Research Projects

Platform for Investigating Concept Networks on the Instrumentality of Knowledge (PICNIK)

PI Matthew Verleger

This engineering education research project seeks to develop a concept network for engineering and a platform for helping students identify how concepts are connected across a curriculum. The goal is to better understand and improve how students value the concepts being taught throughout their education.

By data mining course materials (i.e., textbooks, course notes, syllabi, video transcripts, websites, etc.), a concept network can be developed for that course. With each additional resource, the network connectedness become more fully representative. By mapping materials from courses throughout a curriculum, and then overlaying the resulting map on a degree plan of study, students will be able to better identify and value how concepts being taught today are connected and used throughout the rest of their education. For instructors, curricular redesign becomes significantly easier, as they will be able to more fully contextualize how other courses depend on their material.

Categories: Faculty-Staff

Bayesian Analysis of Stellar Evolution

PI Theodore von Hippel

Bayesian Analysis of Stellar Evolution is an international collaboration studying stellar evolution with an emphasis on stellar ages. We also develop and support a Bayesian software suite that recovers star cluster and stellar parameters from photometry, currently called BASE-9.

BASE-9 is useful for analyzing single-age, single-metallicity star clusters, binaries, or single stars, and for simulating such systems. BASE9 uses Markov chain Monte Carlo to estimate the posterior probability distribution for the age, metallicity, distance modulus, and line-of-sight absorption for a cluster, and for the mass, binary mass ratio, and cluster membership probability for every cluster member.

Categories: Faculty-Staff

Optimizing Countermeasures for Spaceflight-Induced Deconditioning

PI Christine Walck

This research focuses on understanding space deconditioning and developing comprehensive systems to mitigate the adverse physiological effects of microgravity on astronauts.

Spaceflight-induced deconditioning presents a major challenge to human health during and after long-duration missions, contributing to muscle atrophy, bone loss, cardiovascular dysfunction, and sensorimotor impairment. This research investigates the underlying mechanisms of physiological decline in microgravity and evaluates integrated mitigation strategies using a combination of ground-based analogs (e.g., head-down tilt, LBNP), biomechanical modeling, and real-time physiological monitoring. By developing a modular countermeasure system — featuring tools like the Lower Extremity Force Acquisition System (LEFAS) and personalized exercise protocols — we aim to preserve musculoskeletal and cardiovascular integrity throughout space missions. The findings contribute to NASA’s broader efforts in preparing astronauts for lunar and Mars exploration.

Categories: Faculty-Staff

Small UAS (sUAS) Mid-Air Collision (MAC) Likelihood

PI Ryan Wallace

CO-I Dothang Truong

CO-I Scott Winter

CO-I David Cross

This research focuses on sUAS MAC likelihood analysis with general aviation (GA) and commercial aircraft. Because severity research varies based on where a collision occurred on a manned aircraft, this likelihood research will not only look at the probability of a MAC, but also the likelihood of colliding with different parts of a manned aircraft.

Complete Mid-Air Collision (MAC) risk assessments require estimates of both collision severity and collision likelihood. This research focuses on sUAS MAC likelihood analysis with General Aviation (GA) and commercial aircraft. Because severity research varies based on where a collision occurred on a manned aircraft, this likelihood research will not only look at the probability of MAC but also the likelihood of colliding with different parts of a manned aircraft.

Categories: Faculty-Staff

Best practices in teaching statistics and research methods within an aviation curriculum

PI Robert Walton

Student learning assessment is necessary at most universities, the question is whether or not student learning assessment though the use of tests can be turned into a less anxiety-provoking experience and, most ideally, into a summative learning experience for students. Using a three-test format student assessment this research examined an alternate testing paradigm, aiming directly at anxiety associated with tests and grades.

This research will examine an alternate testing paradigm, aiming directly at anxiety associated with tests and grades. The research question for this study is whether or not student assessment though the use of a traditional testing format could be made less anxiety provoking and, most ideally, be turned into a teaching/learning experience for students. Students in a statistics course will be assessed using a three-test format. Tests will be scored immediately after completion, with the student present and incorrect responses explained. The student can then retake an alternate exam and will receive the highest grade on any version of the test they take. Data will be examined for statistically-significant indicators from version 1, to 2, to 3 of the examinations.

Categories: Faculty-Staff

A Biologically Inspired Architecture Screening Tool to Improve Electric Grid Transient Response Design

PI Bryan Watson

The objective of this research is to develop and validate a new approach to design-for-transient resilience that provides additional insights, is less expensive, and can be used early in the design process.

Electrical distribution needs to protect society by providing reliable power, even under changing conditions. The current approach to design electrical distribution grids often focuses on steady state design requirements or response to a subset of potential faults. Even small and gradual changes in loading, however, can cause voltage transients and lead to major blackouts due to voltage collapse. As electric demand increases and infrastructure operates near its design limits, these events are likely to become more common. While designers can examine slowly changing load transients, this occurs after creating a model of the proposed grid, which can be costly. Thus, this research examines the following gap: A cost-effective approach is needed early in the electrical distribution design process to screen candidate architectures for their expected response to slowly changing operating conditions.

There is an opportunity to examine unexpected voltage collapse through the lens of ecosystem critical transitions. Critical transitions occur when an ecosystem shifts suddenly from one stable configuration (e.g. forest) to another (e.g. grassland) due to slowly changing environmental conditions (e.g. annual rainfall). The mathematical framework established to evaluate and classify critical transitions has been well studied but has not been used to design electrical distribution. The central hypothesis examined in this proposal is If we screen initial electrical distribution architectures with graph theory (Ecological Network Analysis), then the resulting designs will have improved critical transition performance over non-screened architectures. Critical transition performance has two aspects:

1.superior ability to absorb additional loading before voltage collapse (i.e. margin to critical transition), and

2. transition to desirable, stable secondary configurations following voltage collapse, rather than cascading throughout the system and causing a complete blackout (i.e. type of Bifurcation).

The objective of this research is to develop and validate a new approach to design-for-transient resilience that provides additional insights, is less expensive, and can be used early in the design process.

Categories: Faculty-Staff

Creating Connections: Bed bugs to UAV Swarms

PI Bryan Watson

The overarching goal of our research is to advance our understanding of bed bug behavior and use this understanding to improve performance of aerospace swarms.

Modern aerospace systems need a new approach for swarm consensus that is distributed, operates with local knowledge, and uses simple agents. The overarching goal of our research is to advance our understanding of bed bug behavior and use this understanding to improve performance of aerospace swarms. The first step is to understand individual bed bug response to stimuli (CO₂, heat, light) and individual neural characteristics, before considering group dynamics. The objective of this research was to establish a collaboration between biologists and engineers at ERAU to design and implement a test-platform to enable new data collection for bed bug movement. This collaboration begins by examining individual bed bug response to CO₂ concentration. Our central hypothesis is that if we record bed bug response to CO₂ exposure, then we will be able to improve our understanding of collective decision making because the bed bugs coordinate their response to environmental conditions. The research involved five undergraduate students from three campuses.

Categories: Faculty-Staff

Learning from Zombie Ants to Increase UAV Swarm Resilience to Faulted Agents

PI Bryan Watson

This proposal examines the issue of faulted-agent mitigation through the lens of Biologically Inspired Design.

Modern aerospace systems often approach problems by connecting many smaller agents, rather than using a single, more expensive platform. For example, it is often advantageous to have a fleet of lower-cost UAVs searching an area than a single, highly capable platform (airship). These sophisticated networks, however, are vulnerable to cascading faults. For example, errors in data from a single UAV could lead the entire search party away from their intended target. Although recognized as a vulnerability for multi-agent systems, current fault-mitigation methods have significant limitations. Centralized monitoring methods are too computationally expensive and do not work well at large scale, while solutions that rely on agents reporting their own failures may not work in situations where the units are under attack or experiencing certain types of faults (e.g. communication failures). Additionally, current approaches often have strict assumptions that may not apply in real-world systems. As a result, large-scale aerospace systems are at risk of individual agent failures that can spread throughout the entire network, causing problems with system operation, and putting personnel in danger. This proposal examines the issue of faulted-agent mitigation through the lens of Biologically Inspired Design. The objective of this research is to investigate and evaluate a new biologically inspired approach to increase multi-agent system resilience. The Ophiocordyceps camponoti-rufipedis (OCR) or Zombie Ant Fungus provides an example of fault resilience in nature. The fungus infects the ant's nervous system and alters their behavior, ultimately leading to death. However, ant colonies have developed a unique foraging and organizational structure that contains the spread of the fungus. The central hypothesis is that an examination of colony response to OCR will allow derivation of information sharing protocols to increase multi-agent system resilience to fault propagation.

Categories: Faculty-Staff

Navigation and Control for Autonomous Vessels

PI Darris White

PI Eric Coyle

PI Patrick Currier

Development of closed-form solution for control of over-actuated maritime systems.

A method for controlling the position, orientation and velocity of a marine vessel in a body of water with multiple, independently steered propulsion devices. The method involves receiving a command to move to a specific position and orientation. Utilizing position/heading feedback control, a control algorithm is used to calculate the required forces and moments to move the vehicle. Steering angles and thrust forces are determined for each of the vessel's propulsion devices. The thrust and angular displacement limits of each device are used to determine if the required forces and moments are achievable using one of three modes of operation: parallel steer, counter steer and combined parallel/counter steer. The approach fully utilizes the solution workspace for the over-actuated system without requiring the use of an optimization. The approach is used for smooth autonomous navigation in scenarios that include station keeping, path following, transitional states, disturbance rejection and object avoidance.

Categories: Faculty-Staff

Research and update SSCP Study Guide to 3d Edition

PI Michael Wills

Research current cybersecurity industry best practices, threat intelligence, and regulatory requirements, as part of publisher update for (ISC)² Systems Security Certified Professional Study Guide, 3d Edition

Extensively revise the previous (2nd Edition) of this study guide to reflect cutting-edge best practices across the information security / cybersecurity market spaces. Research to support new content for operational technology (OT) security issues -- for IoT, process control, autonomous devices, smart buildings and vehicles, and even medical implants. Focus this on the security issues of IT-OT systems integrations, becoming far more commonplace in modern business in most industries. Adapt this to self-paced learning and ready reference format required in a study guide for individual and classroom use.

Categories: Faculty-Staff