dc.description.abstract |
This study extended the boid model to a bird-bot ontology for coordinating robotic
devices deployed for surveillance purposes. The key attributes of the ontology
are the boid rules, the environment, and meta-data on how each component
interacts with other components. Apart from the boid rules, controlled robotic
device actions such as orientation, movement, and speed are integrated into the
ontology to bring about realism and visually appealing simulations. The proposed
ontology was experimentally evaluated for usability and validity in the surveillance
of stationary objects like buildings and dynamic targets like vehicles. The bird-bot
ontology demonstrated superior performance in surveilling stationary targets
when modifying the variable values of control routines (actions) compared to
controlled bird-bots. In the experiments, deployment points were controlled to
allow experiment repeatability. Usability was measured by quantifying the
emergent behavior that emanated from applying the ontology. We looked at how
closely robotic devices stayed together, how they moved in the same general
direction, and how they avoided collisions. We evaluated the time it took for the
bird-bots to locate the target and commence surveillance, which directly reflected
the speed and quality of their emergence. We assessed whether the robotic
devices maintained appropriate spacing and demonstrated avoidance
behaviours, preventing overcrowding and collisions. We also assessed whether
robotic devices maintained their velocities to match those of their neighbours,
resulting in smooth and coordinated movement. Results indicated that the
proposed ontology had causal properties. Robotic devices achieved successful
area coverage with desirable efficiency and speed. Effective separation,
cohesion, and alignment were observed. Properties such as fault tolerance,
adaptability, and robustness emerged. To be precise, the logic in the ontology
can be applied to optimise traffic flow in urban areas, highways, and
transportation systems. It can inform the design of public spaces, pedestrian
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walkways, and urban layouts. This ontology can also be used to develop
strategies for search and rescue operations. During natural disasters, such as
earthquakes or wildfires, people often need to evacuate quickly and safely. The
ontology can guide the development of evacuation plans that ensure a smooth
flow of people and minimize the risk of stampedes. These features insinuate that
an understanding of the ontology can aid in managing large crowds during
events, protests, or gatherings. Even intriguing is the likelihood of this ontology
successfully guiding the movement of autonomous vehicles or sensors in
environmental monitoring tasks. |
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