Fitness Dependent Optimizer for IoT Healthcare using Adapted Parameters:
A Case Study Implementation
- URL: http://arxiv.org/abs/2207.04846v1
- Date: Wed, 18 May 2022 16:18:57 GMT
- Title: Fitness Dependent Optimizer for IoT Healthcare using Adapted Parameters:
A Case Study Implementation
- Authors: Aso M. Aladdin, Jaza M. Abdullah, Kazhan Othman Mohammed Salih, Tarik
A. Rashid, Rafid Sagban, Abeer Alsaddon, Nebojsa Bacanin, Amit Chhabra,
S.Vimal, Indradip Banerjee
- Abstract summary: This chapter discusses a case study on Fitness Dependentwarm or so-called FDO and adapting its parameters to the Internet of Things (IoT) healthcare.
Other algorithms are evaluated and compared to FDO as Genetic Algorithm (GA) and Particle Swarm Optimization (PSO) in the original work.
The target of this chapter's enhancement is to adapt the IoT healthcare framework based on FDO to spawn effective IoT healthcare applications.
- Score: 0.629786844297945
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: This discusses a case study on Fitness Dependent Optimizer or so-called FDO
and adapting its parameters to the Internet of Things (IoT) healthcare. The
reproductive way is sparked by the bee swarm and the collaborative
decision-making of FDO. As opposed to the honey bee or artificial bee colony
algorithms, this algorithm has no connection to them. In FDO, the search
agent's position is updated using speed or velocity, but it's done differently.
It creates weights based on the fitness function value of the problem, which
assists lead the agents through the exploration and exploitation processes.
Other algorithms are evaluated and compared to FDO as Genetic Algorithm (GA)
and Particle Swarm Optimization (PSO) in the original work. The key current
algorithms:The Salp-Swarm Algorithms (SSA), Dragonfly Algorithm (DA), and Whale
Optimization Algorithm (WOA) have been evaluated against FDO in terms of their
results. Using these FDO experimental findings, we may conclude that FDO
outperforms the other techniques stated. There are two primary goals for this
chapter: first, the implementation of FDO will be shown step-by-step so that
readers can better comprehend the algorithm method and apply FDO to solve
real-world applications quickly. The second issue deals with how to tweak the
FDO settings to make the meta-heuristic evolutionary algorithm better in the
IoT health service system at evaluating big quantities of information.
Ultimately, the target of this chapter's enhancement is to adapt the IoT
healthcare framework based on FDO to spawn effective IoT healthcare
applications for reasoning out real-world optimization, aggregation,
prediction, segmentation, and other technological problems.
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