Design of the Control System for Chinese Mitten Crab Nurturing Megalopa Based on Fuzzy-Control Technology

Hong Guang Cui; Wen Tao Ren; Bo Wang

doi:10.4028/www.scientific.net/AMM.644-650.41

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Design and Implementation of ARM-Based Intelligent Switchgear Control System
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Design of the Control System for Chinese Mitten Crab Nurturing Megalopa Based on Fuzzy-Control Technology
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 644-650Design of the Control System for Chinese Mitten...

Design of the Control System for Chinese Mitten Crab Nurturing Megalopa Based on Fuzzy-Control Technology

Abstract:

Using the indoor control system of breeding mitten crab could increase the survival rate and quality effectively. This paper based on the analysis of environmental water quality of breeding mitten crab, according to the characteristics of crab cultivation of water environment, then the method of fuzzy control was proposed to realize the automatic control, the application of MATLAB software complete the design of the fuzzy controller. Combining STC12C5A08AD single chip as mainly control unit and fuzzy control method, design the hardware and software of the crab cultivation environment control system, and the design of fuzzy controller. In the case of the pH control test results, the system performance approximately for the time constant of a character of first-order inertial of 27.535s, which caters the requirement of pH value of crab cultivation. The invention of this controlling system can be a fundament of control of aquaculture environment.

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Periodical:

Applied Mechanics and Materials (Volumes 644-650)

Pages:

41-44

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.644-650.41

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Online since:

September 2014

Authors:

Hong Guang Cui, Wen Tao Ren*, Bo Wang

Keywords:

Chinese Mitten Crab, Control System, Megalopa, Water Quality Detectopm

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* - Corresponding Author

References

[1] Dang J.W., Zhao S.X., Wang Y.P. Fuzzy control technology. Press of Chinese railway (2007).

Google Scholar

[2] Zhong Y.S. ，Yang J.Q. ， Deng J.L. Multivariable fuzzy control of temperature and humidity in a greenhouse. Transaction of the Chinese Society for Agricultural Machinery, (2001)32(3), 75-78.

Google Scholar

[3] Gong C.K., Chen C.Y., Mao H.P. Multivariable fuzzy control and simulation of a greenhouse environment. Transaction of the Chinese Society for Agricultural Machinery, (2000)316), 52-54.

Google Scholar

[4] Ding W.M., Wang X.C., Li Y.N., et al. Review on environmental control and simulation models for greenhouse. Transaction of the Chinese Society for Agricultural Machinery, (2009)40(5), 162-168.

Google Scholar

[5] Yu Y.C., Hu J.D., Mao P.J. Fuzzy control for environment parameters in greenhouse. Transaction of the Chinese Society of Agricultural Engineering, (2002)18(2), 72-75.

Google Scholar

[6] Xie S.H., Gan Y. Fuzzy control system design and applying examples of MCU. Press of electronics industry(1999).

Google Scholar

[7] Guo, Y. X., Liu, W. N., Zhao, Q. X. Study on micro process control system based on precise Sowing. Journal of Agricultural Mechanization Research, (2008)9, 81-83.

Google Scholar

[8] Qiao, X. J., Shen, Z. R., Chen, Q. Y. Design and realization of general computer monitoring and controlling system for environment of agricultural facilities. Transactions of the CSAE, (2000) 16(3), 77-80.

Google Scholar

[9] Wu, Q. H., Xu, B. Q. Analysis of synchronized control system for multi-Motor. Auto-control O.I. Automation, (2003)22(1), 20-24.

Google Scholar

[10] Ding, W. M., Wang, X. C., Li, Y. N. Review on environmental control and simulation models for greenhouse. Transaction of the Chinese Society for Agricultural Machinery, (2009)40(5), 162-168.

Google Scholar

[11] Zheng,S. S., Huang,Y. Q. Measurement virtual instrument design. Mechanical & Electrical Engineering Technology, (2005)34(3), 44–46.

Google Scholar