Two Methods to Discretize the Wave Equation in Time and Space

被引:0
作者
Suzuki, Tomoyu [1 ]
Tokutomi, Yuichi [1 ]
Hori, Noriyuki [1 ]
Nguyen-Van, Triet [2 ]
Kawai, Shin [1 ]
机构
[1] Univ Tsukuba, Intelligent & Mech Interact Syst, 1-1-1 Tennoudai, Tsukuba, Ibaraki 3058573, Japan
[2] Oyama Coll, Natl Inst Technol, 771 Nakakuki, Oyama, Tochigi 3230806, Japan
来源
2022 10TH INTERNATIONAL CONFERENCE ON CONTROL, MECHATRONICS AND AUTOMATION (ICCMA 2022) | 2022年
关键词
exact-discretization-method; wave equation; digital control; variable separation; d'Alembert solution; discrete model; MODELS;
D O I
10.1109/ICCMA56665.2022.10011619
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
This study proposes two methods to derive exact discrete-time and space models for the wave equation as an example of a hyperbolic linear partial differential equation. The first method is based on the separation of variables method, an extension of the previous studies, and discretizes time and space separately. This method can accurately discretize when the initial conditions are expressed as a sum of sinusoidal functions. The second method is based on d'Alembert's method, which can be used strictly with arbitrary initial conditions, and discretizes time and space simultaneously. However, this method requires that the space be one-dimensional. Both models can be computed online, and their use is expected to have applications in control system design.
引用
收藏
页码:148 / 153
页数:6
相关论文
共 50 条
[21]   On a stochastic wave equation in two space dimensions: regularity of the solution and its density [J].
Millet, A ;
Morien, PL .
STOCHASTIC PROCESSES AND THEIR APPLICATIONS, 2000, 86 (01) :141-162
[22]   General energy decay for wave equation with space-time potential and time delay in Rn [J].
Ogbiyele, Paul A. ;
Arawomo, Peter O. .
AFRIKA MATEMATIKA, 2023, 34 (04)
[23]   A Space-Time Interior Penalty Discontinuous Galerkin Method for the Wave Equation [J].
Poorvi Shukla ;
J. J. W. van der Vegt .
Communications on Applied Mathematics and Computation, 2022, 4 :904-944
[24]   Existence of time-dependent attractor of wave equation in locally uniform space [J].
Luo, Xudong ;
Ma, Qiaozhen .
MATHEMATICS AND MECHANICS OF SOLIDS, 2024, 29 (05) :944-958
[25]   An unconditionally stable space-time isogeometric method for the acoustic wave equation [J].
Fraschini, S. ;
Loli, G. ;
Moiola, A. ;
Sangalli, G. .
COMPUTERS & MATHEMATICS WITH APPLICATIONS, 2024, 169 :205-222
[26]   A Space-Time Interior Penalty Discontinuous Galerkin Method for the Wave Equation [J].
Shukla, Poorvi ;
van der Vegt, J. J. W. .
COMMUNICATIONS ON APPLIED MATHEMATICS AND COMPUTATION, 2022, 4 (03) :904-944
[27]   SPACE-TIME PROPAGATOR AND EXACT SOLUTION FOR WAVE EQUATION IN A LAYERED SYSTEM [J].
Los, Victor F. ;
Los, Nicholas, V .
REPORTS ON MATHEMATICAL PHYSICS, 2021, 88 (01) :1-19
[28]   A hardware acceleration of the time domain boundary integral equation method for the wave equation in two dimensions [J].
Takahashi, Toru ;
Ebisuzaki, Toshikazu ;
Koketsu, Kazuki .
ENGINEERING ANALYSIS WITH BOUNDARY ELEMENTS, 2007, 31 (02) :95-102
[29]   Hybrid High-Order Methods for the Acoustic Wave Equation in the Time Domain [J].
Burman, Erik ;
Duran, Omar ;
Ern, Alexandre .
COMMUNICATIONS ON APPLIED MATHEMATICS AND COMPUTATION, 2022, 4 (02) :597-633
[30]   Hybrid High-Order Methods for the Acoustic Wave Equation in the Time Domain [J].
Erik Burman ;
Omar Duran ;
Alexandre Ern .
Communications on Applied Mathematics and Computation, 2022, 4 :597-633
12345