Multi-layer model of swarm intelligence for resilient autonomous systems
Title | Multi-layer model of swarm intelligence for resilient autonomous systems |
Publication Type | Conference Paper |
Year of Publication | 2017 |
Authors | Clifford, J., Garfield, K., Towhidnejad, M., Neighbors, J., Miller, M., Verenich, E., Staskevich, G. |
Conference Name | 2017 IEEE/AIAA 36th Digital Avionics Systems Conference (DASC) |
Date Published | sep |
ISBN Number | 978-1-5386-0365-9 |
Keywords | Air Force Research Lab, anti-access area denial environments, artificial life concepts, artificial life paradigm, autonomous aerial vehicles, autonomous systems, Bioinformatics, central nervous system, composability, cyber-physical layer, deliberative layer, Embry-Riddle Aeronautical University, fast-reactive control systems, Force, genetic algorithm, genetic algorithms, genomics, higher layers, hostile environments, intelligence-surveillance-reconnaissance task, intelligent adaptive adversaries, Intelligent systems, learning (artificial intelligence), lower layers, machine learning techniques, mobile robots, multilayer model, Neural Network, physical configuration, Planning, pubcrawl, reactive layer, resilient autonomous systems, Sensors, stable environment, swarm intelligence |
Abstract | Embry-Riddle Aeronautical University (ERAU) is working with the Air Force Research Lab (AFRL) to develop a distributed multi-layer autonomous UAS planning and control technology for gathering intelligence in Anti-Access Area Denial (A2/AD) environments populated by intelligent adaptive adversaries. These resilient autonomous systems are able to navigate through hostile environments while performing Intelligence, Surveillance, and Reconnaissance (ISR) tasks, and minimizing the loss of assets. Our approach incorporates artificial life concepts, with a high-level architecture divided into three biologically inspired layers: cyber-physical, reactive, and deliberative. Each layer has a dynamic level of influence over the behavior of the agent. Algorithms within the layers act on a filtered view of reality, abstracted in the layer immediately below. Each layer takes input from the layer below, provides output to the layer above, and provides direction to the layer below. Fast-reactive control systems in lower layers ensure a stable environment supporting cognitive function on higher layers. The cyber-physical layer represents the central nervous system of the individual, consisting of elements of the vehicle that cannot be changed such as sensors, power plant, and physical configuration. On the reactive layer, the system uses an artificial life paradigm, where each agent interacts with the environment using a set of simple rules regarding wants and needs. Information is communicated explicitly via message passing and implicitly via observation and recognition of behavior. In the deliberative layer, individual agents look outward to the group, deliberating on efficient resource management and cooperation with other agents. Strategies at all layers are developed using machine learning techniques such as Genetic Algorithm (GA) or NN applied to system training that takes place prior to the mission. |
URL | https://ieeexplore.ieee.org/document/8102147/ |
DOI | 10.1109/DASC.2017.8102147 |
Citation Key | clifford_multi-layer_2017 |
- neural network
- intelligence-surveillance-reconnaissance task
- intelligent adaptive adversaries
- Intelligent systems
- learning (artificial intelligence)
- lower layers
- machine learning techniques
- mobile robots
- multilayer model
- hostile environments
- physical configuration
- Planning
- pubcrawl
- reactive layer
- resilient autonomous systems
- sensors
- stable environment
- Swarm Intelligence
- cyber-physical layer
- anti-access area denial environments
- artificial life concepts
- artificial life paradigm
- autonomous aerial vehicles
- autonomous systems
- bioinformatics
- central nervous system
- composability
- Air Force Research Lab
- deliberative layer
- Embry-Riddle Aeronautical University
- fast-reactive control systems
- Force
- genetic algorithm
- genetic algorithms
- genomics
- higher layers