gas Mixture Length of Nitrogen Replacement in Large-Diameter Natural Gas Pipeline without Isolator.

Author

Hongjun Zhu and Qinghua Han

Subjects

*NATURAL gas pipelines, *COMPUTATIONAL fluid dynamics, *COMPUTER simulation, *MATHEMATICAL formulas, *FLUID flow

Abstract

Nitrogen replacement is a key process for natural gas pipeline before it is put into operation. A computational fluid dynamic model coupled to a species-transportation model has been used to investigate the gas mixture length of nitrogen replacement in largediameter pipeline without isolator. Aseries of numerical simulations are performed over a range of conditions, including pipe length and diameter, inlet rate, and inclination angle of pipe. These affecting factors are analyzed in detail in terms of volume fraction of nitrogen, the maximum gas mixture length, and gas mixture length varied with time. Gas mixture length increases over time, and the maximum gas mixture length is present at outlet of pipe. Long and large-diameter pipe and fast speed of nitrogen lead to long length of mixed gas, while large inclination angle of pipe brings about short length. Several fitting formulas have been obtained, which can predict the maximum gas mixture length in gas pipelines. The used method of fitting formula is shown in the paper by examples. The results provide effective guidance for practical operation of nitrogen replacement. [ABSTRACT FROM AUTHOR]

Published

2014

48. Weighted Multimodel Predictive Function Control for Automatic Train Operation System.

Author

Shuhuan Wen, Jingwei Yang, Rad, Ahmad B., Shengyong Chen, and Pengcheng Hao

Subjects

*AUTOMATIC train control, *PREDICTIVE control systems, *FUZZY control systems, *K-means clustering, *PREDICTION models, *COMPUTER simulation, *NONLINEAR theories

Abstract

Train operation is a complex nonlinear process; it is difficult to establish accuratemathematicalmodel. In this paper, we designATO speed controller based on the input and output data of the train operation. The method combines multimodeling with predictive functional control according to complicated nonlinear characteristics of the train operation. Firstly, we cluster the data sample by using fuzzy-c means algorithm. Secondly, we identify parameter of cluster model by using recursive least square algorithm with forgetting factor and then establish the local set of models of the process of train operation. Then at each sample time, we can obtain the global predictive model about the system based on the weighted indicators by designing a kind of weighting algorithm with error compensation. Thus, the predictive functional controller is designed to control the speed of the train. Finally, the simulation results demonstrate the effectiveness of the proposed algorithm. [ABSTRACT FROM AUTHOR]

Published

2014

49. Optimal Acceleration-Velocity-Bounded Trajectory Planning in Dynamic Crowd Simulation.

Author

Fu Yue-wen, Li Meng, Liang Jia-hong, and Hu Xiao-qian

Subjects

*COMPUTER simulation, *MATHEMATICAL bounds, *CROWD control, *PEDESTRIANS, *DYNAMICAL systems

Abstract

Creating complex and realistic crowd behaviors, such as pedestrian navigation behavior with dynamic obstacles, is a difficult and time consuming task. In this paper, we study one special type of crowd which is composed of urgent individuals, normal individuals, and normal groups. We use three steps to construct the crowd simulation in dynamic environment. The first one is that the urgent individuals move forward along a given path around dynamic obstacles and other crowd members. An optimal accelerationvelocity- bounded trajectory planningmethod is utilized tomodel their behaviors, which ensures that the durations of the generated trajectories are minimal and the urgent individuals are collision-free with dynamic obstacles (e.g., dynamic vehicles). In the second step, a pushing model is adopted to simulate the interactions between urgent members and normal ones, which ensures that the computational cost of the optimal trajectory planning is acceptable. The third step is obligated to imitate the interactions among normalmembers using collision avoidance behavior and flocking behavior. Various simulation results demonstrate that these three steps give realistic crowd phenomenon just like the real world. [ABSTRACT FROM AUTHOR]

Published

2014

50. Performance of Some Stochastic Restricted Ridge Estimator in Linear Regression Model.

Author

Jibo Wu and Chaolin Liu

Subjects

*REGRESSION analysis, *STOCHASTIC analysis, *PARAMETER estimation, *COMPUTER simulation, *MATHEMATICAL analysis

Abstract

This paper considers several estimators for estimating the stochastic restricted ridge regression estimators. A simulation study has been conducted to compare the performance of the estimators. The result from the simulation study shows that stochastic restricted ridge regression estimators outperform mixed estimator. A numerical example has been also given to illustrate the performance of the estimators. [ABSTRACT FROM AUTHOR]

Published

2014