Abstract
Conventionally, agent-based modelling approaches start from a conceptual model capturing the theoretical understanding of the systems of interest. Simulation outcomes are then used “at the end” to validate the conceptual understanding. In today’s data rich era, there are suggestions that models should be data-driven. Data-driven workflows are common in mathematical models. However, their application to agent-based models is still in its infancy. Integration of real-time sensor data into modelling workflows opens up the possibility of comparing simulations against real data during the model run. Calibration and validation procedures thus become automated processes that are iteratively executed during the simulation. We hypothesize that incorporation of real-time sensor data into agent-based models improves the predictive ability of such models. In particular, that such integration results in increasingly well calibrated model parameters and rule sets. In this contribution, we explore this question by implementing a flocking model that evolves in real-time. Specifically, we use genetic algorithms approach to simulate representative parameters to describe flight routes of homing pigeons. The navigation parameters of pigeons are simulated and dynamically evaluated against emulated GPS sensor data streams and optimised based on the fitness of candidate parameters. As a result, the model was able to accurately simulate the relative-turn angles and step-distance of homing pigeons. Further, the optimised parameters could replicate loops, which are common patterns in flight tracks of homing pigeons. Finally, the use of genetic algorithms in this study allowed for a simultaneous data-driven optimization and sensitivity analysis.
Highlights
Agent-based models (ABM) have been formulated from a hypothesis of the systems of interest [1]
The ability of sensors, those deployed under the “breed” of wireless sensor networks (WSN) [6], to dynamically capture spatio-temporal characteristics of the systems at hand and to transfer the information in real-time raises the question on the suitability of traditional methods in model specification [7] and geospatial analysis
We set out to investigate on how spatio-temporal data about a real world system can be used to improve the specification of a rule-based agent-based models (ABM)
Summary
Agent-based models (ABM) have been formulated from a hypothesis (or rules of behaviour) of the systems of interest [1]. Emergence of miniaturized sensors and intelligent sensor networks [5] provides an opportunity of deploying sensors in remote environments and using the resulting sensor data streams to capture dynamic local characteristics of individual drivers of geographic processes. These data can be used to monitor, investigate, and to understand the influence of such individual behaviours on the overall system level outcomes. The ability of sensors, those deployed under the “breed” of wireless sensor networks (WSN) [6], to dynamically capture spatio-temporal characteristics of the systems at hand and to transfer the information in real-time raises the question on the suitability of traditional methods in model specification [7] and geospatial analysis. Sensor observations have become an integral part of research on movement behaviours [14,20,21]
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