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HIGH-SPEED SHAPE AND DISPLACEMENT MEASUREMENTS BY HOLOGRAPHY AND APPLICATIONS IN MIDDLE-EAR RESEARCH
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Development of digital holographic vibrometry methods for determination of mechanical properties of bioengineered tissues
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Opto-mechanical Characterization Methods to Understand Physical and Mechanical Properties of Bioengineered Tissue
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Rapid prototyping of fiber-optic based micro-force sensors by two-photon polymerization
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Multifunctional Testing Artifacts for Evaluation of 3D Printed Components by Fused Deposition Modeling
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A Feasibility Study on Using Infrared- transmitting Fiber-optics for Thermal Imaging
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Development of high-speed digital holographic shape and displacement measurement methods for middle-ear mechanics in-vivo
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Development of an Infrared Direct Viewer Based on a MEMS Focal Plane Array
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Full-field vibrometry by high-speed digital holography for middle-ear mechanics
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Development of a multi-wavelength lensless digital holography system for 3D deformations and shape measurements of tympanic membranes
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Development of Holographic Interferometric Methodologies for Characterization of Shape and Function of the Human Tympanic Membrane
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Computational and Experimental Approach for Non-destructive Testing by Laser Shearography
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Interferometric Optical Readout System for a MEMS Infrared Imaging Detector
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Powering of endoscopic cutting tools for minimally invasive procedures
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Development of a High Speed, Robust System for Full Field-of-View 3D Shape Measurements
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Development of Sound Presentation System (SPS) for Characterization of Sound Induced Displacements in Tympanic Membranes
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Development of an Optoelectronic Holographic Platform for Otolaryngology Applications
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Development of an optoelectronic holographic otoscope system for characterization of sound-induced displacements in tympanic membranes
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Phase modulating interferometry with stroboscopic illumination for characterization of MEMS
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Development of a wireless MEMS inertial system for health monitoring of structures
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