Safety-Aware Learning and Assured Autonomy for Aviation Applications
Funding agency: National Aeronautics and Space Administration (NASA)
This project aims to research continuously updating, self-diagnostic vehicle health management to enhance the safety and reliability of Advanced Air Mobility vehicles.
Assessment of AAM Vehicle Integration at the Orlando International Airport
Funding agency: Greater Orlando Aviation Authority (GOAA)
The assessment of Advanced Air Mobility (AAM) aircraft integration at the Orlando International Airport (MCO) examined the potential operational impacts associated with incorporating AAM traffic into the airport's Class Bravo airspace. The team developed a series of corridor prototypes to assess potential traffic conflicts and the risks of wake turbulence between commercial and AAM operations. Furthermore, an AAM ecosystem was established at MCO to enable the simultaneous integration of realistic traffic routes for commercial and AAM flights. This ecosystem was centered on operational assumptions derived from the FAA's AAM implementation plans, concepts of operation, and stakeholder involvement.
Digital transformation and modernization of general aviation airports, with a special emphasis on preparations for AAM operations
In partnership with Altaport, a survey instrument, targeting general aviation airport stakeholders across the U.S., was designed, implemented, and analyzed focusing on modernization efforts and digital adoption, with a special emphasis on preparations for advanced air mobility (AAM) operations. A resulting industry report provided insights into airport modernization trends, challenges, and the evolving landscape of airport technology and infrastructure in response to AAM developments.
Decentralized Traffic Management for Advanced Air Mobility
This project aims to develop and evaluate decentralized traffic management protocols for Advanced Air Mobility (AAM) to ensure safe, efficient, and fair operations of air taxis in urban airspace.
Efficiency Analysis of Florida Airspace for Optimizing Advanced Air Mobility and Space Launch Operations
This project aims to use flight data to improve the accuracy of trajectory prediction models for advancing Florida airspace with AAM and space flight operations using a data-driven method.
Propose Right-of-Way Rules for UAS Operation and Safety Recommendations
Funding agency: Federal Aviation Administration (FAA)
The overall purpose of this project was to inform rulemaking and standards development regarding potential Right of Way (RoW) concepts for manned an unmanned aircraft in the low altitude environment.
Crowdsensing-Based Multi-Agent Data Collection and Aerial-Terrestrial Hybrid Route Determination for Three Dimensional Urban Environments
This project introduces a novel approach that combines crowdsensing and agent-based modeling to gather high-resolution data in a simulated 3D urban environment, offering predictive enhancements for AAM operations.
Usability of Urban Air Mobility: Quantitative and Qualitative Assessments of Usage in Emergency Situations
Funding agency: U.S. Department of Transportation (USDOT)
The purpose of these studies was to determine the usability of urban air mobility (UAM) vehicles in the emergency response to natural disasters and the ideal locations for their take-off and landing sites to occur. UAM involves aerial vehicles, mostly operated autonomously, which can complete short flights around urban areas, although their applications are expanding to rural operations as well. While initially designed to support advanced transportation mobility, these vehicles could offer numerous advantages in the emergency response to natural disasters. Through a series of four studies with over 2,000 total participants, quantitative and qualitative methods were used to identify UAM vehicles' usability in response to natural disasters. The studies examined the types of natural disasters and types of missions where UAM could be considered usable, along with the creation of a valid scale to determine vertiport usability. Interviews were also be conducted to provide qualitative insights to complement the quantitative findings.
Identify Models for Advanced Air Mobility (AAM)/Urban Air Mobility (UAM) Safe Automation
Funding agency: Federal Aviation Administration (FAA)
Advanced Air Mobility (AAM) and Urban Air Mobility (UAM) operations are expected to involve significant amounts of machine automation in order for operations to be profitable. This work focused on Unmanned Aircraft Systems (UAS) used for passenger transport and cargo delivery in urban areas. The research evaluated AAM/UAM core technology, system architecture, automation design, and system functional concepts to aid the FAA and industry standards development organizations in creating paths forward for these new operational capabilities.
GUMP: General Urban Area Microclimate Predictions Tool
Funding agency: National Aeronautics and Space Administration (NASA)
Adverse weather conditions, particularly high winds, can have a highly adverse impact on small uncrewed aircraft system (sUAS) operations. These conditions can vary significantly within a small area (particularly in an urban environment); thus, hyperlocal weather predictions are often necessary in order to determine whether a particular sUAS route will be safe to fly. The General Urban area Microclimate Predictions tool (GUMP) seeks to provide such predictions through the use of machine learning (ML) models and computational fluid dynamics (CFD) simulations. Specifically, ML models are trained to ingest mesoscale forecasts from the National Oceanic and Atmospheric Administration (NOAA) and output refined forecasts for some specific location, typically, a weather station that serves as a source of ground truth data during training. At the same time, CFD simulations over 3D models of structures (e.g., buildings) are utilized to extend the refined forecast to other points within the area of interest surrounding the location. Because it is difficult to perform such simulations in real-time, they are executed offline under a wide range of boundary conditions, generating a broad set of resulting wind flow fields. During deployment, GUMP retrieves the wind flow field that is most consistent with the ML model’s forecast. The wind flow field can be converted into an intuitive risk map for sUAS operators through the use of appropriate thresholds on wind velocities.
MoVE: A Mobility Virtual Environment for Planning, Rehearsing, Collecting and Visualizing Atmospheric Observations Using Multiple Coordinated Unmanned Aerial Vehicles
Unmanned Aircraft Systems (UAS) have become prevalent in a wide variety of meteorological investigations. UAS afford the ability to fill an important atmospheric observational gap, namely observations in the domain between the reach of ground-based sensors and the altitudes that manned aircraft can safely operate at. Fixed-wing UAS offer an opportunity to cover vast horizontal and vertical distances in a continuous manner with high spatial resolution. Multirotor UAS possess the ability to launch and recover in small spaces, fly at slow airspeeds, hover, accomplish vertical profiles, and probe obstacle laden environments while making spatially dense observations. Each of these UAS categories offer a new observational strategy that is efficient, reusable, durable, repeatable, has a much lower cost barrier, requires minimal infrastructure, and renders superior spatial flexibility, range, and resolution.
Swarms of meteorologically instrumented UAS provide an opportunity to further capitalize on these advantages. However, any given UAS flight must remain within visual line of sight (VLOS) of the remote pilot. Therefore, in order to observe a large geographical area that spans beyond VLOS, multiple UAS must be simultaneously flown. Likewise, to accomplish more spatially dense observations in an immediate area, multiple UAS must undertake concurrent observations. Each of these strategies increase the complexity of the operation and present a challenge in tying together disparate measurements.
To assist in multi-vehicle data collection, as previously described, the open-source, publicly available Mobility Virtual Environment (MoVE) has been developed. This software is designed to first rehearse multi-vehicle scenarios in simulation and then collect real data in real time using a cellular network. In simulation, MoVE can be used to select waypoint routes that ensure safety, are appropriate for the objectives of the atmospheric investigation, and fit within the performance envelope of the involved pilots and unmanned aircraft (UA). Once observational strategies are reasonably well prepared in the virtual environment, real pilots with real UA can rehearse or undertake flight plans with uninstrumented or instrumented UA. Through MoVE, all data is brought together in time and geo-tagged at suitable frequencies making it easy to combine individual UA data together into a single data set. In this presentation, the ability of MoVE to streamline the planning, execution, post-processing and visualization of data in multi-vehicle field campaigns is explored. The benefits MoVE affords the atmospheric science community can also translate to the broader scientific and engineering communities.
Real-Time Weather Observations for Urban Air Mobility
Urban air mobility (UAM) is expected to be an integral component of cities of the future. However, the urban environment is a new setting for sustained aviation operations. The lower mass, more limited thrust and slower speeds of these vehicles increase their sensitivity to the spatially and temporally dynamic urban environment. Exacerbating this situation is the fact that traditional aviation weather products for observations and forecasts on the outskirts of a metropolitan area do not necessarily translate well to the urban setting. The initial and continuing costs associated with a dense meteorological observation network, required for the heterogeneous nature of the urban environment, make the creation of one in every participating metropolitan area across the country unrealistic. This project explores a variety of potential data sources and proposes a cyber-physical system (CPS) architecture, including an incentive-based crowdsensing application, for real-time aviation observations.
Data Link Security Analysis with Threat Modeling, Simulation Testbed, and Prototype Risk Assessment Tool
Funding agency: Federal Aviation Administration (FAA)
The analysis of data link security with threat modeling led to the development of a simulation testbed and a prototype risk assessment tool. Simulated tests of identified threats were conducted to determine the optimal solution for protecting against potential aviation data link security threats. As part of this task, a testbed environment was created to replicate critical wireless data links and collect real data that mimicked the identified threats posed by potential hackers. Based on the data collected from this testbed and the review of existing security assessment tools, a requirements and specification document for an effective security assessment tool was created. Additionally, a prototype FAA security risk assessment tool was designed and built using existing commercial and/or open-source tools to test each threat scenario identified during the data collection phase
UAS Traffic Analysis
Funding agency: Federal Aviation Administration (FAA)
In order for the FAA to maintain the safety of the NAS and accommodate new types of UAS operations, it is important to monitor the effectiveness of existing UAS regulations and forecast future UAS integration needs. Using detection data, first of its kind, this research will provide data to support those needs by analyzing sUAS traffic at several urban locations across the NAS.
Analyze Drone Traffic
Funding agency: Federal Aviation Administration (FAA)
The FAA’s mission is to maintain the safety of the NAS while accommodating new types of Unmanned Aircraft System (UAS) operations, and – to that end – it is important to assess the effectiveness of existing drone regulations and forecast future UAS integration needs. Using detection data, first of its kind all available data including registration, survey, surveillance and navigation, this research will provide data to support those needs by analyzing drone traffic and drone traffic collision risks at several urban locations across the NAS. Note that this research will expand upon prior work and continue efforts to analyze and understand traffic trends for UAS operations in the NAS.
Integrate and Analysis of sUAS Survey, Registration and Airspace Data for Enhanced Risk Assessment and Forecasting
Funding agency: Federal Aviation Administration (FAA)
The purpose of this project is to analyze FAA furnished and publicly available sUAS datasets to support the following tasks: 1) estimation and forecasting of sUAS population; 2) understand sUAS operational behaviors (such as operational times, flight frequency, flight duration, operation type, and related factors); 3) create an instrument or algorithm for assessing sUAS operational air and ground risk; 4) evaluate potential implications of sUAS operations on future National Airspace System activities (such as Advanced Air Mobility) and, 4) support integration of further analysis capabilities within the FAA’s Geographic Low Altitude Risk Estimation (GLARE) analysis tool. Implementation of additional capabilities are effected via additional or modification of various geographic information systems (GIS) layers within the FAA’s ArcGIS infrastructure, or incorporated into a supporting data visualization tool, such as Tableau. Specific emphasis is placed on enabling refined estimation of sUAS population and operational activities at county-level geospatial fidelity. When possible, data is assessed for temporal changes to enable trend identification.