Your search keyword '"Szenher, Matthew"' showing total 4 results

1. Visual homing in dynamic indoor environments

Author

Szenher, Matthew D. and Webb, Barbara

Subjects

629.8, Informatics, Institute of Perception, Action and Behaviour, Robotics, Image processing

Abstract

Our dissertation concerns robotic navigation in dynamic indoor environments using image-based visual homing. Image-based visual homing infers the direction to a goal location S from the navigator’s current location C using the similarity between panoramic images IS and IC captured at those locations. There are several ways to compute this similarity. One of the contributions of our dissertation is to identify a robust image similarity measure – mutual image information – to use in dynamic indoor environments. We crafted novel methods to speed the computation of mutual image information with both parallel and serial processors and demonstrated that these time-savers had little negative effect on homing success. Image-based visual homing requires a homing agent tomove so as to optimise themutual image information signal. As the mutual information signal is corrupted by sensor noise we turned to the stochastic optimisation literature for appropriate optimisation algorithms. We tested a number of these algorithms in both simulated and real dynamic laboratory environments and found that gradient descent (with gradients computed by one-sided differences) works best.

Published

2008

2. A Hardware and Software Platform for Aerial Object Localization

Author

Szenher, Matthew, Delacroix, Alex, Keto, Eric, Little, Sarah, Randall, Mitch, Watters, Wesley Andrés, Masson, Eric, Cloete, Richard, Szenher, Matthew, Delacroix, Alex, Keto, Eric, Little, Sarah, Randall, Mitch, Watters, Wesley Andrés, Masson, Eric, and Cloete, Richard

Abstract

To date, there are little reliable data on the position, velocity and acceleration characteristics of Unidentified Aerial Phenomena (UAP). The dual hardware and software system described in this document provides a means to address this gap. We describe a weatherized multi-camera system which can capture images in the visible, infrared and near infrared wavelengths. We then describe the software we will use to calibrate the cameras and to robustly localize objects-of-interest in three dimensions. We show how object localizations captured over time will be used to compute the velocity and acceleration of airborne objects.

Published

2023

3. The Scientific Investigation of Unidentified Aerial Phenomena (UAP) Using Multimodal Ground-Based Observatories

Author

Watters, Wesley Andrés, Loeb, Abraham, Laukien, Frank, Cloete, Richard, Delacroix, Alex, Dobroshinsky, Sergei, Horvath, Benjamin, Kelderman, Ezra, Little, Sarah, Masson, Eric, Mead, Andrew, Randall, Mitch, Schultz, Forrest, Szenher, Matthew, Vervelidou, Foteini, White, Abigail, Ahlström, Angelique, Cleland, Carol, Dockal, Spencer, Donahue, Natasha, Elowitz, Mark, Ezell, Carson, Gersznowicz, Alex, Gold, Nicholas, Hercz, Michael G., Keto, Eric, Knuth, Kevin H., Lux, Anthony, Melnick, Gary J., Moro-Martín, Amaya, Martin-Torres, Javier, Ribes, Daniel Llusa, Sail, Paul, Teodorani, Massimo, Tedesco, John Joseph, Tedesco, Gerald Thomas, Tu, Michelle, Zorzano, Maria-Paz, Watters, Wesley Andrés, Loeb, Abraham, Laukien, Frank, Cloete, Richard, Delacroix, Alex, Dobroshinsky, Sergei, Horvath, Benjamin, Kelderman, Ezra, Little, Sarah, Masson, Eric, Mead, Andrew, Randall, Mitch, Schultz, Forrest, Szenher, Matthew, Vervelidou, Foteini, White, Abigail, Ahlström, Angelique, Cleland, Carol, Dockal, Spencer, Donahue, Natasha, Elowitz, Mark, Ezell, Carson, Gersznowicz, Alex, Gold, Nicholas, Hercz, Michael G., Keto, Eric, Knuth, Kevin H., Lux, Anthony, Melnick, Gary J., Moro-Martín, Amaya, Martin-Torres, Javier, Ribes, Daniel Llusa, Sail, Paul, Teodorani, Massimo, Tedesco, John Joseph, Tedesco, Gerald Thomas, Tu, Michelle, and Zorzano, Maria-Paz

Abstract

(Abridged) Unidentified Aerial Phenomena (UAP) have resisted explanation and have received little formal scientific attention for 75 years. A primary objective of the Galileo Project is to build an integrated software and instrumentation system designed to conduct a multimodal census of aerial phenomena and to recognize anomalies. Here we present key motivations for the study of UAP and address historical objections to this research. We describe an approach for highlighting outlier events in the high-dimensional parameter space of our census measurements. We provide a detailed roadmap for deciding measurement requirements, as well as a science traceability matrix (STM) for connecting sought-after physical parameters to observables and instrument requirements. We also discuss potential strategies for deciding where to locate instruments for development, testing, and final deployment. Our instrument package is multimodal and multispectral, consisting of (1) wide-field cameras in multiple bands for targeting and tracking of aerial objects and deriving their positions and kinematics using triangulation; (2) narrow-field instruments including cameras for characterizing morphology, spectra, polarimetry, and photometry; (3) passive multistatic arrays of antennas and receivers for radar-derived range and kinematics; (4) radio spectrum analyzers to measure radio and microwave emissions; (5) microphones for sampling acoustic emissions in the infrasonic through ultrasonic frequency bands; and (6) environmental sensors for characterizing ambient conditions (temperature, pressure, humidity, and wind velocity), as well as quasistatic electric and magnetic fields, and energetic particles. The use of multispectral instruments and multiple sensor modalities will help to ensure that artifacts are recognized and that true detections are corroborated and verifiable., Comment: This paper is published in the Journal of Astronomical Instrumentation, 12(1), 2340006 (2023) https://doi.org/10.1142/S2251171723400068

Published

2023

4. The Probability of Poetry: From Math to Literature.

Author

Szenher, Matthew and Worsley, Dale

Abstract

Discusses a method of teaching math students to conquer their math anxiety. Describes a student assignment to write metaphors describing their frustrations with mathematics. Outlines a method of converting the students' metaphors into poems by programming a computer to select words by scanning a list of metaphors to generate a poem. (CR)

Published

1998