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[Keyword] moments(70hit)

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  • Numerical Derivation of Design Guidelines for Tightness and Shaking Amplitude of Vibrating Intrinsic Reverberation Chamber by Method of Moment

    Makoto HARA  Jianqing WANG  Frank LEFERINK  

     
    PAPER-Electromagnetic Compatibility(EMC)

      Pubricized:
    2023/06/02
      Vol:
    E106-B No:11
      Page(s):
    1173-1181

    Vibrating intrinsic reverberation chamber is being used as an in-situ EMC test equipment for large and complex systems such as automobiles and aircrafts. In this paper, the stirring conditions, such as tightness and shaking amplitude of the walls, of a vibrating intrinsic reverberation chamber have been analyzed using the method of moments. From the viewpoint of quantitative evaluation of the flexible moving walls configuration, it was found that the random electromagnetic environment can be generated under the stirring conditions of loose configuration and a shaking amplitude more than one eighth of the wavelength at the test frequency above the lowest usable frequency.

  • Volume Integral Equations Combined with Orthogonality of Modes for Analysis of Two-Dimensional Optical Slab Waveguide

    Masahiro TANAKA  

     
    PAPER

      Pubricized:
    2021/10/18
      Vol:
    E105-C No:4
      Page(s):
    137-145

    Volume integral equations combined with orthogonality of guided mode and non-guided field are proposed for the TE incidence of two-dimensional optical slab waveguide. The slab waveguide is assumed to satisfy the single mode condition. The formulation of the integral equations are described in detail. The matrix equation obtained by applying the method of moments to the integral equations is shown. Numerical results for step, gap, and grating waveguides are given. They are compared to published papers to validate the proposed method.

  • Circuit Modeling of Wireless Power Transfer System in the Vicinity of Perfectly Conducting Scatterer

    Nozomi HAGA  Jerdvisanop CHAKAROTHAI  Keisuke KONNO  

     
    PAPER-Antennas and Propagation

      Pubricized:
    2020/06/22
      Vol:
    E103-B No:12
      Page(s):
    1411-1420

    The impedance expansion method (IEM) is a circuit-modeling technique for electrically small devices based on the method of moments. In a previous study, a circuit model of a wireless power transfer (WPT) system was developed by utilizing the IEM and eigenmode analysis. However, this technique assumes that all the coupling elements (e.g., feeding loops and resonant coils) are in the absence of neighboring scatters (e.g., bodies of vehicles). This study extends the theory of the IEM to obtain the circuit model of a WPT system in the vicinity of a perfectly conducting scatterer (PCS). The numerical results show that the proposed method can be applied to the frequencies at which the dimension of the PCS is less than approximately a quarter wavelength. In addition, the yielded circuit model is found to be valid at the operating frequency band.

  • Method of Moments Based on Electric Field Integral Equation for Three-Dimensional Metallic Waveguide: Single Mode Waveguide

    Masahiro TANAKA  Kazuo TANAKA  

     
    PAPER

      Vol:
    E102-C No:1
      Page(s):
    30-37

    This paper presents the method of moments based on electric field integral equation which is capable of solving three-dimensional metallic waveguide problem with no use of another method. Metals are treated as perfectly electric conductor. The integral equation is derived in detail. In order to validate the proposed method, the numerical results are compared with those in a published paper. Three types of waveguide are considered: step discontinuity waveguide, symmetrical resonant iris waveguide, and unsymmetrical resonant iris waveguide. The numerical results are also verified by the law of conservation of energy.

  • Analysis of a Wireless Power Transfer System by the Impedance Expansion Method Using Fourier Basis Functions

    Nozomi HAGA  Masaharu TAKAHASHI  

     
    PAPER-Antennas and Propagation

      Pubricized:
    2018/01/18
      Vol:
    E101-B No:7
      Page(s):
    1708-1715

    The impedance expansion method (IEM), which has been previously proposed by the authors, is a circuit-modeling technique for electrically-very-small devices. This paper provides a new idea on the principle of undesired radiation in wireless power transfer systems by employing IEM. In particular, it is shown that the undesired radiation is due to equivalent infinitesimal dipoles and loops of the currents on the coils.

  • Passive Element Approximation of Equivalent Circuits by the Impedance Expansion Method

    Nozomi HAGA  Masaharu TAKAHASHI  

     
    PAPER-Antennas and Propagation

      Pubricized:
    2017/10/16
      Vol:
    E101-B No:4
      Page(s):
    1069-1075

    The impedance expansion method (IEM), which was previously proposed by the authors, is a circuit-modeling technique for electrically-very-small devices. The equivalent circuits derived by the IEM include dependent voltage sources proportional to the powers of the frequency. However, the previous report did not describe how circuit simulators could realize such dependent voltage sources. This paper shows how this can be achieved by approximating the equivalent circuit using only passive elements.

  • Circuit Modeling Technique for Electrically-Very-Small Devices Based on Laurent Series Expansion of Self-/Mutual Impedances

    Nozomi HAGA  Masaharu TAKAHASHI  

     
    PAPER-Antennas and Propagation

      Pubricized:
    2017/08/14
      Vol:
    E101-B No:2
      Page(s):
    555-563

    This paper proposes a circuit modeling technique for electrically-very-small devices, e.g. electrodes for intrabody communications, coils for wireless power transfer systems, high-frequency transformers, etc. The proposed technique is based on the method of moments and can be regarded as an improved version of the partial element equivalent circuit method.

  • Accuracy Improvement of Characteristic Basis Function Method by Using Multilevel Approach

    Tai TANAKA  Yoshio INASAWA  Naofumi YONEDA  Hiroaki MIYASHITA  

     
    PAPER-Electromagnetic Theory

      Vol:
    E101-C No:2
      Page(s):
    96-103

    A method is proposed for improving the accuracy of the characteristic basis function method (CBFM) using the multilevel approach. With this technique, CBFs taking into account multiple scattering calculated for each block (IP-CBFs; improved primary CBFs) are applied to CBFM using a multilevel approach. By using IP-CBFs, the interaction between blocks is taken into account, and thus it is possible to reduce the number of CBFs while maintaining accuracy, even if the multilevel approach is used. The radar cross section (RCS) of a cube, a cavity, and a dielectric sphere were analyzed using the proposed CBFs, and as a result it was found that accuracy is improved over the conventional method, despite no major change in the number of CBFs.

  • Radio Wave Shadowing by Two-Dimensional Human BodyModel

    Mitsuhiro YOKOTA  Yoshichika OHTA  Teruya FUJII  

     
    PAPER-Antennas and Propagation

      Pubricized:
    2017/07/06
      Vol:
    E101-B No:1
      Page(s):
    195-202

    The radio wave shadowing by a two-dimensional human body is examined numerically as the scattering problem by using the Method of Moments (MoM) in order to verify the equivalent human body diameter. Three human body models are examined: (1) a circular cylinder, (2) an elliptical cylinder, and (3) an elliptical cylinder with two circular cylinders are examined. The scattered fields yields by the circular cylinder are compared with measured data. Since the angle of the model to an incident wave affects scattered fields in models other than a circular cylinder, the models of an elliptical cylinder and an elliptical cylinder with two circular cylinders are converted into a circular cylinder of equivalent diameter. The frequency characteristics for the models are calculated by using the equivalent diameter.

  • Statistical Analysis of Phase-Only Correlation Functions between Real Signals with Stochastic Phase-Spectrum Differences

    Shunsuke YAMAKI  Masahide ABE  Masayuki KAWAMATA  

     
    PAPER-Digital Signal Processing

      Vol:
    E100-A No:5
      Page(s):
    1097-1108

    This paper proposes the statistical analysis of phase-only correlation functions between two real signals with phase-spectrum differences. For real signals, their phase-spectrum differences have odd-symmetry with respect to frequency indices. We assume phase-spectrum differences between two signals to be random variables. We next derive the expectation and variance of the POC functions considering the odd-symmetry of the phase-spectrum differences. As a result, the expectation and variance of the POC functions can be expressed by characteristic functions or trigonometric moments of the phase-spectrum differences. Furthermore, it is shown that the peak value of the POC function monotonically decreases and the sidelobe values monotonically increase as the variance of the phase-spectrum differences increases.

  • Improved Primary-Characteristic Basis Function Method Considering Higher-Order Multiple Scattering

    Tai TANAKA  Yoshio INASAWA  Yasuhiro NISHIOKA  Hiroaki MIYASHITA  

     
    PAPER

      Vol:
    E100-C No:1
      Page(s):
    45-51

    We propose a novel improved characteristic basis function method (IP-CBFM) for accurately analysing the radar cross section (RCS). This new IP-CBFM incorporates the effect of higher-order multiple scattering and has major influences in analyzing monostatic RCS (MRCS) of single incidence and bistatic RCS (BRCS) problems. We calculated the RCS of two scatterers and could confirm that the proposed IP-CBFM provided higher accuracy than the conventional method while significantly reducing the number of CBF.

  • Spectral Features Based on Local Normalized Center Moments for Speech Emotion Recognition

    Huawei TAO  Ruiyu LIANG  Xinran ZHANG  Li ZHAO  

     
    LETTER-Speech and Hearing

      Vol:
    E99-A No:10
      Page(s):
    1863-1866

    To discuss whether rotational invariance is the main role in spectrogram features, new spectral features based on local normalized center moments, denoted by LNCMSF, are proposed. The proposed LNCMSF firstly adopts 2nd order normalized center moments to describe local energy distribution of the logarithmic energy spectrum, then normalized center moment spectrograms NC1 and NC2 are gained. Secondly, DCT (Discrete Cosine Transform) is used to eliminate the correlation of NC1 and NC2, then high order cepstral coefficients TNC1 and TNC2 are obtained. Finally, LNCMSF is generated by combining NC1, NC2, TNC1 and TNC2. The rotational invariance test experiment shows that the rotational invariance is not a necessary property in partial spectrogram features. The recognition experiment shows that the maximum UA (Unweighted Average of Class-Wise Recall Rate) of LNCMSF are improved by at least 10.7% and 1.2% respectively, compared to that of MFCC (Mel Frequency Cepstrum Coefficient) and HuWSF (Weighted Spectral Features Based on Local Hu Moments).

  • Time-Domain Solver for 3D Electromagnetic Problems Using the Method of Moments and the Fast Inverse Laplace Transform

    Shinichiro OHNUKI  Yuya KITAOKA  Takashi TAKEUCHI  

     
    BRIEF PAPER

      Vol:
    E99-C No:7
      Page(s):
    797-800

    A novel computational method based on a combination of the method of moments in the complex frequency domain and the fast inverse Laplace transform is proposed for solving time-domain electromagnetic problems. Using our proposed method, it is easy to estimate and control the computational error, and the observation time can be selected independently. We investigate canonical scattering problems and verify these advantages.

  • Improved Primary Characteristic Basis Function Method for Monostatic Radar Cross Section Analysis of Specific Coordinate Plane

    Tai TANAKA  Yoshio INASAWA  Yasuhiro NISHIOKA  Hiroaki MIYASHITA  

     
    PAPER

      Vol:
    E99-C No:1
      Page(s):
    28-35

    The characteristic basis function method using improved primary characteristic basis functions (IP-CBFM) has been proposed as a technique for high-precision analysis of monostatic radar cross section (RCS) of a scattering field in a specific coordinate plane. IP-CBFM is a method which reduces the number of CBF necessary to express a current distribution by combining secondary CBF calculated for each block of the scatterer with the primary CBF to form a single improved primary CBF (IP-CBF). When the proposed technique was evaluated by calculating the monostatic RCS of a perfect electric conductor plate and cylinder, it was found that solutions corresponding well with analysis results from conventional CBFM can be obtained from small-scale matrix equations.

  • Quantification and Verification of Whole-Body-Average SARs in Small Animals Exposed to Electromagnetic Fields inside Reverberation Chamber

    Jingjing SHI  Jerdvisanop CHAKAROTHAI  Jianqing WANG  Kanako WAKE  Soichi WATANABE  Osamu FUJIWARA  

     
    PAPER-Electromagnetic Compatibility(EMC)

      Vol:
    E97-B No:10
      Page(s):
    2184-2191

    This paper aims to achieve a high-quality exposure level quantification of whole-body average-specific absorption rates (WBA-SARs) for small animals in a medium-size reverberation chamber (RC). A two-step method, which incorporates the finite-difference time-domain (FDTD) numerical solutions with electric field measurements in an RC-type exposure system, has been used as an evaluation method to determine the whole-body exposure level in small animals. However, there is little data that quantitatively demonstrate the validity and accuracy of this method in an RC up to now. In order to clarify the validity of the two-step method, we compare the physical quantities in terms of electric field strength and WBA-SARs by using a direct numerical assessment method known as the method of moments (MoM) with ten homogenous gel phantoms placed in an RC with 2GHz exposure. The comparison results show that the relative errors between the two-step method and the MoM approach are approximately below 10%, which reveals the validity and usefulness of the two-step technique. Finally, we perform a dosimetric analysis of the WBA-SARs for anatomical mouse models with the two-step method and determine the input power related to our developed RC-exposure system to achieve a target exposure level in small animals.

  • Numerical Simulation of Far-Field Gain Determination at Reduced Distances Using Phase Center Open Access

    Katsushige HARIMA  

     
    INVITED PAPER

      Vol:
    E97-B No:10
      Page(s):
    2001-2010

    This paper describes numerical analyses of the distance-dependent gain variation that exists in gain measurements based on the Friis transmission formula for typical broadband antennas, including double-ridged guide horn and log-periodic dipole array antennas. The analyses are performed by simulating gain measurements using the method of moments with higher-order basis functions and the finite integration method. In addition, we propose approximate techniques to determine the antenna phase center by exploiting the distance dependence of the gain. Simulation and experimental results show the effectiveness of using the location of the phase center to accurately determine the far-field gain at reduced antenna separation distances.

  • The Numerical Analysis of an Antenna near a Dielectric Object Using the Higher-Order Characteristic Basis Function Method Combined with a Volume Integral Equation

    Keisuke KONNO  Qiang CHEN  

     
    PAPER

      Vol:
    E97-B No:10
      Page(s):
    2066-2073

    The higher-order characteristic basis function method (HO-CBFM) is clearly formulated. HO-CBFM provides results accurately even if a block division is arbitrary. The HO-CBFM combined with a volume integral equation (VIE) is used in the analysis of various antennas in the vicinity of a dielectric object. The results of the numerical analysis show that the HO-CBFM can reduce the CPU time while still achieving the desired accuracy.

  • Boundary Integral Equation Analysis of Spoof Localized Surface Plasmons Excited in a Perfectly Conducting Cylinder with Longitudinal Corrugations

    Kazuhiro FUJITA  

     
    BRIEF PAPER

      Vol:
    E97-C No:7
      Page(s):
    710-713

    The main purpose of this paper is to apply the boundary integral equation (BIE) method to the analysis of spoof localized surface plasmons (spoof LSPs) excited in a perfectly conducting cylinder with longitudinal corrugations. Frequency domain BIE schemes based on electric field integral equation (EFIE), magnetic field integral equation (MFIE) and combined field integral equation (CFIE) formulations are used to solve two-dimensional electromagnetic (EM) problems of scattering from the cylinder illuminated by a transverse electric plane wave. In this approach effects of spoof LSPs are included in the secondary surface current and charge densities resulting from the interaction between the plane wave and the cylinder. Numerical results obtained with the BIE schemes are validated by comparison with that of a recently proposed modal solution based on the metamaterial approximation.

  • Parallel Computation of Complex Antennas around the Coated Object Using Iterative Vector Fields Technique

    Ying YAN  Xunwang ZHAO  Yu ZHANG  Changhong LIANG  Zhewang MA  

     
    PAPER

      Vol:
    E97-C No:7
      Page(s):
    661-669

    In this paper, a novel hybrid technique for analyzing complex antennas around the coated object is proposed, which is termed as “iterative vector fields with Physical Optics (PO)”. A closed box is used to enclose the antennas and the complex field vectors on the box' surfaces can then be obtained using Huygens principle. The equivalent electromagnetic currents on Huygens surfaces are computed by Higher-order Method of Moments (HOB-MoM) and the fields scattered from the coated object are calculated by PO method. In addition, the parallel technique based on Message Passing Interface (MPI) and Scalable Linear Algebra Package (ScaLAPACK) is employed so as to accelerate the computation. Numerical examples are presented to validate and to show the effectiveness of the proposed method on solving the practical engineering problem.

  • Voice Activity Detection Based on Generalized Normal-Laplace Distribution Incorporating Conditional MAP

    Ji-Hyun SONG  Sangmin LEE  

     
    LETTER-Speech and Hearing

      Vol:
    E96-D No:12
      Page(s):
    2888-2891

    In this paper, we propose a novel voice activity detection (VAD) algorithm based on the generalized normal-Laplace (GNL) distribution to provide enhanced performance in adverse noise environments. Specifically, the probability density function (PDF) of a noisy speech signal is represented by the GNL distribution; the variance of the speech and noise of the GNL distribution are estimated using higher-order moments. After in-depth analysis of estimated variances, a feature that is useful for discrimination between speech and noise at low SNRs is derived and compared to a threshold to detect speech activity. To consider the inter-frame correlation of speech activity, the result from the previous frame is employed in the decision rule of the proposed VAD algorithm. The performance of our proposed VAD algorithm is evaluated in terms of receiver operating characteristics (ROC) and detection accuracy. Results show that the proposed method yields better results than conventional VAD algorithms.

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