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Cesar Sciammarella | |
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Born | |
Alma mater | University of Buenos Aires Illinois Institute of Technology |
Occupation | Scientist |
Known for | Experimental Mechanics Holographic interferometry Moire deflectometry |
Title | Emeritus Professor, Department of Mechanical, Materials and Aerospace Engineering Illinois Institute of Technology |
Spouse | Esther Sciammarella |
Children | Eduardo Sciammarella Federico Sciammarella |
Website | General Stress Optics |
Cesar Augusto Sciammarella (born August 22, 1924) is an Argentine civil engineer who made significant contributions to the field of experimental mechanics.[1] In the last decade, he has extended his pioneering developments in moiré,[2] holography, and speckle interferometry[3] methodologies down to the nanometer level.[4] These efforts have enabled optics to be applied beyond the classical Rayleigh limit, reaching the nanometer range.
His research is widely used for 3D reconstruction and stress and strain analysis. In his Doctoral Thesis on the moiré method, he extended the Continuum Mechanics model originally developed by Dantu to large deformations. He developed fundamental equations on the properties of moiré fringes and sign conventions. This was an analysis of a non-elastic problem with the moiré method. Dr Sciammarella generalised the methods that measure displacements using Fourier analysis in the process of formation of the fringe images. He proved formally that the orders could be represented by real numbers instead of integers.[5] In 1966, he presented a full model of the moiré fringes as phase modulated signals and provided a method to get displacements and strains for moiré and photo-elastic fringes. He introduced in the literature the Fourier method as a tool for fringe pattern analysis. His model is still used as a standard model in the fringe analysis method.[6]
Cesar Sciammarella received his diploma in Civil Engineering from the University of Buenos Aires in July 1950. After graduation, he worked as a professional engineer in different industries, including the Director of the Materials Testing Laboratories in the Metallurgy and Materials Division of the Atomic Energy Commission of Argentina. Later, he was invited by Dr A.J. Durelli to come to the US to get a PhD degree. He received his PhD from the Illinois Institute of Technology in June 1960. Upon graduation, he returned to the Argentine Atomic Energy Commission.
From 1952–57, Cesar was Professor of Physics at Argentine Army Engineering School. This was a period in Argentina under the democratically-elected Juan Domingo Perón. The coup that brought down Perón's difficult republic was aided by officers from Argentine Army Engineering School. Although Cesar was not involved in the coup, he was detained and tortured during the uprising. Peron's government fell two weeks after his detention and he was able to escape. He spent several months fighting pneumonia caused by his detention.
Since 1962, he worked as an Associate professor at the University of Florida, Gainesville, where he researched the moiré method and the Fourier method to analyze the contours and deformations of bodies. In 1967, he became professor at the Department of Aerospace and Applied Mechanics, Polytechnic Institute of Brooklyn. During this period, Sciammarella pioneered digital analysis of moiré fringes with the use of computers.[7] In 1985, he further developed this methodology by putting together an optics and computer system for fringe pattern analysis.[8] Later, he published a series of papers answering how far it is possible to recover fringe order information utilizing computer analysis. This work culminated in the paper Heisenberg Principle Applied to the Analysis of Speckle Interferometry Fringes. [9]
Since 2005, Dr. Sciammarella, with his co-workers, succeeded in overcoming the Rayleigh limit. In recent work, measurements in the far field have been carried out in nano-crystals and nano-spheres with accuracies on the order of ±3.3 nm.[10][11]
In 2012, Cesar Sciammarella and his son Dr. Federico Sciammarella co-authored Experimental Mechanics of Solids, a comprehensive textbook of the techniques used in experimental mechanics.[12]