Speaker: Lior Fritz,

M.Sc. student under the supervision of Prof. David Burshtein

Wednesday, November 22^nd, 2017 at 15:00

Room 011, Kitot Bldg., Faculty of Engineering

Simplified End-to-End MMI Training and Voting for ASR

Abstract

A simplified speech recognition system that uses the maximum mutual information (MMI) criterion is considered. End-to-end training using gradient descent is suggested, similarly to the training of connectionist temporal classification (CTC). We use an MMI criterion with a simple language model in the training stage, and a standard HMM decoder. Our method compares favorably to CTC in terms of performance, robustness, decoding time, disk footprint and quality of alignments. The good alignments enable the use of a straightforward ensemble method, obtained by simply averaging the predictions of several neural network models, that were trained separately end-to-end. The ensemble method yields a considerable reduction in the word error rate.

School of Mechanical Engineering Seminar
Wednesday, December 27, 2017 at 14:00
Wolfson Building of Mechanical Engineering, Room 206

Hydroelastic waves and their interaction with structures

Prof. Alexander Korobkin

(University of East Anglia, UK)

Co-author: S. Malenica (BV), T. Khabakhpasheva (Lavrentyev Institute of Hydrodynamics)

Linear problems of hydroelastic wave diffraction by structures with vertical walls are studied for a circular cylinder frozen in ice cover of constant thickness and infinite extent. The water depth is constant. The ice plate is modelled by a thin elastic plate clamped to the surface of the cylinder. The cylinder is mounted at the sea bottom. One-dimensional incident hydroelastic wave of small amplitude propagates towards the cylinder and is diffracted on the cylinder.  Deflection of the ice plate and the bending stresses in it are determined by two methods: (a) using the integral Weber transform in radial direction, (b) using the vertical modes for the fluid of constant depth with the rigid bottom and elastic upper boundary. The solution by the second method is straightforward but we cannot prove that the solution is complete because the properties of the vertical modes are not known. The solution by the Weber transform is more complicated but this solution is unique. We will show that these two solutions are identical. This result justifies the method of the vertical modes in the hydroelastic wave diffraction problems. For a circular cylinder the vertical-mode solution can be also justified by substitution. Different conditions at the contact line between the cylinder and the ice sheet are considered. The wave diffraction problem for broken ice is also considered. It is shown how the problem can be generalised to non-circular cylinders and interaction of several cylinders in ice.

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School of Mechanical Engineering Seminar
Monday, November 27, 2017 at 14:00
Wolfson Building of Mechanical Engineering, Room 206

An afternoon talk on femurs, arteries and high order finite element methods

Prof. Zohar Yosibash

School of Mechanical Engineering, Tel Aviv University

Predicting the mechanical response of human femurs and arteries is of major clinical importanceare for diagnostic purposes as well as for patient-specific treatment. Such prediction capabilities are being described which involve the combination of high order finite element (FE) methods, medical imaging and experimental observations.

Our research on human femurs will first be addressed, where we use quantitative computerized tomography (qCT scans) that enables a computer realization of subject-specific bone models. Combining qCT scans with high order FE simulations and a large set of experiments provide the opportunity to accurately simulate patient-specific femur’s response, allowing orthopedic surgeons to plan a proper patient specific treatment. Examples of the use of our methods in clinical practice for treatment of metastatic bone tumors will be provided.

If time allows, experimental and numerical methods for the analysis of human arteries will be addressed. Arteries are complex anisotropic structures undergoing large deformations and strains and are subject to active response due to contraction of smooth muscle cells. Attempts to properly describe their response will be described.

About the Lecturer

Prof. Yosibash received his B.Sc. in Aeronautical Engineering from the Technion (87), his M.Sc. in Applied Mathematics from Tel-Aviv Unviersity (92) and D.Sc. in Mechanical Engineering from Washington University, St. Louis, USA (94). He joined Ben-Gurion University in 1995 and since 2008 he is a full professor of mechanical engineering. He has been a visiting professor at Brown Univ from 2002-2007, and at the Technical Univ of Munich during 2010-2011. He received the Toronto prize for excellence in research at BGU in 2009. Prof. Yosibash was a Hans Fischer Senior Fellow at the Institute for Advanced Study at the Technical University of Munich (2009-2012) and serves as the scientific ambassador since 2013.  Prof. Yosibash joined the School of Mechanical Engineering at TAU in Oct 2017. He is the head of the lab for computational mechanics and experimental biomechanics at TAU and since 2015 serves as the president of the Israel Association for Computational Methods in Mechanics.

You are invited to attend a lecture

Higher Order Modulation Backscatter Combined with WPT as a Solution for IoT Development

:By

Nuno Borges Carvalho

Professor Catedrático, Dep. Electronica, Telecomunicacoes e Informatica

Instituto de Telecomunicacoes, Universidade de Aveiro

Aveiro,  Portugal

Abstract

The Internet-of-Things (IoT) vision calls for thousands interconnected devices in wearables, vehicles, buildings, using a multitude of sensors to provide us with useful information.

Backscatter communication provides an enabling technology to address the needs of IoT, due to the simplicity of the tag circuit and the ability to minimize the usage of batteries or even completely eliminate them taking advantage of wireless power transmission as well as energy harvesting. This talk presents the latest advances in backscatter communication technology, covering a wide range of topics, focusing on the combination of modulation constellation diagrams with the Smith chart.

On Thursday, November 16, 2017, 15:00

Room 011, Kitot building