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839 results on '"Two-dimensional space"'

1. Dynamic Formation of Robot Movement Route in Nondeterministic Environment with Bypassing Stationary and Nonstationary Obstacles.

Author

Lebedev, O. B. and Beskhmelnov, M. I.

Abstract

The work describes a hybrid algorithm for the dynamic formation of a robot's movement route in nondeterministic environments with bypassing stationary and nonstationary obstacles for two-dimensional space, based on the integration of wave and ant algorithms, which makes it possible to build trajectories of minimum length in real time with simultaneous optimization of a number of criteria for the quality of the constructed path. Restrictions preventing the construction of a trajectory from the current position are identified during the construction process. The trajectory is constructed step by step. The entire trajectory connecting the robot's initial position with the target position is a collection of individual sections. The time complexity of the algorithm depends on the lifespan of the colony, l (number of iterations); the number of graph vertices, n; the number of ants, m; and is estimated as O(ln2m). [ABSTRACT FROM AUTHOR]

Published
2024
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2. 二维空间中距离不确定性的测度方法研究.

Author

毛政元, 范琳娜, and 李 霖

Subjects
*MEASUREMENT
Abstract

Objectives: Distances are functions of spatial positions. Precisely revealing the functional relationship which quantitatively embodies the transmission of uncertainty from spatial positions to their distance, a key scientific problem in need of being solved urgently in geomatics, has important theoretical and practical significance. Methods: Aiming at the limitation of presently available solution of the above mentioned problem, under the premise of that the real position corresponding with the observed one of an uncertain point follows the complete spatial random distribution within the error circle, we have derived the probability distribution function of the distance uncertainty and the corresponding density function containing an uncertain point and those between two uncertain points respectively in two-dimensional space. The latter has been employed to explore the transmission law of point uncertainties to distance uncertainties, opening up a new way for studying and solving the problem of distance uncertainties. Results: The results show that for all cases: (1) When the radius of the error circle (corresponding to the point position accuracy) and the observed distance between points change simultaneously, their ratio has a significant positive correlation with the level of distance uncertainties. (2) When the former remains constant, the distance uncertainty has a significant negative correlation with the latter. (3) When the latter remains constant, the distance uncertainty has a significant positive correlation with the former. Conclusions: As far as the distance uncertainty of cases containing an uncertain point and the one of those between two uncertain points are concerned, the latter is obviously greater than the former when the radius of the error circle and the observed distance between points are consistent for both of them. Otherwise they are not comparable. [ABSTRACT FROM AUTHOR]

Published
2023
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5. Hybrid Algorithm of Mobile Position-Trajectory Control

Author

Veselov, Gennady E., Lebedev, Boris K., Lebedev, Oleg B., Kostyuk, Andrey I., Kacprzyk, Janusz, Series Editor, Pal, Nikhil R., Advisory Editor, Bello Perez, Rafael, Advisory Editor, Corchado, Emilio S., Advisory Editor, Hagras, Hani, Advisory Editor, Kóczy, László T., Advisory Editor, Kreinovich, Vladik, Advisory Editor, Lin, Chin-Teng, Advisory Editor, Lu, Jie, Advisory Editor, Melin, Patricia, Advisory Editor, Nedjah, Nadia, Advisory Editor, Nguyen, Ngoc Thanh, Advisory Editor, Wang, Jun, Advisory Editor, and Silhavy, Radek, editor

Published
2019
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6. Using Multidimensional Scaling for Assessment Economic Development of Regions

Author

Pavlo Hryhoruk, Nila Khrushch, and Svitlana Grygoruk

Subjects
economic development, multidimensional scaling, region, two-dimensional space, latent scales, Technology
Abstract

Addressing socio-economic development issues are strategic and most important for any country. Multidimensional statistical analysis methods, including comprehensive index assessment, have been successfully used to address this challenge, but they don't cover all aspects of development, leaving some gap in the development of multidimensional metrics. The purpose of the study is to construct a latent metric space based on the use of multidimensional scaling. Based on statistics showing the economic development of Ukrainian regions, two-dimensional space of latent scales was constructed and Ukrainian's regions were positioned in this space. The results were interpreted meaningfully. This use of multidimensional statistical analysis confirms its usefulness for measuring the economic development of regions and allows their comprehensive assessment and comparison.

Published
2020

7. A Plane-Dependent Model of 3D Grid Cells for Representing Both 2D and 3D Spaces Under Various Navigation Modes.

Author

Gong, Ziyi and Yu, Fangwen

Subjects
GRID cells, RECURRENT neural networks, ENTORHINAL cortex
Abstract

Grid cells are crucial in path integration and representation of the external world. The spikes of grid cells spatially form clusters called grid fields, which encode important information about allocentric positions. To decode the information, studying the spatial structures of grid fields is a key task for both experimenters and theorists. Experiments reveal that grid fields form hexagonal lattice during planar navigation, and are anisotropic beyond planar navigation. During volumetric navigation, they lose global order but possess local order. How grid cells form different field structures behind these different navigation modes remains an open theoretical question. However, to date, few models connect to the latest discoveries and explain the formation of various grid field structures. To fill in this gap, we propose an interpretive plane-dependent model of three-dimensional (3D) grid cells for representing both two-dimensional (2D) and 3D space. The model first evaluates motion with respect to planes, such as the planes animals stand on and the tangent planes of the motion manifold. Projection of the motion onto the planes leads to anisotropy, and error in the perception of planes degrades grid field regularity. A training-free recurrent neural network (RNN) then maps the processed motion information to grid fields. We verify that our model can generate regular and anisotropic grid fields, as well as grid fields with merely local order; our model is also compatible with mode switching. Furthermore, simulations predict that the degradation of grid field regularity is inversely proportional to the interval between two consecutive perceptions of planes. In conclusion, our model is one of the few pioneers that address grid field structures in a general case. Compared to the other pioneer models, our theory argues that the anisotropy and loss of global order result from the uncertain perception of planes rather than insufficient training. [ABSTRACT FROM AUTHOR]

Published
2021
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8. A Plane-Dependent Model of 3D Grid Cells for Representing Both 2D and 3D Spaces Under Various Navigation Modes

Author

Ziyi Gong and Fangwen Yu

Subjects
grid cell, space representation, path integration, navigation, two-dimensional space, three-dimensional space, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Grid cells are crucial in path integration and representation of the external world. The spikes of grid cells spatially form clusters called grid fields, which encode important information about allocentric positions. To decode the information, studying the spatial structures of grid fields is a key task for both experimenters and theorists. Experiments reveal that grid fields form hexagonal lattice during planar navigation, and are anisotropic beyond planar navigation. During volumetric navigation, they lose global order but possess local order. How grid cells form different field structures behind these different navigation modes remains an open theoretical question. However, to date, few models connect to the latest discoveries and explain the formation of various grid field structures. To fill in this gap, we propose an interpretive plane-dependent model of three-dimensional (3D) grid cells for representing both two-dimensional (2D) and 3D space. The model first evaluates motion with respect to planes, such as the planes animals stand on and the tangent planes of the motion manifold. Projection of the motion onto the planes leads to anisotropy, and error in the perception of planes degrades grid field regularity. A training-free recurrent neural network (RNN) then maps the processed motion information to grid fields. We verify that our model can generate regular and anisotropic grid fields, as well as grid fields with merely local order; our model is also compatible with mode switching. Furthermore, simulations predict that the degradation of grid field regularity is inversely proportional to the interval between two consecutive perceptions of planes. In conclusion, our model is one of the few pioneers that address grid field structures in a general case. Compared to the other pioneer models, our theory argues that the anisotropy and loss of global order result from the uncertain perception of planes rather than insufficient training.

Published
2021
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9. Two-dimensional helium-like atom in a homogeneous magnetic field: Numerically exact solutions.

Author

Ly, Duy-Nhat, Hoang-Trong, Duong D., Phan, Ngoc-Hung, Nguyen, Duy-Anh P., and Le, Van-Hoang

Subjects
*MAGNETIC fields, *MAGNETIC flux density, *SCHRODINGER equation, *EQUATIONS of motion, *HELIUM atom, *COMPILERS (Computer programs), *LINUX operating systems, *ATOMS
Abstract

A two-dimensional helium atom (2D-helium) is a real subject for current studies, particularly regarding a hot topic of negatively charged excitons (trions) in semiconducting monolayers. The present study considers a 2D-helium-like atom in a homogeneous magnetic field. We are able to rewrite its Schrödinger equation into a polynomial form concerning dynamic variables. This form is useful for utilizing the algebraic calculation by annihilation and creation operators, enabling the successful application of the Feranchuk-Komarov (FK) operator method to obtain numerically exact solutions (energies and wave functions) for this system. The polynomialization of the equation allows obtaining analytical expressions of all matrix elements, which saves the computational resources significantly. Numerical results for the case without a magnetic field are comparable to other calculations. Moreover, the precise separation of the center-of-mass motion, as provided in this study, leads to an equation for the relative motion of the electrons in a magnetic field, incorporating all previously neglected terms. This result is useful for further study of trions where the electron effective mass is comparable with the hole effective mass. Additionally, we provide a FORTRAN program designed to solve the problems above. Program Title: CHeAMF CPC Library link to program files: https://doi.org/10.17632/mp8tf2dz67.1 Licensing provisions: BSD 3-clause Programming language: FORTRAN90 Nature of problem: The Schrödinger equation for a 2D-helium-like atom in a homogeneous magnetic field is transformed into a polynomial form using the Levi-Civita transformation twice. This transformation results in a structure more conductive to applying algebraic methods based on annihilation and creation operators. Consequently, we employ the FK operator method [1] to obtain numerically exact solutions, ensuring that the calculated energies converge to a high level of precision, up to 15 decimal places in this study. This method is developed to cover a broad range of magnetic field intensities, extending up to 0.1 a.u. (2.35 × 10 4 Tesla). Moreover, it is applicable not only for the ground state but also for highly excited states. Solution method: The modified FK operator method, as introduced in reference [2], has been developed and applied to obtain precise numerical solutions for a 2D-helium-like atom. Concurrently, algebraic techniques have been employed to compute matrix elements. Subsequently, we transformed the Schrödinger equation into a linear matrix equation, which we solved using the 'dsygvx.f' subroutine from the LAPACK library [3]. This subroutine has been optimized for improved accuracy by employing real*16 variables instead of real*8. Furthermore, we have incorporated an optimal free parameter into the FORTRAN program, enhancing convergence speed. Additional comments including restrictions and unusual features: Operating system: Linux. RAM: at least 4 GByte per core. We recommend using the gFortran compiler for this program. The runtime varies from a few minutes to hours, depending on the required precision. Particularly for strong magnetic fields (γ ≥ 0.01 a.u.) or when working with excited levels, the runtime may extend to several hours to achieve a precision of 16 decimal places. In such cases, it is advisable to have at least 60 GB of RAM per core. [1] I. Feranchuk, A. Ivanov, Van-Hoang Le, A. Ulyanenkov, Non-perturbative Description of Quantum Systems, Springer, Switzerland, 2015, https://doi.org/10.1007/978-3-319-13006-4. [2] Thanh-Xuan H. Cao, Duy-Nhat Ly, Ngoc-Tram D. Hoang, Van-Hoang Le, High-accuracy numerical calculations of the bound states of a hydrogen atom in a constant magnetic field with arbitrary strength, Comput. Phys. Commun. (2019), https://doi.org/10.1016/j.cpc.2019.02.013. [3] Netlib.org. LAPACK: Linear Algebra PACKage, Subroutine dsygvx.f, https://netlib.org/lapack/explore-3.1.1-html/dsygvx.f.html. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Lie symmetry analysis, explicit solutions, and conservation laws of the time-fractional Fisher equation in two-dimensional space

Author

Rawya Al-Deiakeh, Shaher Momani, Omar Abu Arqub, and Mohammed Al-Smadi

Subjects
Power series, Nonlinear system, Conservation law, Environmental Engineering, Two-dimensional space, Homogeneous space, Fisher equation, Applied mathematics, Ocean Engineering, Oceanography, Space (mathematics), Symmetry (physics), Mathematics
Abstract

In these analyses, we consider the time-fractional Fisher equation in two-dimensional space. Through the use of the Riemann-Liouville derivative approach, the well-known Lie point symmetries of the utilized equation are derived. Herein, we overturn the fractional fisher model to a fractional differential equation of nonlinear type by considering its Lie point symmetries. The diminutive equation's derivative is in the Erdelyi-Kober sense, whilst we use the technique of the power series to conclude explicit solutions for the diminutive equations for the first time. The conservation laws for the dominant equation are built using a novel conservation theorem. Several graphical countenances were utilized to award a visual performance of the obtained solutions. Finally, some concluding remarks and future recommendations are utilized.

Published
2022

12. Leaderless cooperative control of robotic sensor networks for monitoring dynamic pollutant plumes.

Author

Wang, Jun‐Wei and Guo, Yi

Abstract

In this paper, the problem of cooperative control of robotic sensor networks (RSNs) for monitoring dynamic pollutant plumes in two‐dimensional (2D) space is studied. The pollutant plume propagation dynamics is governed by a 2D advection‐diffusion partial differential equation (PDE), and the plume front is modelled by a level set with a pre‐specified threshold value. Distributed consensus Luenberger‐type PDE observers are first constructed using local concentration measurements from the RSNs for unanimous estimate of the dynamic concentration field over the entire spatial domain. With the aid of the distributed consensus observers, a leaderless cooperative control scheme is then developed for the RSNs to monitor the dynamic plume front expansion. It is proved using the Lyapunov stability method and set stability concept that the proposed cooperative control scheme guarantees tracking of the dynamic plume front expansion and coverage of the plume front. Extensive numerical simulation results demonstrate the effectiveness and merit of the proposed cooperative control scheme. [ABSTRACT FROM AUTHOR]

Published
2019
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13. Disturbance‐observer‐based antiswing control of underactuated crane systems via terminal sliding mode.

Author

Zhang, Zhongcai, Li, Li, and Wu, Yuqiang

Abstract

In this study, based on the finite‐time sliding mode control method, an antiswing control law is designed for the underactuated crane systems in two‐dimensional space with external disturbance. The finite‐time disturbance observer is utilised to estimate the external disturbance and develop the finite‐time control law. The designed controller can regulate the trolley to the planned trajectory within a finite time in the presence of external disturbance. Then it can be shown that the proposed control approach can achieve precise trolley positioning and swing suppression. Simulation results are provided to show the satisfactory control performances of the presented control method in terms of working efficiency as well as robustness with respect to external disturbance. [ABSTRACT FROM AUTHOR]

Published
2018
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14. Στοιχεία από τη Γραμμική Άλγεβρα

Author

Charalambous, Hara and Vavatsoulas, Charilaos

Subjects
Μιγαδικοί Αριθμοί, norm, Περιστροφή, eigenspaces, Πίνακας, two-dimensional space, Determinant, Χαρακτηριστικό Πολυώνυμο, eigenvectors, Linear systems, Βαθμίδα, Μέτρο, rotation, Επίπεδα, similar matrices, basis, όμοιοι πίνακες, Τρισδιάστατος χώρος, βάση, complex numbers, Ευθείες, Δισδιάστατος χώρος, Linear functions, Αλγόριθμος του Gauss, Ιδιοδιανύσματα, Matrix, Ιδιοχώροι, γραμμική ανεξαρτησία, Ορίζουσα, Gaussian algorithm, Ιδιοτιμές, Eigenvalues, Γραμμικές Συναρτήσεις, Rank, Αντικατοπτρισμός, Όρισμα, Γραμμικά Συστήματα, γραμμική εξάρτηση, συμμετρικοί πίνακες, symmetric matrices, planes, argument, linear independence, Lines, characteristic polynomial, linear dependece, reflection, three-dimensional space
Abstract

Το σύγγραμμα επιχειρεί να συνεισφέρει σε μία ομαλή μετάβαση από την ύλη του λυκείου στις μαθηματικές έννοιες που είναι απαραίτητες για την κατανόηση της Γραμμικής Άλγεβρας και της Αναλυτικής Γεωμετρίας. Η ύλη που καλύπτεται περιλαμβάνει τους Μιγαδικούς αριθμούς, την Άλγεβρα πινάκων (πίνακας, πράξεις πινάκων, είδη πινάκων, αντίστροφος), το πραγματικό επίπεδο, ο τρισδιάστατος χώρος, γραμμικές απεικονίσεις (με τη βοήθεια πινάκων), Μέθοδος απαλοιφής Gauss, Ορίζουσες, Επίλυση γραμμικών συστημάτων. Ιδιοτιμές, Ιδιοδιανύσματα Πινάκων. Η έμφαση δίνεται στη γεωμετρική ερμηνεία των παραπάνω εννοιών. Η καινοτομία του προτεινόμενου συγγράμματος έγκειται στο ότι ενσωματώνει τη χρήση του υπολογιστικού προγράμματος Mathematica σε ξεχωριστή ενότητα σε κάθε κεφάλαιο. Έτσι γίνονται δυνατοί οι πειραματισμοί και οι εξερευνήσεις και ο αναγνώστης μπορεί να εμπεδώσει καλύτερα τη γνώση και να εξοικειωθεί με τον ηλεκτρονικό τρόπο επίλυσης αριθμητικών προβλημάτων στη Γραμμική Άλγεβρα.

Published
2023
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15. On an inverse curvature flow in two-dimensional space forms

Author

Kwok-Kun Kwong, Valentina-Mira Wheeler, Yong Wei, and Glen Wheeler

Subjects
Mathematics - Differential Geometry, Geodesic, General Mathematics, 010102 general mathematics, Mathematical analysis, 53E10, Space (mathematics), Curvature, 01 natural sciences, Ambient space, Mathematics - Analysis of PDEs, Differential Geometry (math.DG), Two-dimensional space, Flow (mathematics), 0103 physical sciences, FOS: Mathematics, 010307 mathematical physics, 0101 mathematics, Isoperimetric inequality, Analysis of PDEs (math.AP), Mathematics, Counterexample
Abstract

We study the evolution of compact convex curves in two-dimensional space forms. The normal speed is given by the difference of the weighted inverse curvature with the support function, and in the case where the ambient space is the Euclidean plane, is equivalent to the standard inverse curvature flow. We prove that solutions exist for all time and converge exponentially fast in the smooth topology to a standard round geodesic circle. This has a number of consequences: first, to prove the isoperimetricinequality; second, to establish a range of weighted geometric inequalities; and third, to give a counterexample to the $n=2$ case of a conjecture of Gir\~ao-Pinheiro., Comment: 17 pages

Published
2021

16. Optimal placement of sampling locations for identification of a two-dimensional space

Author

Ikumasa Yoshida, Yukihisa Tomizawa, and Yosuke Tasaki

Subjects
Identification (information), Two-dimensional space, Computer science, Kriging, Sampling (statistics), Geology, Building and Construction, Geotechnical Engineering and Engineering Geology, Safety, Risk, Reliability and Quality, Algorithm, Civil and Structural Engineering, Gaussian random field, Value of information
Abstract

In recent years, substantial attention has been given to the optimal placement and planning of sampling or monitoring based on the Value of Information (VoI). The drawback of the VoI approach is it...

Published
2021

17. General decay of energy to a nonlinear viscoelastic two-dimensional beam.

Author

Lekdim, B. and Khemmoudj, A.

Subjects
*NONLINEAR analysis, *VISCOELASTIC materials, *EXPONENTIAL decay law, *LYAPUNOV functions, *NONLINEAR systems
Abstract

A viscoelastic beam in a two-dimensional space is considered with nonlinear tension. A boundary feedback is applied at the right boundary of the beam to suppress the undesirable vibration. The well-posedness of the problem is established. With the multiplier method, a uniform decay result is proven. [ABSTRACT FROM AUTHOR]

Published
2018
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18. The finite volume element method for the two-dimensional space-fractional convection–diffusion equation

Author

Ziwen Jiang and Yanan Bi

Subjects
Algebra and Number Theory, Partial differential equation, Finite volume element method, Discretization, Applied Mathematics, Derivative, Fractional derivative, Convection–diffusion equation, Stability (probability), Two-dimensional space, Ordinary differential equation, Convergence (routing), QA1-939, Applied mathematics, Convergence, Stability, Analysis, Mathematics
Abstract

We develop a fully discrete finite volume element scheme of the two-dimensional space-fractional convection–diffusion equation using the finite volume element method to discretize the space-fractional derivative and Crank–Nicholson scheme for time discretization. We also analyze and prove the stability and convergence of the given scheme. Finally, we validate our theoretical analysis by data from three examples.

Published
2021

21. Modeling Plant Stems Using the Deterministic Lindenmayer System

Author

Juhari Juhari and Muhammad Zia Alghar

Subjects
0106 biological sciences, 0301 basic medicine, Pine tree, General Medicine, Object (computer science), 01 natural sciences, Visualization, 03 medical and health sciences, 030104 developmental biology, Two-dimensional space, Plant morphology, Parametric model, Stage (hydrology), Algorithm, 010606 plant biology & botany, Parametric statistics, Mathematics
Abstract

Plant morphology modeling can be done mathematically which includes roots, stems, leaves, to flower. Modeling of plant stems using the Lindenmayer System (L-system) method is a writing returns that are repeated to form a visualization of an object. Deterministic L-system method is carried out by predicting the possible shape of a plant stem using its iterative writing rules based on the original object photo. The purpose of this study is to find a model of the plant stem with Deterministic Lindenmayer System method which will later be divided into two dimensional space three. The research was conducted by identifying objects in the form of pine tree trunks measured by the angle, thickness, and length of the stem. Then a deterministic and parametric model is built with L-system components . The stage is continued by visualizing the model in two dimensions and three dimensions. The result of this research is a visualization of a plant stem model that is close to the original. Addition color, thickness of the stem, as well as the parametric writing is done to get the results resembles the original. The iteration is limited to less than 20 iterations so that the simulation runs optimal.

Published
2021

22. Numerical investigation of the two-dimensional space-time fractional diffusion equation in porous media

Author

B. Farnam, O. Nikan, and Y. Esmaeelzade Aghdam

Subjects
Statistics and Probability, Numerical Analysis, Discretization, Applied Mathematics, 010102 general mathematics, Mathematical analysis, Order (ring theory), Derivative, 01 natural sciences, Stability (probability), Chebyshev filter, Computer Science Applications, 010101 applied mathematics, Alpha (programming language), Two-dimensional space, Signal Processing, Convergence (routing), 0101 mathematics, Analysis, Information Systems, Mathematics
Abstract

This paper develops the approximate solution of the two-dimensional space-time fractional diffusion equation. Firstly, the time-fractional derivative is discretized with a scheme of order $${\mathcal {O}}({\delta \tau }^{2-\alpha }),~ 0

Published
2021

23. Block generation in a two-dimensional space constructed by Hellinger metric and affinity for weather data fusion and learning inputs

Author

Xu Haitao, Aihong Chen, Jing Chen, and Weimin Peng

Subjects
Computer Networks and Communications, Computer science, 020206 networking & telecommunications, 02 engineering and technology, Sensor fusion, Metric space, Matrix (mathematics), Two-dimensional space, Hardware and Architecture, Position (vector), Metric (mathematics), 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Rectangle, Algorithm, Software, Block (data storage)
Abstract

The concise and reliable representation of a given source dataset is available for data based learning and decision-making, which can be obtained through a controllable data fusion process within a formatted space. Based on the density matrix representation of a given source weather dataset, this paper first calculates the Hellinger distances and affinities between different density matrices, and then takes them to construct a two-dimensional metric space using the longest Hellinger metric and affinity paths. Within this space, the given source data units are converted into the corresponding rectangle nodes which are determined by the minimum horizontal and vertical distances between different data units. According to a predefined detection size in this space, the basic blocks centred by different rectangle nodes are classified into different subset blocks for fusion. Each subset block is jointed by the basic blocks with overlapped areas. During the detection process, the detection size keeps increasing until a predefined reference variable, such as the relative density for all subset blocks, reaches a predefined turning point. The fusion of the rectangle nodes in a subset block depends on the distances between the included rectangle nodes’ positions and this subset block’s centre position which is calculated according to the included rectangle nodes’ weights and positions. The experimental analysis shows that the proposed weather data fusion method is controllable and stable and can obtain concise and reliable fusion results for learning inputs and decision-making.

Published
2021

24. Boundary control of a flexible crane system in two‐dimensional space.

Author

Zhang, Shuang and He, Xiuyu

Abstract

A flexible crane system with vibrating and varying cable is investigated in two‐dimensional space. Two partial differential equations and four ordinary differential equations derived by the Hamilton's principle are used to describe the dynamics of the flexible crane system. The dynamic model of the crane system considers the variation of the tension of the cable. Boundary control design is given to suppress vibrations of the flexible crane system. The Lyapunov's direct method is employed to prove the uniform ultimate boundedness of the states of the cable system. The effectiveness and performance of the proposed control schemes are depicted via numerical simulations. [ABSTRACT FROM AUTHOR]

Published
2017
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26. On the Classification of Fractal and Non-Fractal Objects in Two-Dimensional Space

Author

K. A. Pshenichnyi, P. M. Pustovoit, S. V. Grigoriev, and E. G. Yashina

Subjects
Physics, 010304 chemical physics, Mathematical analysis, Mathematics::General Topology, Boundary (topology), Koch snowflake, 01 natural sciences, Fractal dimension, Surfaces, Coatings and Films, Sierpinski triangle, Fractal, Two-dimensional space, Sierpinski carpet, 0103 physical sciences, Snowflake, 010306 general physics
Abstract

The method of numerical Fourier analysis is used to investigate the fractal properties of 2D objects with micrometer–centimeter sizes. This numerical method simulates the small-angle light scattering experiment. Different geometric 2D-regular fractals, such as the Sierpinski carpet, Sierpinski triangle, Koch snowflake, and Vishek snowflake, are studied. We can divide 2D fractals, by analogy with 3D fractals, into “plane” and “boundary” fractals with fractal dimensions lying in the intervals from 1 to 2 and from 2 to 3, respectively. For an object with a smooth boundary, i.e., a circle, the model small-angle scattering curve decreases according to the power law q–3, where q is the momentum transferred.

Published
2020

27. TT-M finite element algorithm for a two-dimensional space fractional Gray–Scott model

Author

Hong Li, Jinfeng Wang, Baoli Yin, Enyu Fan, and Yang Liu

Subjects
Correctness, Iterative method, Stability (learning theory), 010103 numerical & computational mathematics, Grid, 01 natural sciences, Finite element method, 010101 applied mathematics, Computational Mathematics, Nonlinear system, Computational Theory and Mathematics, Two-dimensional space, Modeling and Simulation, Applied mathematics, A priori and a posteriori, 0101 mathematics, Mathematics
Abstract

In this article, a fast time two-mesh (TT-M) finite element (FE) method for the two-dimensional space fractional Gray–Scott model is studied and discussed to get the numerical solutions effectively. The method mainly includes three steps: firstly, one uses an iterative method for solving the coupled nonlinear system on the time coarse grid; secondly, by an interpolation formula, one can get any coarse values on the time fine mesh; finally, based on the computed coarser solutions, a linear FE system on time fine mesh can be constructed by using the two-variables Taylor’s formula. Here, some theoretical results, which include stability and a priori error for the fully discrete scheme, are analyzed and proved. Furthermore, the computing data are given to verify the correctness of the theoretical results and to illustrate that the TT-M FE algorithm can reduce the computing time.

Published
2020

28. Linearized ADI schemes for two-dimensional space-fractional nonlinear Ginzburg–Landau equation

Author

Xiaoman Lin, Yunzhu Ren, Qifeng Zhang, and Kejia Pan

Subjects
Numerical analysis, Mathematical analysis, Extrapolation, Finite difference method, 010103 numerical & computational mathematics, Abstract space, Space (mathematics), 01 natural sciences, 010101 applied mathematics, Computational Mathematics, Nonlinear system, Alternating direction implicit method, Computational Theory and Mathematics, Two-dimensional space, Modeling and Simulation, 0101 mathematics, Mathematics
Abstract

Space and time approximations for two-dimensional space fractional complex Ginzburg–Landau equation are examined. The schemes under consideration are discreted by the second-order backward differential formula (BDF2) in time and two classes of the fractional centered finite difference methods in space. A linearized technique is employed by the extrapolation. We prove the unique solvability and stability for both numerical methods. The convergence of both numerical methods is analyzed at length utilizing the energy argument, and the convergence orders under the optimal step size ratio are O ( τ 2 + h 2 ) and O ( τ 2 + h 4 ) in the sense of the discrete L 2 -norm, where τ is the time step size, h = max { h x , h y } , and h x , h y are spatial grid sizes in the x -direction and y -direction, respectively. In addition, we construct a multistep alternating direction implicit (ADI) scheme and a multistep compact ADI scheme based on BDF2 for the efficiently numerical implementation. Finally, numerical examples are carried out to verify our theoretical results.

Published
2020

29. Global classical solutions and convergence to a mathematical model for cancer cells invasion and metastatic spread

Author

Chunhua Jin

Subjects
Steady state, Applied Mathematics, 010102 general mathematics, 01 natural sciences, 010101 applied mathematics, Strong solutions, Two-dimensional space, Convergence (routing), Uniform boundedness, Uniqueness, Boundary value problem, 0101 mathematics, Analysis, Mathematics, Mathematical physics
Abstract

In this paper, we consider the following system { u t = Δ u − χ ∇ ⋅ ( u ∇ ω ) , v t = d v Δ v − ξ ∇ ⋅ ( v ∇ ω ) , m t = d m Δ m + u − m , ω t = − ( γ 1 u + m ) ω , in two dimensional space with zero-flux boundary conditions. This model was proposed by Franssen et al. [7] to characterize the invasion and metastatic spread of cancer cells. We first establish the global existence of uniformly bounded global strong solutions. Then using the decay of ECM and the positivity of MDE, we further improve the regularity of obtained solutions, and achieve the uniform boundedness of solutions in the classical sense. Subsequently, we also prove the uniqueness of solutions. After that, we turn our attention to the large time behavior of solutions, and show that the global classical solution strongly converges to a semi-trivial steady state in the large time limit.

Published
2020

30. Kinematics of interacting solitons in two-dimensional space

Author

Yury Stepanyants and Lev A. Ostrovsky

Subjects
Physics, Surface (mathematics), 010504 meteorology & atmospheric sciences, Integrable system, Kinematics, Internal wave, 010502 geochemistry & geophysics, 01 natural sciences, Nonlinear Sciences::Exactly Solvable and Integrable Systems, Classical mechanics, Two-dimensional space, Simple (abstract algebra), General Earth and Planetary Sciences, Nonlinear Sciences::Pattern Formation and Solitons, 0105 earth and related environmental sciences
Abstract

A simple kinematic approach to the description of the interaction between solitons is developed. It is applicable to both integrable and non-integrable two-dimensional models, including those commonly used for studying the surface and internal oceanic waves. This approach allows obtaining some important characteristics of the interaction between solitary waves propagating at an angle to each other. The developed theory is validated by comparison with the exact solutions of the Kadomtsev-Petviashvili equation and then applied to the observed interaction of solitary internal waves in a two-layer fluid within the two-dimensional Benjamin-Ono model.

Published
2020

31. A second-order accurate scheme for two-dimensional space fractional diffusion equations with time Caputo-Fabrizio fractional derivative

Author

Jiankang Shi and Minghua Chen

Subjects
Numerical Analysis, Applied Mathematics, Numerical Analysis (math.NA), 010103 numerical & computational mathematics, 01 natural sciences, Fractional calculus, Exponential function, 010101 applied mathematics, Computational Mathematics, symbols.namesake, Two-dimensional space, Norm (mathematics), Mathematical induction, FOS: Mathematics, symbols, Applied mathematics, Initial value problem, Mathematics - Numerical Analysis, 0101 mathematics, Continuous-time random walk, Mathematics, Debye
Abstract

We provide and analyze a second order scheme for the model describing the functional distributions of particles performing anomalous motion with exponential Debye pattern and no-time-taking jumps eliminated, and power-law jump length. The model is derived in [M. Chen, J. Shi, W. Deng, arXiv:1809.03263], being called the space fractional diffusion equation with the time Caputo-Fabrizio fractional derivative. The designed schemes are unconditionally stable and have the second order global truncation error with the nonzero initial condition, being theoretically proved and numerically verified by two methods (a prior estimate with $L^2$-norm and mathematical induction with $l_\infty$ norm). Moreover, the optimal estimates are obtained., Comment: 19pages

Published
2020

32. Global strong solutions of a 2-D new magnetohydrodynamic system

Author

Jiayan Yang and Ruikuan Liu

Subjects
Strong solutions, Two-dimensional space, Mathematical analysis, Mathematics::Analysis of PDEs, Compressibility, Uniqueness, Magnetohydrodynamic drive, Stokes flow, Nirenberg and Matthaei experiment, Mathematics
Abstract

The main objective of this paper is to study the global strong solution of the parabolic-hyperbolic incompressible magnetohydrodynamic model in the two dimensional space. Based on Agmon, Douglis, and Nirenberg’s estimates for the stationary Stokes equation and Solonnikov’s theorem on Lp-Lq-estimates for the evolution Stokes equation, it is shown that this coupled magnetohydrodynamic equations possesses a global strong solution. In addition, the uniqueness of the global strong solution is obtained.

Published
2020

33. Spectral methods for two-dimensional space and time fractional Bloch-Torrey equations

Author

Hong Lu, Mingji Zhang, and Ji Li

Subjects
Alternating direction implicit method, Two-dimensional space, Spacetime, Applied Mathematics, Computation, Mathematical analysis, Convergence (routing), Finite difference method, Discrete Mathematics and Combinatorics, Spectral method, Space (mathematics), Mathematics
Abstract

In this paper, we consider the numerical approximation of the space and time fractional Bloch-Torrey equations. A fully discrete spectral scheme based on a finite difference method in the time direction and a Galerkin-Legendre spectral method in the space direction is developed. In order to reduce the amount of computation, an alternating direction implicit (ADI) spectral scheme is proposed. Then the stability and convergence analysis are rigorously established. Finally, numerical results are presented to support our theoretical analysis.

Published
2020

34. Parallel-in-time multigrid for space–time finite element approximations of two-dimensional space-fractional diffusion equations

Author

Shi Shu, Weiping Bu, Xiaoqiang Yue, Kejia Pan, and Xiaowen Xu

Subjects
Discretization, Space time, Stability (learning theory), Propagator, 010103 numerical & computational mathematics, 01 natural sciences, Finite element method, 010101 applied mathematics, Computational Mathematics, Multigrid method, Computational Theory and Mathematics, Two-dimensional space, Modeling and Simulation, Applied mathematics, 0101 mathematics, Diffusion (business), Mathematics
Abstract

The paper investigates a non-intrusive parallel time integration with multigrid for space-fractional diffusion equations in two spatial dimensions, which is discretized by the space–time finite element method to propagate solutions. We develop a multigrid-reduction-in-time (MGRIT) algorithm with time-dependent time-grid propagators and provide its two-level convergence theory under the assumptions of the stability and simultaneous diagonalizability on time-grid propagators. Numerical results show that the proposed method possesses the saturation error order, theoretical results of the two-level variant deliver good predictions for our model problems, and significant speedups of the MGRIT can be achieved when compared to the two-level variant with F-relaxation (an equivalent version of the parareal algorithm) and the sequential time-stepping approach.

Published
2019

35. On local strong solutions to the Cauchy problem of the two-dimensional full compressible magnetohydrodynamic equations with vacuum and zero heat conduction.

Author

Lu, Li and Huang, Bin

Subjects
*NUMERICAL solutions to the Cauchy problem, *TWO-dimensional models, *COMPRESSIBLE flow, *HEAT conduction, *VACUUM
Abstract

This paper concerns the Cauchy problem of the two-dimensional full compressible magnetohydrodynamic equations with zero heat-conduction and vacuum as far field density. In particular, the initial density can have compact support. We prove that the Cauchy problem admits a local strong solution provided both the initial density and the initial magnetic field decay not too slow at infinity. [ABSTRACT FROM AUTHOR]

Published
2016
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36. Spherical interpolation method of emitter localisation using weighted least squares.

Author

Noroozi, Ali and Sebt, Mohammad Ali

Abstract

In this study, a new noise model is presented to address the issue of finding an emitting target using time difference of arrival measurements, based on the range between the emitter and a known sensor. To improve the performance of the estimator under the proposed noise model, a weighted version of the spherical interpolation method is proposed and then two weighting matrices required in the method are derived in two different conditions. A detailed theoretical error analysis associated with this algorithm is presented and the Cramer–Rao lower bound is also derived. Simulation studies verify the validity of the proposed error analysis. In addition, in a two‐dimensional space and in the case of a minimal number of sensors, the authors analytically determine the sensors layout in which the location solution is not unique. Via simulations, several placements in a covered region are studied to select the appropriate placement in which the root mean square error of the target position estimation is minimised. Furthermore, simulation results show that they can do this work by the derived expression of the error analysis, which leads to the same outcome. [ABSTRACT FROM AUTHOR]

Published
2016
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37. Elementary operations for rigidity restoration and persistence analysis of multi‐agent system.

Author

Hou, Yun and Yu, Changbin

Abstract

This work focuses on the construction of rigid formation from non‐rigid ones in the two‐dimensional space. Analogously to operations of Henneberg sequence aiming to guarantee the minimal rigidity of formation, two new operations are introduced, allowing one to sequentially build any rigid graph by connecting non‐rigid ones. A systematic construction sequence is developed based on proposed operations, and is shown to be able to restore rigidity by introducing minimum number of new edges during the construction process. Further applications of the proposed operations are also presented, one of which is successfully employed in the problem of persistence analysis of directed graphs, and can verify the persistence of a given graph with a speed two times faster comparing with existing solution. [ABSTRACT FROM AUTHOR]

Published
2016
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38. A general theory of polymer ejection tested in a quasi two-dimensional space

Author

Pai-Yi Hsiao and Wei-Yei Chen

Subjects
Science, Biophysics, Boundary (topology), 02 engineering and technology, Space (mathematics), 01 natural sciences, Article, Nanopores, Molecular dynamics, Variational principle, 0103 physical sciences, 010306 general physics, Scaling, Physics, Quantitative Biology::Biomolecules, Multidisciplinary, Atmospheric escape, Molecular engineering, Mechanics, 021001 nanoscience & nanotechnology, Nanopore, Two-dimensional space, Medicine, 0210 nano-technology, Biological physics
Abstract

A general ejection theory of polymer is developed in a two- and three-dimensional space.A polymer is confined initially in a cavity and ejects spontaneously to the outer space through a nanopore channel without the help of any external stimulus. A reflective wall boundary is set at the pore entrance to prevent the falling of the head monomer of chain into the cavity. Three stages are distinguished in a process: (1) the entering stage, in which the head monomer enters the pore to search for a way to traverse the pore channel, (2) the main ejection stage, in which the chain body is transported from the cavity to the outer space, (3) the leaving stage, in which the tail monomer passes through and leaves the pore channel. Depending on the number of the monomers remaining in the cavity, the main ejection stage can be divided into the confined and the non-confined stages. The non-confined stage can be further split into the thermal escape and the entropic pulling stages. The Onsager's variational principle is used to derive the kinetics equation of ejection. The escape time is calculated from the corresponding Kramers' escape problem.Extensive molecular dynamics simulations are then performed in a quasi two-dimensional space to verify the theory. The variation of the ejection speed is carefully examined in a process. The decreasing behavior of the number of monomers in the cavity is studied in details. The scaling properties of the spending time at each processing stage are investigated systematically by varying the chain length, the cavity diameter, and the initial volume fraction of chain. The results of simulation support firmly the predictions of the theory, cross-checked in the studies of various topics. Together with the previous investigations in the three-dimensional space, the generalized theory is very robust able to explain the two seemly different phenomena, polymer ejection and polymer translocation, under the same theoretical framework in the two space dimensions.

Published
2021

39. Two-Dimensional Space-Time Image Velocimetry for Surface Flow Field of Mountain Rivers Based on UAV Video

Author

Xiaolin Han, Kebing Chen, Qiang Zhong, Qigang Chen, Fujun Wang, and Danxun Li

Subjects
010504 meteorology & atmospheric sciences, river surface velocity, Science, 0208 environmental biotechnology, Magnitude (mathematics), Oblique case, Terrain, 02 engineering and technology, Velocimetry, Geodesy, 01 natural sciences, 020801 environmental engineering, Two-dimensional space, Flow (mathematics), image analysis, unmanned aerial vehicle (UAV), Streamflow, Line (geometry), General Earth and Planetary Sciences, mountain flash floods, space-time image velocimetry (STIV), Geology, 0105 earth and related environmental sciences
Abstract

Space-time image velocimetry (STIV) is a promising technique for river surface flow field measurement with the development of unmanned aerial vehicles (UAVs). STIV can give the magnitude of the velocity along the search line set manually thus the application of the STIV needs to determine the flow direction in advance. However, it is impossible to judge the velocity direction at any points before measurement in most mountainous rivers due to their complex terrain. A two-dimensional STIV is proposed in this study to obtain the magnitude and direction of the velocity automatically. The direction of river flow is independently determined by rotating the search line to find the space-time image which has the most prominent oblique stripes. The performance of the two-dimensional STIV is examined in the simulated images and the field measurements including the Xiasi River measurements and the Kuye River measurements, which prove it is a reliable method for the surface flow field measurement of mountain rivers.

Published
2021

40. Impact Vibration Source Localization in Two-Dimensional Space Around Hand

Author

Ryunosuke Tokuhisa, Sho Sakurai, Koichi Hirota, and Yusuke Ujitoko

Subjects
Computer science, Acoustics, Vibration source, Posture, Impulse (physics), Hand, Vibration, Computer Science Applications, Human-Computer Interaction, Fingers, Two-dimensional space, Position (vector), Touch, Humans, Actuator
Abstract

This study investigated the localization ability of an impulse vibration source outside the body in two-dimensional space. We tested whether humans can recognize the direction or distance of an impulse vibration source when using their hand to detect spatiotemporal vibrotactile information provided by the propagated vibrational wave from the source. Specifically, we had users put their hands on a silicone rubber sheet in several postures. We asked users to indicate the position of the vibration source when a location on the sheet was indented. Experimental results suggested that the direction of the impact vibration source can be recognized to some extent, although recognition accuracy depends on hand posture and the position of the vibration source. The best results were achieved when the fingers and palm were grounded and a vibration source was presented around the middle fingertip, and the directional recognition error in this case was 6 degree. In contrast, results suggest it is difficult to accurately recognize the distance of the vibration. The results of this study suggest a new possibility for directional display where vibrotactile actuators are embedded at a distance from the user's hand.

Published
2021

42. Fractional cable problem in the frame of meshless singular boundary method

Author

Mohammad Aslefallah, Saeid Abbasbandy, and Elyas Shivanian

Subjects
Discretization, Applied Mathematics, Numerical analysis, General Engineering, Finite difference method, 02 engineering and technology, Singular boundary method, 01 natural sciences, Fractional calculus, 010101 applied mathematics, Method of undetermined coefficients, Computational Mathematics, 020303 mechanical engineering & transports, 0203 mechanical engineering, Two-dimensional space, Applied mathematics, Boundary value problem, 0101 mathematics, Analysis, Mathematics
Abstract

In this study, singular boundary method (SBM) is employed for solving fractional cable problem in two dimensional space with initial and Dirichlet-type boundary conditions. The process is modeled as a two dimensional time-fractional equation in sense of Riemann–Liouville fractional derivatives. A splitting scheme is applied to split the solution of the inhomogeneous governing equation into homogeneous solution and particular solution. We present the numerical operation for calculating the particular solution and homogeneous solution. For achieving approximation particular solution and homogeneous solution, we employ Method of Particular solution (MPS) and SBM, respectively. We use θ-weighted and finite difference method as time discretization for time derivatives. A comparison between the present method and other methods is given to show the accuracy of SBM applying on this equation. Consequently, some numerical examples with different domains are tested and compared with the exact analytical solutions to display the validity and accuracy of the numerical method in comparison with other methods.

Published
2019

44. Identifying the Ground-State NP Sheet through a Global Structure Search in Two-Dimensional Space and Its Promising High-Efficiency Photovoltaic Properties

Author

Xiaolei Feng, Hanyu Liu, Zebin Lao, Bai Sun, Hongyan Wang, Simon A. T. Redfern, Jian Lv, Yuanzheng Chen, and Zhongfang Chen

Subjects
Materials science, business.industry, General Chemical Engineering, Photovoltaic system, Biomedical Engineering, Stability (probability), Phosphorene, chemistry.chemical_compound, chemistry, Two-dimensional space, Optoelectronics, General Materials Science, business, Ground state, Global structure
Abstract

Recently fabricated two-dimensional (2D) black phosphorene (BP) is considered to be a promising optoelectronic sheet, but its applications are hindered by the poor stability in air. Thus, it is des...

Published
2019

45. Optimization of Secondary Sources Configuration in Two-Dimensional Space Based on Sound Field Decomposition and Sparsity-Inducing Regularization

Author

Bing Zhou, Kean Chen, Jian Xu, and Lei Wang

Subjects
Underdetermined system, Computer science, Noise reduction, secondary sources configuration, General Engineering, Stability (learning theory), TL1-4050, Function (mathematics), algorithms, Regularization (mathematics), Two-dimensional space, Genetic algorithm, sparsity-inducing regularization, active noise control, optimization, Algorithm, sound field decomposition, Motor vehicles. Aeronautics. Astronautics, Active noise control
Abstract

During the design of transducers configuration for an active noise control system, current optimization methods need to predetermine the error sensors configuration, which significantly increases the workload of later optimization of the secondary sources configuration. In this study, a new method free from specific error sensors configuration information is presented that higher order microphones are used to capture the sound field so as to formulate the cost function in wave domain. In addition, according to sparsity characteristics of the primary sound field, sparsity-inducing regularization is introduced to optimize the secondary sources configuration, including the number and positions, by calculating a sparse approximate solution to underdetermined equations. Effects of the number of candidate secondary sources are discussed, and the comparison with the uniform configuration and the optimized configuration using the genetic algorithm is performed. Results show that the proposed method can optimize the secondary sources configuration effectively independent of the error sensors configuration information. The noise reduction of the proposed method is close to that by the genetic algorithm, while other evaluation metrics for the system are much better, which would benefit the stability of active noise control system.

Published
2019

48. A novel analysis of spun yarn hairiness inside limited two-dimensional space

Author

Xia Zhigang, Bo Deng, KeZuo Wang, Xin Liu, and Xu Weilin

Subjects
Materials science, Polymers and Plastics, Two-dimensional space, visual_art, visual_art.visual_art_medium, Chemical Engineering (miscellaneous), Yarn, Composite material
Abstract

Surface hairiness of spun yarns is critical to the yarn post-processing deficiency and resultant fabric quality. Several test methods are available for measuring yarn hairiness but they cannot detect the accurate hair amount and precise hair length. This paper provides a novel method to perform accurate hairiness tests on the spun yarn. A new test apparatus was devised by installing a blowing pipe outside of the hairiness testing area comprising a projection receiver and a corresponding laser. The rectangle end plane of the blowing pipe air inlet is vertical to the laser plane and tangent to the edge line of the projection receiver surface. Pressure generated through this inlet stretches yarn wild hairiness straightly in one direction, and fully maps accurate hairiness amount and length configuration on the projection receiver surface. The subsequent measurement showed that this novel test apparatus detected more hairiness with improved accuracy in both number and length of hairiness. Approximately real gravimetric hairiness weight can be obtained by this method which is impracticable for other conventional photoelectric apparatus.

Published
2019

49. Numerical analysis and fast implementation of a fourth-order difference scheme for two-dimensional space-fractional diffusion equations

Author

Zhiyong Xing and Liping Wen

Subjects
Physics, 0209 industrial biotechnology, Applied Mathematics, Numerical analysis, Mathematical analysis, 020206 networking & telecommunications, 02 engineering and technology, Grid, Computational Mathematics, symbols.namesake, 020901 industrial engineering & automation, Positive definiteness, Two-dimensional space, Norm (mathematics), Dirichlet boundary condition, Conjugate gradient method, 0202 electrical engineering, electronic engineering, information engineering, symbols, Coefficient matrix
Abstract

In this paper, a fourth-order difference scheme (FODS) is proposed for solving the two-dimensional Riesz space-fractional diffusion equations with homogeneous Dirichlet boundary conditions. It is proved that the FODS is uniquely solvable, unconditionally stable, and convergent with order O ( τ 2 + h x 4 + h y 4 ) in the discrete L∞- norm, where τ is the time step size, and hx, hy are the space grid sizes in the x direction and the y direction, respectively. Based on the special structure and symmetric positive definiteness of the coefficient matrix, a fast method is developed for the implementation of the FODS. The fast method reduces the storage requirement of O(N2) and computational cost of O(N3) down to O ( M + J ) and O(Nlog N), where N = M J , M and J are the numbers of the spatial grid points in the x direction and the y direction, respectively. Finally, several numerical results are shown to verify the theoretical results and the efficiency of the fast method.

Published
2019

50. Numerical investigation of a mixture two-phase flow model in two-dimensional space

Author

Dia Zeidan, Peter Farber, Peer Ueberholz, P. Bähr, and J. Gräbel

Subjects
Finite volume method, General Computer Science, Numerical analysis, General Engineering, Relative velocity, Mixture model, 01 natural sciences, 010305 fluids & plasmas, 010101 applied mathematics, Two-dimensional space, Flow (mathematics), 0103 physical sciences, Applied mathematics, Two-phase flow, Flux limiter, 0101 mathematics, Mathematics
Abstract

A two-dimensional two-phase flow model for gas-liquid mixture is presented. The model takes into account the relative velocity between the gas and liquid phases and is based on conservation equations for gas-liquid mixtures. The mixture model involves balance equations for the relative velocity and is able to handle it without any physical or artificial stabilization in the source terms. The novel aspect of the mixture model is that it is written in a conservative form and ensures the hyperbolicity of the two-phase flow equations. With this regard, the governing equations are solved with finite volume methods. We extend and apply the framework of Godunov methods of centred-type, namely, the FirstOrder Centered (FORCE) and the Slope Limiter Centered (SLIC) methods to the two-dimensional governing equations without any loss of generality in the numerical solutions. An efficient assessment of both the mixture model and the numerical methods is carried out by simulating physical problems available in the literature. Simulations agree well with those in the literature and include new insights that could be used to explain the relative velocity observations. The favourable results suggest that the two-dimensional mixture model simulations can be employed for practical engineering problems of the non-equilibrium type.

Published
2019

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