Transfer matrix study of the Anderson transition in non-Hermitian systems

This paper presents a technique by which the transfer matrix in explicit form of an orthotropic layer can be easily obtained. This transfer matrix is applicable for both the wave propagation problem and the reflection/transmission problem. The obtained transfer matrix is then employed to derive the explicit secular equation of Rayleigh waves propagating in an orthotropic half-space coated by an orthotropic layer of arbitrary thickness.

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Proper, Stable Transfer Matrix Factorizations and Internal System Descriptions

10.23919/acc.1986.4789011 ◽

1986 ◽

Author(s):

P. J. Antsaklis

Keyword(s):

Transfer Matrix ◽

Matrix Factorizations ◽

Internal System

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Effect of leakage and blockage on the acoustic behavior of particle filters

Noise Control Engineering Journal ◽

10.3397/1/376744 ◽

2019 ◽

Vol 67 (6) ◽

pp. 483-492

Author(s):

Seonghyeon Baek ◽

Iljae Lee

Keyword(s):

Transfer Matrix ◽

Particle Filters ◽

Acoustic Analysis ◽

Transmission Loss ◽

One Dimensional ◽

Filter System ◽

The Difference ◽

The One ◽

Analytical Approaches ◽

Good Agreement

The effects of leakage and blockage on the acoustic performance of particle filters have been examined by using one-dimensional acoustic analysis and experimental methods. First, the transfer matrix of a filter system connected to inlet and outlet pipes with conical sections is measured using a two-load method. Then, the transfer matrix of a particle filter only is extracted from the experiments by applying inverse matrices of the conical sections. In the analytical approaches, the one-dimensional acoustic model for the leakage between the filter and the housing is developed. The predicted transmission loss shows a good agreement with the experimental results. Compared to the baseline, the leakage between the filter and housing increases transmission loss at a certain frequency and its harmonics. In addition, the transmission loss for the system with a partially blocked filter is measured. The blockage of the filter also increases the transmission loss at higher frequencies. For the simplicity of experiments to identify the leakage and blockage, the reflection coefficients at the inlet of the filter system have been measured using two different downstream conditions: open pipe and highly absorptive terminations. The experiments show that with highly absorptive terminations, it is easier to see the difference between the baseline and the defects.

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Comparisons of regularization methods and regularization parameter selection methods in sound source identification using inverse boundary element method

Noise Control Engineering Journal ◽

10.3397/1/376720 ◽

2019 ◽

Vol 67 (3) ◽

pp. 219-227

Author(s):

Youhong Xiao ◽

Qingqing Song ◽

Shaowei Li ◽

Guoxue Lv ◽

Zhenlin Ji

Keyword(s):

Boundary Element Method ◽

Boundary Element ◽

Transfer Matrix ◽

Sound Source ◽

Source Identification ◽

Regularization Parameter ◽

Vibration Velocity ◽

Regularization Methods ◽

Inverse Boundary ◽

Element Method

In noise source identification based on the inverse boundary element method (IBEM), the boundary vibration velocity is predicted based on the field pressure through a transfer matrix of the vibration velocity and field pressure established on the Helmholtz integral equation. Because the matrix is often ill-posed, it needs to be regularized before reconstructing the vibration velocity. Two regularization methods and two methods of selecting the regularization parameter are investigated through the simulation analysis of a pulsating sphere. The result of transfer matrix regularization is further verified through the reconstruction of the vibration of an aluminum plate. Additionally, to reduce the large errors at some frequencies in the reconstruction result, increasing the number of measuring points is more effective than reducing the distance between the measurement plane and the sound source.

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Generalized Transfer-Matrix Description of the Optical Properties of Spatially Dispersive Periodic Metal Multilayers

physica status solidi (b) ◽

10.1002/pssb.2221510143 ◽

1989 ◽

Vol 151 (1) ◽

pp. 383-397 ◽

Cited By ~ 3

Author(s):

U. Trutschel ◽

M. Golz ◽

M. Abraham

Keyword(s):

Optical Properties ◽

Transfer Matrix ◽

Matrix Description ◽

Spatially Dispersive

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Free fermions, vertex Hamiltonians, and lower-dimensional AdS/CFT

Journal of High Energy Physics ◽

10.1007/jhep02(2021)191 ◽

2021 ◽

Vol 2021 (2) ◽

Author(s):

Marius de Leeuw ◽

Chiara Paletta ◽

Anton Pribytok ◽

Ana L. Retore ◽

Alessandro Torrielli

Keyword(s):

Spectral Problem ◽

Transfer Matrix ◽

Arbitrary Number ◽

Free Fermion ◽

Nearest Neighbour ◽

Bogoliubov Transformation ◽

Free Fermions ◽

New Models ◽

Lower Dimensional

Abstract In this paper we first demonstrate explicitly that the new models of integrable nearest-neighbour Hamiltonians recently introduced in PRL 125 (2020) 031604 [36] satisfy the so-called free fermion condition. This both implies that all these models are amenable to reformulations as free fermion theories, and establishes the universality of this condition. We explicitly recast the transfer matrix in free fermion form for arbitrary number of sites in the 6-vertex sector, and on two sites in the 8-vertex sector, using a Bogoliubov transformation. We then put this observation to use in lower-dimensional instances of AdS/CFT integrable R-matrices, specifically pure Ramond-Ramond massless and massive AdS3, mixed-flux relativistic AdS3 and massless AdS2. We also attack the class of models akin to AdS5 with our free fermion machinery. In all cases we use the free fermion realisation to greatly simplify and reinterpret a wealth of known results, and to provide a very suggestive reformulation of the spectral problem in all these situations.

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The prediction of vehicle vibration transmitted to the occupant using a modular transfer matrix

Journal of Vibration and Control ◽

10.1177/1077546321997593 ◽

2021 ◽

pp. 107754632199759

Author(s):

Jianchun Yao ◽

Mohammad Fard ◽

John L Davy ◽

Kazuhito Kato

Keyword(s):

Finite Element ◽

Transfer Matrix ◽

Dynamic Performance ◽

Complex Structure ◽

Vehicle Body ◽

Computational Time ◽

Accurate Estimation ◽

Finite Element Models ◽

Transfer Matrices ◽

Body Vibration

Industry is moving towards more data-oriented design and analyses to solve complex analytical problems. Solving complex and large finite element models is still challenging and requires high computational time and resources. Here, a modular method is presented to predict the transmission of vehicle body vibration to the occupants’ body by combining the numerical transfer matrices of the subsystems. The transfer matrices of the subsystems are presented in the form of data which is sourced from either physical tests or finite element models. The structural dynamics of the vehicle body is represented using a transfer matrix at each of the seat mounting points in three triaxial (X–Y–Z) orientations. The proposed method provides an accurate estimation of the transmission of the vehicle body vibration to the seat frame and the seated occupant. This method allows the combination of conventional finite element analytical model data and the experimental data of subsystems to accurately predict the dynamic performance of the complex structure. The numerical transfer matrices can also be the subject of machine learning for various applications such as for the prediction of the vibration discomfort of the occupant with different seat and foam designs and with different physical characteristics of the occupant body.

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