An IOT Approach for Monitoring Aqua Culture Using GSM Module

Š MAY 2020 | IRE Journals | Volume 3 Issue 11 | ISSN: 2456-8880

An IoT Approach for Monitoring Aqua Culture Using GSM Module N.RAJASHREE1, Y. SAI NITHISHA2, SHAIK SHAHEEN3, P. GOVARDHAN4 1, 2, 3, 4 Institutute of Aeronautical Engineering Abstract- Water deprivation has been more and more a day, creating unknown problems. The water quality control program techniques include a group of water tests from diverse sites. In the laboratory these water trials are tried using laborious skills. Those tactics are expensive and time overriding. The grown-up process of detecting water from old days developed into time overriding, poor accuracy and expensive. A low-cost water quality control system is intended to refer out the above problems. In this proposed method, different sensors monitor the water samples which contain pH, temperature and conductivity to communicate data via a microcontroller computer. Any of certain criteria can be fulfilled by this water quality program. And different technologies such form GSM (Global Mobile Communication System) can be used. A GSM digitizes, decreases the information and has a mobile communication modem

sanitation. In the area of water good research some studies were completed. Ibnu Salim Taufik et. Al. [1] al1rso suggested the usage of the Wireless Sensor Network (WSN), a compact and online water quality control device.

Indexed Terms- Internet of Things (IOT), GSM, Sensors, Quality, Arduino

IoT is used to constantly expose and monitor water use. wireless sensor nodes and is currently indicated for excess water usage and warning. In this article, SWMS for aqua culture is built with the intention of tackling all these real-life issues which have a significant effect on the wonderful life we live in. Section II is a comprehensive overview of our projected system beside with the flowchart

I.

INTRODUCTION

Water can be assumed to be one of life's most essential forces for survival. When it is revealed that water occupies 70 per cent of the earth's surface. Just 2 percent water is utilized, and another amount of water is new and discarded water. The population is raising day by day, with humans starting to experience water shortages and growing urbanization and industrialization, which often raises water consumption that is bad for intake. At Current, fresh water's attainability threatens the worldwide environmental shifts. With all these things in view, the highest concern of today's environment is water protection.

The paper offers a measurement device for checking and recording nice water in a large region utilizing the wi-fi sensor network and specializes in tracking and gathering reports from the sensor node, saving details in the record and showing actual-time and past documents. And Arjun K. Al. [2] has sent you a Water Temperature, Performance, and Leakage Detection framework for the usage of Internet of Things. Their planned gadget depends on sensors. This gadget tests the PH, temperature, conductivity and these calculated values into the microcontroller, and the alerts are sent to authorities largely depending on the specified thresholds. Yang Shuang-Hua et. Al.

Section IV indicates the various findings found on applying the unit, found by the usage of Section V on Assumptions and Potential Research which could be done on the built device. prescribed, although the various table text styles are provided. The formatter will need to create these components, incorporating the applicable criteria that follow.

When migration has been a major concern, it has also become difficult to preserve fresh water, and portable

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Š MAY 2020 | IRE Journals | Volume 3 Issue 11 | ISSN: 2456-8880 II.

EASE OF USE

A. Low-Cost System for Real Time Monitoring of Water Quality Parameters in IOT Environment Water is a life force and there are no lives on this earth world without oxygen. The water samples desires to be continuously pursued using smart expertise. Precise purification systems are presented for governing drinking water; however, the dangers in various types are mutual with the drinking water that comes from development, growth, culture, etc. To prevent contamination in the IoT setting, thus, the water quality must be checked at various sites in one line. The Internet of Things (IoT), because more of the infrastructure is linked to the internet, can revolutionize the water industry. Device-based filtered water pulses are a type of IoT, a system of technology that can track external objects location, collect relevant data and relay the data through a wireless network to a cloud computer-based software platform for review. Technologies may track items such as smart water pulses with other electrical instruments, animals or a normal aspect of the climate, such as a land region to be assessed for humidity or biochemical material. This paper talks about a low-price device that uses various sensors to test the water quality. IoT networks will endorse water quality data and can provide governing authorities with actionable information to measure enforcement by domestic, agricultural and other industry water consumers and water system stakeholders. The data should be the foundation for regulatory measures such that the water quality criteria in the IoT setting will be tracked in real time. B. Smart Water Monitoring System for Real-time water quality and usage monitoring This paper intends to develop a Smart Water Management System (SWMS) to track the consistency of the water in real time and the usage. It comprises in two parts: smart water measure meter and quality meter Smart Water. The aim of developing Smart Water Quantity Meter is to achieve conservation by measuring the volume of water used by a household and informing consumers and authorities of the same.

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A three-slab billing scheme produces bills of sale, based on the volume produced. The Water Efficiency device measures the consistency of mobile water provided by the user, by calculating five water variable qualitative criteria. The network guarantees that any environmental risks or possible dangers created by unintended waste or farm spill into the portable water are avoided. An electronic surveillance program shall have these details in realtime on the cloud. An electronic tracking program is to send these data in real time to the cloud. Any desecrations of any the consumption capacity or water eminence are automatically reported to the customer and authority through SMS and a system-caused warning signal. III.

THE MONITORING OF WATER QUALITY IN IOT ENVIRONMENT

Fresh liquid is perhaps an important and essential for all people today, and consumption water systems pose different obstacles in real-time service. This problem emerged due to the small increasing population of water supplies, aging facilities etc. Therefore, improved methodologies are required to track water quality Typical approaches of quality of the water include physical sampling of water samples at various sites, supplemented by experimental techniques to assess the nature of quality of the water. Those methods take longer and are no often seen as efficient [1]-[5]. While existing approaches examine human, chemical or biological substances, they have some disadvantages: a) temporal scope b) effort-intensive and heavy-price (employment, procedure; and machinery) c) absence of local-stint water health knowledge towards allow important public safety choices to be taken. Therefore, consistent digital monitoring of the water quality is required. Online water management systems have enabled substantial strides in the field of water supply control and service of water plants. The usage of their heavy-cost technology correlated with deploying and calibrating a broad variety of tracking sensors spread. The suggested method on the latest technologies will be ideal for a specific field and is not appropriate for large systems.

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© MAY 2020 | IRE Journals | Volume 3 Issue 11 | ISSN: 2456-8880 By concentrating from the above problems, our document model and designing a lower cost device to track the quality of water in IOT area in live time. A customized IOT unit is added to the model framework to connect visual data from central controller to server. Use a specific IP address the inertial sensors may be accessed in the cloud.

 Using assert-based encryption to build confidential data in cloud storage by deleting the description from the analysis to be viewed by the public sphere to the correct authority.

An IOT component also offers Wi-Fi aimed at accessing mobile data. Thus, remainder of this paper is structured as follows: The association with IOT as seen in section II. In Section III, displays the total current diagram and description in suggested process. The experiment performed and its subsequent findings obtained are included in Section IV. The summary of our proposed model is provided in Section V.

In our proposed phase Arduino is used as central controller. From the command line you can interpret the temperature sensor, conductivity sensor, turbidity sensor, dissolved oxygen sensor, Ph sensor directly. That requires us to enter a command when we want the sensors to read. Software to monitor all the sensor terminals. The Arduino deals with a range of drivers which connect. However, charging any driver when device boots are not possible, because that will raise the boot period significantly and require a considerable number of computer assets for repetitive operations. So, such drivers are processed as installable modules The IoT system sends information to the Internet and even to WIFI for mobile devices utilizing cloud storage

A. Abbreviations and Acronyms IOT-Internet of Things, GSM-Global System for Mobile Communication. IV.

PROBLEM DEFINITION

The inexpensive tool for actual-time control of water quality by calculating humidity, turbidity, ph, water conductivity leveraging and different detectors in IoT Setting and alerting their quality of water to the appropriate officials.  To perform bottom line survey for collection of water samples at various sites.  Conduct a systematic literature review to classify the scientific and technical gaps in the present scenario.  To test physico-chemical parameters of the water samples using background info.  Create an efficient sensor system designed to quantify physical chemical parameters such as pH, temperature, turbidity, conductivity, dissolved oxygen and total strength.  The data derived from the study will be analyzed using the framework of the core controller i.e. Script.  To transfer data to the cloud storage network through the sensor and the central controller device.

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V.

PROPOSED SYSTEM

Via the IoT module the sensor water control parameters are then sent to the gateway. The gateway is accountable for the data collection and the transmission of detecting data to the central server. A. Overall Structure The system's overall block diagram is related to the central controller in this proposed block diagram consisting of multiple sensors (temperature, Ph, turbidity, conductivity, dissolved oxygen). The central controller accesses and processes the sensor values to transfer the data over internet. Key controller is Arduino. You can display the sensor data on the internet using cloud computing.

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Š MAY 2020 | IRE Journals | Volume 3 Issue 11 | ISSN: 2456-8880 VI.

FUTURE SCOPE

For the future, the software will also be implemented on a broader scale, with the help of numerous available tools. For analyze more accurate and reliable data, other sensors can decide the water quality can be used. By incorporating this program into the workflow of state and central government, we will help government officials respond quickly and thus raise the standard of living in both rural and urban areas.

Fig 1: Architecture Diagram for Proposed System As presented in Figure: 1, it is evident that different components are provided in order to show the system to provide intended functionality. It has different operations involved. They include finding status of all nodes, choosing neighbour nodes, verifying network of moving nodes, find and list network and moving nodes and providing communication.

Since most of India's villages will not have Wireless sync, we may connect a Cellular GPRS device to our service to enable 3 G or 4 G channels to transmit data Adding more quality sensors capable of detecting certain chemical and physical parameters that affect water quality will make our system more effective and reliable. CONCLUSION During the transfer of information, it is delivered one by one, which creates a vibration and hastens the transfer. Nevertheless, data transmission must be concurrent, faster and more effective. Consequently, certain systems such as GSM (Global System for Mobile Communication) can be required to satisfy any of these specifications. Instead of using GSM community we can also use other technology, MQTT algorithm could be applied to render the system viable, modular, scalar and value-efficient, while flowing information exchange between detectors and databases simultaneously. Through dealing with any challenge, a major one. The idea may be applied on a greater scale in the possibility, with the help of varied availability of services. Other water-capture sensors of first class can be used to evaluate more sensitive and consistent data.

Fig2: Flowchart for Proposed System As shown in Figure 3.3.3, the flow chart is presented to know the functionalities of the proposed system with ease.

Possibility, with the help of varied availability of services. Other water-capture sensors of first class can be used to evaluate more sensitive and consistent data. REFERENCES [1] Pavana NR and Dr. M.C. Padma, "Low Cost Device Design for Real Time Monitoring of IOT Environmental Water Quality Parameters,"

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© MAY 2020 | IRE Journals | Volume 3 Issue 11 | ISSN: 2456-8880 International Journal of Applied Research in Computer Science and Technology Volume 4, issue 5, May 2016. [2] An. N. Prasad, K.A. Mamun, F.R. Islam, H. Haqva, "Control Device for Smart Water Quality," IEEE, 2015. [3] N Vijayakumar, R Ramya, International Conference on Circuit, Power and Computing Technology, IEEE, 2015. "The Real Time Monitoring of Water Quality in IOT System." [4] Young Hua Ling, Jiabin Tang, Qing Yang, Chao Zui, "IOT (Internet of Things) Wireless Communication," IBM Research. 17 December 2016, Downloaded.

Journal of Distributed Sensor Networks, Volume 2013 [12] Kedia, Nikhil. ”Water Quality Monitoring for Rural Areas- a Sensor Cloud Based Economical Project” 2015 1st International Conference on Next Generation Computing Technologies (NGCT), 2015, doi:10.1109/ngct.2015.7375081. [13] R.Karthik Kumar, M.Chandra Mohan, S.Vengateshapandiyan, M.Mathan Kumar, R.Eswaran. ”Solar based advanced water quality monitoring system using wireless sensor network” 2014, International Journal of Science, Engineering and Technology Research, 2014

[5] Wind River, "SECURITY IN THE INTERNET OF THINGS–Related Future lessons from the past" 2015. Retrieved Dec 17, 2016. [6] Model Spark,' 11 protocols of the Internet of Things (IOT) you must learn about. Accessed 10 Dec 2016. [7] Version 3.1.1 of OASIS –MQTT plus Errata 01. Accessed 7 November 2016. [8] Daudi S. Simbeye and Shi Feng Yang, “Water Quality Monitoring and Control for Aquaculture Based on Wireless Sensor Networks,” JOURNAL OF NETWORKS, VOL. 9, NO. 4, APRIL 2014. [9] Changhui Deng, YanpingGao, Jun Gu, Xinying Miao, “Research on the Growth Model of Aquaculture Organisms Based on Neural Network Expert System,” Sixth International Conference on Natural Computation (ICNC 2010) ; pg.no 18121815, SEPTEMBER 2010. [10] Pradeepkumar M, Monisha J. ”The Real Time Monitoring of Water Quality in IoT Environment” 2016 International Journal of Innovative Research in Science, Engineering and Technology, 2015 ISSN(Online) : 2319-8753 [11] Atif Alamri, Wasai Shadab Ansari, Mohammad Mehedi Hassan, M. Shamim Hossain, Abdulhameed Alelaiwi, and M.Anwar Hossain, ”A Survey on Sensor-Cloud: Architecture, Applications, and Approaches”, International

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