TWO EFFICIENT UNCONDITIONALLY-STABLE FOUR-STAGES SPLIT-STEP FDTD METHODS WITH LOW NUMERICAL DISPERSION

The leapfrog schemes have been developed for unconditionally stable alternating-direction implicit (ADI) finite-difference time-domain (FDTD) method, and recently the complying-divergence implicit (CDI) FDTD method. In this paper, the formulations from time-collocated to leapfrog fundamental schemes are presented for ADI and CDI FDTD methods. For the ADI FDTD method, the time-collocated fundamental schemes are implemented using implicit E-E and E-H update procedures, which comprise simple and concise right-hand sides (RHS) in their update equations. From the fundamental implicit E-H scheme, the leapfrog ADI FDTD method is formulated in conventional form, whose RHS are simplified into the leapfrog fundamental scheme with reduced operations and improved efficiency. For the CDI FDTD method, the time-collocated fundamental scheme is presented based on locally one-dimensional (LOD) FDTD method with complying divergence. The formulations from time-collocated to leapfrog schemes are provided, which result in the leapfrog fundamental scheme for CDI FDTD method. Based on their fundamental forms, further insights are given into the relations of leapfrog fundamental schemes for ADI and CDI FDTD methods. The time-collocated fundamental schemes require considerably fewer operations than all conventional ADI, LOD and leapfrog ADI FDTD methods, while the leapfrog fundamental schemes for ADI and CDI FDTD methods constitute the most efficient implicit FDTD schemes to date.

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A New Unconditionally Stable Time Integration Method for Analysis of Nonlinear Structural Dynamics

Journal of Applied Mechanics ◽

10.1115/1.4007682 ◽

2013 ◽

Vol 80 (2) ◽

Cited By ~ 6

Author(s):

Ali Akbar Gholampour ◽

Mehdi Ghassemieh ◽

Mahdi Karimi-Rad

Keyword(s):

Time Integration ◽

Second Order ◽

Numerical Dispersion ◽

Computational Time ◽

Numerical Dissipation ◽

Integration Scheme ◽

Time Step ◽

Similar Time ◽

Unconditionally Stable ◽

Average Acceleration

A new time integration scheme is presented for solving the differential equation of motion with nonlinear stiffness. In this new implicit method, it is assumed that the acceleration varies quadratically within each time step. By increasing the order of acceleration, more terms of the Taylor series are used, which are expected to have responses with better accuracy than the classical methods. By considering this assumption and employing two parameters δ and α, a new family of unconditionally stable schemes is obtained. The order of accuracy, numerical dissipation, and numerical dispersion are used to measure the accuracy of the proposed method. Second order accuracy is achieved for all values of δ and α. The proposed method presents less dissipation at the lower modes in comparison with Newmark's average acceleration, Wilson-θ, and generalized-α methods. Moreover, this second order accurate method can control numerical damping in the higher modes. The numerical dispersion of the proposed method is compared with three unconditionally stable methods, namely, Newmark's average acceleration, Wilson-θ, and generalized-α methods. Furthermore, the overshooting effect of the proposed method is compared with these methods. By evaluating the computational time for analysis with similar time step duration, the proposed method is shown to be faster in comparison with the other methods.

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Fast Modeling of Terahertz Plasma-Wave Devices Using Unconditionally Stable FDTD Methods

IEEE Journal on Multiscale and Multiphysics Computational Techniques ◽

10.1109/jmmct.2018.2825427 ◽

2018 ◽

Vol 3 ◽

pp. 29-36 ◽

Cited By ~ 1

Author(s):

Shubhendu Bhardwaj ◽

Fernando L. Teixeira ◽

John L. Volakis

Keyword(s):

Plasma Wave ◽

Unconditionally Stable ◽

Fdtd Methods

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A Compact Unconditionally Stable Method for Time-Domain Maxwell's Equations

International Journal of Antennas and Propagation ◽

10.1155/2013/689327 ◽

2013 ◽

Vol 2013 ◽

pp. 1-7

Author(s):

Zhuo Su ◽

Yongqin Yang ◽

Yunliang Long

Keyword(s):

Time Domain ◽

Finite Difference Time Domain ◽

Symmetric Operator ◽

Numerical Dispersion ◽

Stable Method ◽

Unconditionally Stable ◽

Electromagnetic Problems ◽

Performance Analyses ◽

Computational Expenditure ◽

Difference Time

Higher order unconditionally stable methods are effective ways for simulating field behaviors of electromagnetic problems since they are free of Courant-Friedrich-Levy conditions. The development of accurate schemes with less computational expenditure is desirable. A compact fourth-order split-step unconditionally-stable finite-difference time-domain method (C4OSS-FDTD) is proposed in this paper. This method is based on a four-step splitting form in time which is constructed by symmetric operator and uniform splitting. The introduction of spatial compact operator can further improve its performance. Analyses of stability and numerical dispersion are carried out. Compared with noncompact counterpart, the proposed method has reduced computational expenditure while keeping the same level of accuracy. Comparisons with other compact unconditionally-stable methods are provided. Numerical dispersion and anisotropy errors are shown to be lower than those of previous compact unconditionally-stable methods.

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