A Structurally-Adaptive Framework for Distributed Airborne Sensing over Real-time Collaborative Information Sharing Networks
A Structurally-Adaptive Framework for Distributed Airborne Sensing over Real-time Collaborative Information Sharing Networks
- Neue Suche nach: Corey A Ippolito
- Neue Suche nach: Evan Kawamura
- Neue Suche nach: George Gorospe
- Neue Suche nach: Wendy Holforty
- Neue Suche nach: Keerthana Kannan
- Neue Suche nach: Vahram Stepanyan
- Neue Suche nach: Thomas Lombaerts
- Neue Suche nach: Nelson Brown
- Neue Suche nach: A J Jaffe
- Neue Suche nach: Chester Dolph
- Neue Suche nach: Corey A Ippolito
- Neue Suche nach: Evan Kawamura
- Neue Suche nach: George Gorospe
- Neue Suche nach: Wendy Holforty
- Neue Suche nach: Keerthana Kannan
- Neue Suche nach: Vahram Stepanyan
- Neue Suche nach: Thomas Lombaerts
- Neue Suche nach: Nelson Brown
- Neue Suche nach: A J Jaffe
- Neue Suche nach: Chester Dolph
The emergence and maturation of wireless communication technologies continue to transform the aviation industry and are enabling new solutions to challenges faced by NASA’s Advanced Air Mobility (AAM) initiative. AAM is leading towards high-density autonomous aircraft operations in areas underserved by traditional aviation, such as over densely populated urban centers. In this paper, we build on concepts from distributed sensing and smart spaces - where sensing, processing, and communication are embedded in an environment, and agents are operating within the space can exploit these capabilities in real-time through collaborative information sharing networks. Building from these concepts, we propose a framework to enable a dynamic, topologically-adaptive, and distributed estimation system for man-rated aviation to address challenges faced by autonomous AAM operations. This paper presents the initial concept of operations and system design for this framework, presents a mathematical formulation for abstraction of the problem, identifies requirements and constraints for operation, and presents algorithmic constructs to demonstrate operation. The initial framework design will focus on supporting precision navigation and independent surveillance supporting conformance monitoring of aircraft in airspace corridors and vertiport airspaces. Preliminary results from this framework shows promise in addressing gaps in current technologies needed to enable future AAM concepts, while promising greater capabilities, performance, robustness, and safety over current aviation systems and operations.
Dokumentinformationen
A Structurally-Adaptive Framework for Distributed Airborne Sensing over Real-time Collaborative Information Sharing Networks
AIAA SciTech Forum and Exposition ; 2023 ; National Harbor, MD, US
Aufsatz (Konferenz)
Keine Angabe
Englisch