Review and Trend Analysis of Water Quality Monitoring and Control Technology in Aquaculture

The real-time monitoring and control is an essential part of aquaculture, which is one of the important measures to ensure quality safety of aquatic products. After summarizing and collating the existing domestic and foreign research literature, according to the characteristic that domestic aquaculture is mostly in the closed water quality environment, such as ponds and cages, the typical structure of aquaculture water quality monitoring system, the monitoring technology of water quality, the communication technology and intelligent control technology of water quality monitoring system were summarized and compared. The results showed that the real-time online water quality monitoring and sensing technology would be the focus of research. The research of multi-parameter sensor technology based on data fusion would become a research hotspot. The prediction of water quality parameters remained the focus of water quality monitoring research, and nonlinear modeling was the main method for water quality prediction modeling. The low power wan (LPWAN) would soon become the mainstream remote communication mode in aquaculture water quality monitoring system.

Keywords: aquaculture, water quality, prediction, monitoring

 

BOSMA R II, VERDEGEM M С J. Sustainable aquaculture in ponds: principles, practices and limits[ J ]. Livestock Science, 2011 , 139( 1 -2) :58 -68.

SHAREEF Z, REDDY S R N. Wireless sensor network for aquaculture: review, survey, and case study of aquaculture practices in western Godavari region[J]. Journal of Ambient Intelligence and Smart Environments, 2018, 10(5) ; 409 -423.

OTTINGER M, CLAUSS K, KUENZER C. Aquaculture: relevance, distribution, impacts and spatial assessments—a review [J]. Ocean & Coastal Management, 2016, 119; 244 -266.

ZHOU C, XU В, LIN K, et al. Intelligent feeding control methods in aquaculture with an emphasis on fish; a review [J]. Reviews in Aquaculture, 2017,10(4) ; 1 - 19.

JANSEN II M, REID G К, BANNISTER R J, et al. Discrete water quality sampling at open-water aquaculture sites; limitations and strategies[ J ]. Aquaculture Environment Interactions, 2016, 8: 463 -480.

VAN Guoqi, N1 Xiaohui,MO Jiasi. Research status and development tendency of deep sea aquaculture equipment: a review [J]. Journal of Dalian Ocean University, 2018, 33( 1 ) : 123 - 129. ( in Chinese)

FANG Jianguang, LI Zhongjie, JIANG Zengjie, et al. Development strategy for ecological aquaculture and new mode of aquaculture farming[ J ]. Engineering Sciences, 2016(3) : 22 -28. (in Chinese)

ZHANG М, LI В, WANG L, et al. Design and development of water quality monitoring system based on wireless sensor network in aquaculture [ С ]// International Conference on Computer and Computing Technologies in Agriculture. Springer, Berlin, Heidelberg, 2010: 629 -641.

| 14] ZIIU X, LI D, HE D, et al. A remote wireless system for water quality online monitoring in intensive fish culture [ J ]. Computers and Electronics in Agriculture, 2010, 71; S3 -S9.

LIU Yuqing, LI Jiajia, CAO Shouqi, et al. Design and application of monitoring system for crab breeding based on internet of tliings [ J ]. Transactions of the CSAE, 2018,34( 16) ; 205 -213. ( in Chinese)

MAHALIk N, KIM K. Aquaculture monitoring and control systems for seaweed ami fish farming [J]. World Journal of Agricultural Research, 2014, 2(4): 176 - 182.

WANG Z, WANG Q, HAO X. The design of the remote water quality monitoring system based on WSN [ С ] //Wireless Communications, Networking and Mobile Computing, WiCom*09. 5tli International Conference on. IEEE, 2009; 1 -4.

SIMBEYE D S, YANG S F. Water quality monitoring and control for aquaculture based on wireless sensor networks [ J ] . Journal of Networks, 2014, 9(4) ; 840 -849.

LI Daoliang. Internet of things and wisdom agriculture[ J ]. Agricultural Engineering, 2012, 2( 1 ) : 1 -7. ( in Chinese)

DUPONT C, WUSSAH A, MALO S, et al. Low-cost IoT solutions for fish farmers in Africa[ С ] //2018 1ST — Africa Week Conference ( 1ST — Africa). IEEE, 2018; 1 -8.

SIMBEYE D S, ZHAO J, YANG S. Design and deployment of wireless sensor networks for aquaculture monitoring and control based on virtual instruments [ J ]. Computers and Electronics in Agriculture, 2014, 102; 31 -42.

BASAVARADDI S B, KOUSAH H, PUTTAIAH E T. Dissolved oxygen concentration—a remarkable indicator of ground water pollution in and around Tiptur town, Tumkur District, Karnataka, India[J]. Bull. Env. , Pharm. & Life Sci. , 2012, 1(3) ; 48 -54.

COLT J. Water quality requirements for reuse systems[J]. Aquacultural Engineering, 2006, 34(3) : 143 - 156.

LIAO Heqin. The design of water quality testing instrument based on liquid drop analysis technology [D]. Tianjin; Tianjin University, 2012. (in Chinese)

WIRANTO G, MAULANA Y Y, HERMIDA I D P, et al. Integrated online water quality monitoring [С] //Smart Sensors and Application ( ICSSA) , 2015 International Conference on. IEEE, 2015; 111 - 115.

GAO Minghui, MA Libao, К l.ian, et al. Nitrite uptake mechanism and the influencing factors of accumulation in aquatic animals [J]. South China Fisheries Science, 2008, 4(4) ; 73 -79. (in Chinese)

ZHANG Weiqiang, ZIIU Ying. Advances on the research of tin? hazard of ammonia nitrogen in aquaculture water and its determination method [J]. Journal of Environmental Hygiene, 2012(6) ;324 -327. (in Chinese)

ZHANG Wei, FU Weijie, SUN Yi, et al. Advances on the research of the determination of ammonia nitrogen in water [ J], Journal of Green Science and Technology ,2017 ( 10) : 19-21. (in Chinese)

ZIIOU L, BOYD С E. Comparison of Nessler, phenate, salicylate and ion selective electrode procedures for determination of total ammonia nitrogen in aquaculture[ J]. Aquaculture, 2016, 450: 187 - 193.