Open Access
ARTICLE
Development of an Artificial Fish Swarm Algorithm Based on a Wireless Sensor Networks in a Hydrodynamic Background
Sheng Bai, Feng Bao*, Fengzhi Zhao, Miaomiao Liu
School of Computer and Information Technology, Northeast Petroleum University, Daqing, 163318, China
* Corresponding Author: Feng Bao. Email:
(This article belongs to this Special Issue: EFD and Heat Transfer II)
Fluid Dynamics & Materials Processing 2020, 16(5), 935-946. https://doi.org/10.32604/fdmp.2020.010113
Received 26 February 2020; Accepted 13 August 2020; Issue published 09 October 2020
Abstract
The main objective of the present study is the development of a new
algorithm that can adapt to complex and changeable environments. An artificial
fish swarm algorithm is developed which relies on a wireless sensor network
(WSN) in a hydrodynamic background. The nodes of this algorithm are viscous
fluids and artificial fish, while related ‘events’ are directly connected to the food
available in the related virtual environment. The results show that the total processing time of the data by the source node is 6.661 ms, of which the processing time
of crosstalk data is 3.789 ms, accounting for 56.89%. The total processing time of
the data by the relay node is 15.492 ms, of which the system scheduling and the
Carrier Sense Multiple Access (CSMA) rollback time of the forwarding is
8.922 ms, accounting for 57.59%. The total time for the data processing of the
receiving node is 11.835 ms, of which the processing time of crosstalk data is
3.791 ms, accounting for 32.02%; the serial data processing time is 4.542 ms,
accounting for 38.36%. Crosstalk packets occupy a certain amount of system
overhead in the internal communication of nodes, which is one of the causes of
node-level congestion. We show that optimizing the crosstalk phenomenon can
alleviate the internal congestion of nodes to some extent.
Keywords
Cite This Article
Bai, S., Bao, F., Zhao, F., Liu, M. (2020). Development of an Artificial Fish Swarm Algorithm Based on a Wireless Sensor Networks in a Hydrodynamic Background.
FDMP-Fluid Dynamics & Materials Processing, 16(5), 935–946.