推进水产养殖:基于模糊逻辑的精准水产养殖水质监测和维护系统

IF 2.2 3区 农林科学 Q2 FISHERIES
Sudheer Kumar Nagothu, Pudota Bindu Sri, G. Anitha, Shweta Vincent, Om Prakash Kumar
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引用次数: 0

摘要

水产养殖在全球粮食生产中发挥着至关重要的作用,而保持最佳水质对水生物种的健康和生长至关重要。这项研究通过为水产养殖池塘引入创新的水质监测和维护系统,满足了对高效、自适应解决方案的需求。与传统系统不同,我们的方法独特地将模糊逻辑与物联网技术相结合,以优化池塘管理的精确性和适应性。该系统可持续监测温度、pH 值、溶解氧 (DO)、天气条件和盐度等关键参数,并能根据动态环境变化自主调整增氧机和水泵等操作控制。这确保了理想的水质条件,无需人工干预,为水产养殖池塘管理提供了可靠而有效的解决方案。这项工作的新颖之处在于应用模糊逻辑来处理水产养殖环境的复杂性和多变性,从而做出细致入微的控制决策,改善水质管理。该系统通过 72 小时的运行测试证明了其效率,在该测试中,该系统保持了最佳溶解氧和盐度水平,展示了其在实际条件下的可靠性和有效性。模糊逻辑模型的准确率高达 98%,值得称赞。这些结果验证了该系统的性能,并强调了其实际效益,通过实现远程监控和快速问题识别,满足了水产养殖生产的需求,并显著提高了运营效率。这项研究为水产养殖者提供了一个强大的技术解决方案,通过提高生产力和确保水生物种的健康和生长,为水产养殖管理带来了可喜的进步。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Advancing aquaculture: fuzzy logic-based water quality monitoring and maintenance system for precision aquaculture

Aquaculture plays a vital role in global food production, and maintaining optimal water quality is essential for the health and growth of aquatic species. This research addresses the need for an efficient, adaptive solution by introducing an innovative water quality monitoring and maintenance system for aquaculture ponds. Unlike conventional systems, our approach uniquely integrates fuzzy logic with IoT technologies to optimise the precision and adaptability of pond management. The system stands out with its continuous monitoring of critical parameters such as temperature, pH, dissolved oxygen (DO), weather conditions and salinity and its ability to autonomously adjust operational controls, such as aerators and water pumps, based on dynamic environmental changes. This ensures ideal water conditions without manual intervention, providing a reliable and effective solution for aquaculture pond management. This work’s novelty lies in applying fuzzy Logic to handle the complexity and variability of aquaculture environments, allowing for nuanced control decisions that improve water quality management. The system’s efficiency was demonstrated through a 72-h operational test, where it maintained optimal DO and salinity levels, showcasing its reliability and effectiveness in real-world conditions. The fuzzy logic model has demonstrated a commendable accuracy rate of 98%. These results validate the system’s performance and underscore its practical benefits, meeting the demands of aquaculture production and significantly enhancing operational efficiency by enabling remote monitoring and rapid issue identification. This research contributes a robust technological solution for aquafarmers, offering a promising advancement in aquaculture management by improving productivity and ensuring the health and growth of aquatic species.

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来源期刊
Aquaculture International
Aquaculture International 农林科学-渔业
CiteScore
5.10
自引率
6.90%
发文量
204
审稿时长
1.0 months
期刊介绍: Aquaculture International is an international journal publishing original research papers, short communications, technical notes and review papers on all aspects of aquaculture. The Journal covers topics such as the biology, physiology, pathology and genetics of cultured fish, crustaceans, molluscs and plants, especially new species; water quality of supply systems, fluctuations in water quality within farms and the environmental impacts of aquacultural operations; nutrition, feeding and stocking practices, especially as they affect the health and growth rates of cultured species; sustainable production techniques; bioengineering studies on the design and management of offshore and land-based systems; the improvement of quality and marketing of farmed products; sociological and societal impacts of aquaculture, and more. This is the official Journal of the European Aquaculture Society.
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