Mr. Pramod.N

PG Scholar, Department of computer science and Engineering, Maharaja Institute of Technology (MIT), Mysore, Karnataka, India

     Prof. Honnaraju.B

Assistant professor, Department of computer Science and Engineering, Maharaja Institute of Technology (MIT), Mysore, Karnataka, India

ABSTRACT:

Outlier detection in high-dimensional data presents various challenges resulting from the “curse of dimensionality.” A prevailing view is that distance concentration, i.e., the tendency of distances in high-dimensional data to become indiscernible, hinders the detection of outliers by making distance-based methods label all points as almost equally good outliers. In this paper, we provide evidence supporting the opinion that such a view is too simple, by demonstrating that distance-based methods can produce more contrasting outlier scores in high-dimensional settings. Furthermore, we show that high dimensionality can have a different impact, by reexamining the notion of reverse nearest neighbors in the unsupervised outlier-detection context. Namely, it was recently observed that the distribution of points’ reverse-neighbor counts becomes skewed in high dimensions, resulting in the phenomenon known as hubness. We provide insight into how some points (antihubs) appear very infrequently in k-NN lists of other points, and explain the connection between antihubs, outliers, and existing unsupervised outlier-detection methods. By evaluating the classic k-NN method, the angle-based technique designed for high-dimensional data, the density-based local outlier factor and influenced outlierness methods, and anti hub-based methods on various synthetic and real-world data sets, we offer novel insight into the usefulness of reverse neighbor counts in unsupervised outlier detection.

Pravana S

M-tech Student Scholar

Department of Electrical & Electronics Engineering,

Anurag College of Engineering , Aushapur;

Ranga Reddy (Dt); Telangana, India.

Gujjari Chandra

 Assistant Professor

Department of Electrical & Electronics Engineering,

Anurag College of Engineering , Aushapur;

Ranga Reddy (Dt); Telangana, India.

 

 

Abstract – In this project, an asymmetrical duty cycle control strategy was proposed to the TPTL dc/dc converter. The modified converter remains all the advantages of original control strategy; meanwhile, soft-switching can be achieved using the energy stored in output filter inductance and leakage inductances of transformers (or resonant inductances).Three-phase three-level (TPTL) dc/dc converter has the advantages of lower voltage and current stress on switches, which is suitable for high power and high input voltage applications. Adopting a symmetrical control strategy, the ripple frequency of input and output current can be increased significantly, resulting in a reduced filter requirement. However, all the switches are hard-switching, leading to a considerable switching loss. Full-bridge dc/dc converters have been used widely in the medium-to-high-power applications for the pulse width = modulation (PWM) control, soft-switching characteristics, and lower power rating on switches. To further reduce the current stress on switches for higher power level requirements, a prominent three-phase full-bridge topologies was first put forward by Ziogas for medium-voltage-level applications [1], in which three-phase bridges consisting of six switches and a three-phase transformer are adopted. With the three-phase architecture, the converters has the superior features, including lower current rating of switches, reduced input and output current ripple allowing small size filter requirement and better utilization of transformer core. The improved resonant converter features zero-voltage-switching (ZVS) realization under wide load range and higher conversion efficiency. However, wide variation in switching frequency should be concerned in the applications with wide input/output voltage range. Other alternative solutions are the non resonant soft-switching three-phase converters. in order to obtain ZVS commutation for all switches and control the output voltage, Nevertheless, the upper and lower commutation cell switches are subjected to different current stresses) is improved by using MAT Lab/Simulink. The proposed concept can be implemented with five levels the proposed concept can be implemented for speed control of BLDC motor using Matlab/Simulink software

Index Terms—Asymmetrical duty cycle control, dc/dc converter, three-level, three-phase, zero-voltage switching.

ISMAIL SHAIK

M-Tech Student Scholar

Department of Electrical & Electronics Engineering,

Sri Mittapalli Engineering College, Tummalapalem;

Guntur (Dt); Andhra Pradesh, India.

Mail id :Ismail05227@gmail.com

SURESH MIKKILI

Associate Professor

Department of Electrical & Electronics Engineering,

Sri Mittapalli Engineering College, Tummalapalem;

Guntur (Dt); Andhra Pradesh, India.

 

Abstract-. This paper deals with the solutions for developing the direct coupled electric drive to be used in combination with a radial turbo-expander for exhaust energy recovery in automotive applications. The descriptions of project realization of both the axial-flux permanent-magnet (PM) generator and the three-level boost-rectifier converter, which results as the preferred topology for the controlled rectifier, are given. The high rotational speed of the direct-driven PM generator results in high electric fundamental frequency also, which is challenging for the electric drive control issues.the proposed concept can be implemented for multilevel inverter fed high speed electric drive applications by using Matlab/Simulation software and the results are verified.

 

Keywords: Multilevel inverters, Power electronic converters, Axial flux permanent magnet (AFPM), Pulse width modulation