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Ongoing Projects

Note: Unless otherwise noted, project Principal Investigator (PI) is Dr. DeLaurentis.

High Speed Flight Systems & Defense Cluster

 

Design, Build, Test, and Fly (DBTF) Time Reduction
SponsorStratolaunch
Co-Investigator: Dr. Leifur Leifsson (AAE)

SynopsisThe team optimizes/minimizes the cycle time for the Design, Build, Test, and Fly (DBTF) process by using the SoS tools

 

Wolfpack
SponsorUniversity Consortium for Applied Hypersonics (UCAH)
Co-investigators: Dr. Shreyas Sundaram (ECE)

Synopsis: The team applies optimal trajectory generation techniques and the SoS AWB tool suite to hypersonic vehicle missions, allowing multiple hypersonic and conventional vehicles to complete preemptive strike and defensive missions.

Advanced Aerial Mobility & Air Transportation Cluster

Operations limits for passenger-carrying Urban Air Mobility missions
Principal-investigators: Dr. Daniel DeLaurentis, Dr. William Crossley
Sponsor: Logistics Management Institute, NASA Langley Research Center

Synopsis: The convergence of new technologies, such as electric propulsion, autonomy, and new business models, such as app-based ride sharing, are generating the potential for a new aviation market known as Urban Air Mobility (UAM) to emerge. It is envisioned that UAM may revolutionize mobility within metropolitan areas by enabling a safe, efficient, convenient, affordable, and accessible air transportation system for passengers and cargo. Such an air transportation system could bring aviation into people’s daily lives and provide an augmentation and/or alternative to other ground-based transit modes, such as cars. The UAM market is not likely to appear overnight. Rather, some form of evolutionary approach based on the pace of technology development, infrastructure limitations, societal acceptance, airspace integration, and many other factors may bring us from the current state of the art to the envisioned future state where aviation is a normal part of people’s daily lives. To help NASA’s Aeronautics Research Mission Directorate (ARMD) consider potential near-term applications for passenger-carrying UAM and which issues will be the key “bottlenecks” limiting the scalability of early UAM operations, this task is focused on studying the “operational limits” of near-term UAM applications. The work builds upon previous methodology developments of the Purdue PIs to assess the mobility benefits from CTOL and VTOL operations, at a regional transportation level and with initial “hooks” into urban areas.

UAM Ops Architecture

 

Secure and Safe Assured Autonomy (S2A2)
Sponsor: NASA University Leadership Initiative

Synopsis: The recent introduction of unmanned systems into the NAS will bring challenges and opportunities for the nation’s aviation system. The integration of such a complex transportation system creates a clear need to develop new technologies and innovative operational concepts for secure and safe assured autonomy. An unmanned systems future will see the integration of a wide variety of Unmanned Aerial Systems (UAS), personal air vehicles, Urban Air Mobility (UAM) vehicles, and cargo and special mission aircraft into the NAS. These developments can leverage UAS Traffic Management (UTM) advancements for the unique requirements of UAM airspace management. The main challenges include: (i) sensing and understanding complex operational surroundings, coordinating different types of aerial vehicles, planning and navigation through highly dynamic and uncertain environments; (ii) securing the NAS against a wide range of malicious adversarial threats, specifically cyber-physical attacks; (iii) verifying and validating autonomous system operation; and, finally, (iv) properly integrating new vehicles and traffic management approaches in the midst of autonomy. Our primary goal is to ensure safe, secure and robust integration of autonomous vehicles into a UAM-tailored transportation infrastructure while maintaining compliance with existing commercial and civil air transportation safety standards.

Space Systems Cluster

 
Studies of Disruption in Space Technologies
Sponsor: Lockheed Martin Space
 
Synopsis: The purpose of this activity is to produce scoping information that could define a plan of multidisciplinary research required to achieve disruptive capabilities in space-based quantum communication. 
 

System of Systems /Systems Engineering Methodology Cluster

 

Mission Engineering-based Integrated Acquisition Portfolio Review (IAPR) Decision-Support Tool
Sponsor: Department of Defense (DoD) via AIRC
Co-investigators: Dr. Jitesh Panchal (ME) 

Synopsis: The team adapts the SoS AWB to create decision-support prototype tools for the Integrated Acquisition Portfolio Reviews (IAPRs) and demonstrates the capability using an anti-surface warfare (ASuW) mission thread.

 

Mission-Aware Integrated Digital Transformation for Operational Advantage
PI: Dr. Jitesh Panchal
Co-PI: Dr. Daniel DeLaurentis
Sponsor: DoD

Synopsis: The project explores digitalization efforts within the Department of Defense (DoD), drawing insights from in-depth stakeholder interviews and a thorough review of existing guidelines, standards, and literature. It examines the Technical Data Package (TDP) based on MIL-STD-31000, assessing its limitations for sustainment. The project extensively explores digital models in ground vehicle development, focusing on the Joint Light Tactical Vehicle (JLTV) and detailing the types of data used alongside the application of the NATO Reference Mobility Model. Additionally, the project develops a metamodel for the JLTV TDP. The project proposes short-term enhancements for TDP and outlines long-term strategies to adapt to the rapidly evolving digital landscape. Emphasizing the adoption of digital technologies, optimizing data utilization, and addressing data challenges are central to enhancing the operational readiness and effectiveness of the DoD.

 

Pilot Program Design to Test Innovative Approaches in Negotiating Intellectual Property
PI: Dr. Daniel DeLaurentis
Sponsor: DoD
 
Synopsis: Intellectual property (IP) rights are essential for operational, sustainable, adaptable, and cost-effective systems in the Department of Defense (DoD) acquisitions. The DoD needs proper IP and technical data rights to prevent issues like vendor lock, limited sourcing, and high sustainment costs. On the other hand, Defense Industrial Base (DIB) companies view their IP as a valuable asset. Therefore, differing perspectives on IP rights between the DoD (seeking access) and DIB entities (seeking protection) create tensions that must be managed carefully. Recent advancements in additive manufacturing (AM) add IP management challenges, necessitating careful contractual considerations. This project proposes a decision framework to address these AM IP challenges, covering scenario screening, AM lifecycle, IP asset identification, and strategy options. The research illustrates the framework through three vignettes: 1. limited access to original equipment manufacturers; 2. demand surge; and 3. maintenance, repair, and operations. Furthermore, the project identifies future research pathways to enhance sustainable defense acquisition practices.