Abstract
Internet of Things (IoT) is the paradigm that has largely contributed to the development of smart buildings in our society. This technology makes it possible to monitor all aspects of the smart building and to improve its operation. One of the main challenges encountered by IoT networks is that the the data they collect may be unreliable since IoT devices can lose accuracy for several reasons (sensor wear, sensor aging, poorly constructed buildings, etc.). The aim of our work is to study the evolution of IoT networks over time in smart buildings. The hypothesis we have tested is that, by amplifying the Lotka–Volterra equations as a community of living organisms (an ecosystem model), the reliability of the system and its components can be predicted. This model comprises a set of differential equations that describe the relationship between an IoT network and multiple IoT devices. Based on the Lotka–Volterra model, in this article, we propose a model in which the predators are the non-precision IoT devices and the prey are the precision IoT devices. Furthermore, a third species is introduced, the maintenance staff, which will impact the interaction between both species, helping the prey to survive within the ecosystem. This is the first Lotka–Volterra model that is applied in the field of IoT. Our work establishes a proof of concept in the field and opens a wide spectrum of applications for biology models to be applied in IoT.
Highlights
The aim is to mathematically validate the Lotka–Volterra non-autonomous system (LVNA) model proposed in this paper and to study the behavior of Internet of Things (IoT) devices in an IoT network in order to predict their reliability over time
We extend the LV equations from community ecology to an ecosystem model based in an IoT
We show the IoT model as an LVNA system in system evolution prediction through trajectories and equilibrium points analysis in C1
Summary
Internet of Things (IoT) networks are a current solution to a wide spectrum of technological problems. The range of applications varies from environment control and security to home automation and security control [1]. IoT networks relay the information provided by sensors in the IoT nodes. Data from the sensors are integrated and processed by the control algorithm that produces actuator signals. Faulty data due to inaccurate IoT nodes cause the algorithm to make erroneous decisions. Given that sensors are accurate (AD) in a normal state, we can define an inaccurate (NAD) state as an abnormal state caused by a malfunction, or even a False Data Injection attack [2]
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