Smart Poly-House Surveillance using IOE
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This document proposes a smart poly-house surveillance system using the Internet of Things. The system uses sensors like a soil moisture sensor, temperature sensor, and light sensor attached to a Raspberry Pi controller. These sensors collect data on soil moisture levels, temperature, and light intensity. The Raspberry Pi analyzes the sensor data and sends it to a server using WiFi. An Android application allows farmers to monitor the sensor data in real-time and control an irrigation motor if soil moisture levels drop below a threshold. The system aims to automate poly-house monitoring and irrigation to reduce farmer workloads and ensure optimal growing conditions. Camera images of the poly-house are also sent periodically to the server and smartphone for remote surveillance.
![International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395 -0056
Volume: 04 Issue: 03 | Mar -2017 www.irjet.net p-ISSN: 2395-0072
© 2017, IRJET | Impact Factor value: 5.181 | ISO 9001:2008 Certified Journal | Page 2786
6) Android application:-
We develop anandroidapplicationforthefarmer.In
these application all the data isprovidedtofarmerwhichcan
be seen by anywhere. Also farmer can control the soil
moisture by using motor if the value of moisture in soil is
below threshold value. These application also shows the
surveillance images to farmer.
3. CONCLUSIONS
Precision agriculture is a comprehensive system
designed to optimize agriculture production. Using the
technology human work will be reduced. These agriculture
increases production efficiency, improve product quality,
improve the efficiency of crop, conserve energy, and protect
the environment. In a playhouse environment using IOE our
test shows clearly that automatic irrigation is more efficient
compared to manual irrigation. Automatic irrigation will
control the usage of water and maintain the moisture level
and healthiness of the plant. Also the surveillance to the
farmer is provided.
REFERENCES
[1] Jackson T, Mansfield K, Saafi M, etal. “Measuring soil
temperature and moisture using wireless MEMS
sensors”, Journal ofMeasurement,41(4):381-390,2007.
M. Young, The Technical Writer’s Handbook. Mill Valley,
CA: University Science, 1989.
[2] Soil moisture monitoringstandards[S] SL000-2005.The
People's Republic of China Ministry of Water Resources
,2005-00 -00 promulgated, China Water Power Press
Publishing ,2007-6-1.
[3] Adams, M.L., Cook, S. & Corner, R. , “Managing
Uncertainty in Site-Specific Management: What is the
Best Model?” Precision Agriculture. 2, 39-54, 2000
[4] J. Burrell et al. Vineyard computing: sensor networks in
agricultural production. IEEE Pervasive Computing,
3(1):38–45, Jan-Mar 2004.
[5] W. Zhang, G. Kantor, and S. Singh Integrated wireless
sensor/actuator networks in agricultural applications.
In Second ACM International Conference on Embedded
Networked Sensor
Systems (SenSys), page 317, Baltimore, Maryland, USA,
Nov. 2004.
[6] J. Thelen et al. Radio wave propagation in potato fields.
In First workshop on Wireless Network Measurements
(located with WiOpt 2005), Riva del Garda, Italy, Apr.
2005.
[7] V.I. Adamchuk, J.W. Hummel, M.T. Morgan and S.K.
Upadhyaya, “On the-go soil sensors for precision
agriculture”, Computers and Electronics in Agriculture,
44, 71–91, 2004.](https://image.slidesharecdn.com/irjet-v4i3703-180109072301/85/Smart-Poly-House-Surveillance-using-IOE-3-320.jpg)
Smart Poly-House Surveillance using IOE
- 1. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395 -0056 Volume: 04 Issue: 03 | Mar -2017 www.irjet.net p-ISSN: 2395-0072 © 2017, IRJET | Impact Factor value: 5.181 | ISO 9001:2008 Certified Journal | Page 2784 Smart Poly-House Surveillance Using IOE Vaibhav Sherkar1, Akshay Surwase2, Prasad Kalekar3, Bhagyashree Gavhane4 1, 2, 3 Student, Dept. of ENTC Engineering, Dr.D.Y.Patil college of engineering Ambi, Maharashtra, India 4 Professor, Dept. of ENTC Engineering, Dr.D.Y.Patil College of engineering Ambi, Maharashtra, India ---------------------------------------------------------------------***--------------------------------------------------------------------- Abstract - The required climate condition for the green house can be provided by proposed system. With the machine- controlled of playhouse human intervention will be reduced. Agriculture requires irrigation at the time of drought as well as some plants require a lot of water which is not sufficiently provided by the rain water. Farmer needs to continuously monitor the soil moisture andwaterlevel. Sometimesfarmeris far away from farm or gets some health problem, the plants may spoil due to less water irrigation. Key Words: IOT, Poly-house, WSN, Raspberry pi 1. INTRODUCTION Embedded Ethernet is used for supervise and moderation of the physical parameters in any domain such as industrial, commercial, home, agricultural etc. we can see there are various problems in monitoring the parameters in the irrigational plant such as moistureofthe soil,temperature of the soil. Now a day’s various problems are rising in polyhouse superintendence. We required lots of man power for maintenance of polyhouse. We can use Embedded Ethernet for home automation based applications for controlling the various components such as lights, fans, ACs, etc. To deal with these daily and toilful problems,wedecided to launch this project which will satisfy the above discussed problems. By using such type of system we can control and monitorthe parameter through your mobile phones or by your personal computers. And also by moderating the home appliance we can spare the energy by knowing the current status of the appliance and in polyhouse surveillance we can check the status of the motor and control it by relays. The internet of things (IOT) is an important topic in technology industry and engineering circle the large scale implementation of IOT devices promises to transform many aspects of the we live. IOT is expected to offer advanced connectivity devices systems & services that goes beyond machine to machine communication and covers variety of protocols. In the polyhouse to ease the work of farmer this system used. In this system the soil moisture sensor, light intensity sensor and temperature sensor gives the data to the controller unit on particular defined time in the form of images. The data analysed by controller is send to theserver with the help of Wi-Fi module. The android app is designed for this system which is load in smart phoneandwhichtakes sensors data time to time. We shows the graphical data of this sensors, so it becomes easy to analyse. Also we can on and OFF the motor according to the soil moisture. We gives some threshold value for the controlling motorbasedonsoil moisture. The relay used for the controlling Light (Bulb), which takes data from LDR sensor and measure light intensity and then control the bulb using relay. The farmer can also control the motor and bulb from his smart phone using android App. The camera is used to take the photos of fields capture randomly in small period and send it to server at some interval of times. Then farmer checks it at his smart phone. The LDR (Light Dependent Resistor) sensor is used to sense the intensity of light and according to the light intensity the bulb will ON & OFF. An Android provides access to the end devices for Farmer uploading web pages as per the client request. In polyhouse too ease the work of farmer this method is used. In this system the soil moisture sensor, light intensity sensor and temperature sensor gives the data to the controller unit in particular defined time. The controller analysed data and send to the server with the help of Wi-Fi module. The android app is designed for this system which is load in smart phone and which takes sensors data time to time. We shows the graphical data of this sensors, so it becomes easy to analyse. Also we can ON and OFF the motor according to the soil moisture. We gives some threshold value for the controlling motor based on soil moisture. The relay used for the controlling Light (Bulb), which takes data from LDR sensor and measure light intensity and then control thebulb using relay. The farmer can also control the motor and bulb from his smart phone using android App. 2. SYSTEM ARCHITECTURE In our system we use the raspberry pi3 as main processor. It has the high capacity of processing. Camera port is also provided to it. We use different sensorslike moisturesensor, temperature sensor. Motor is also attached to it for controlling water for a plants. System architecture provides the overview of the system and components present in the system. Using this sensors we can control and monitor various conditionsacquire in poly-house. Surveillanceisalso possible using these systems.
- 2. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395 -0056 Volume: 04 Issue: 03 | Mar -2017 www.irjet.net p-ISSN: 2395-0072 © 2017, IRJET | Impact Factor value: 5.181 | ISO 9001:2008 Certified Journal | Page 2785 Fig -1: Proposed System Fig -2: Flowchart 1) Raspberry 3 Raspberry pi 3 provides 6 time processing capacity of than raspberry pi 2. It also has a high memory capacity. Also we can expand memory by using external memorycard Raspberry pi 3 has separate port to attach camera. Features: SoC : Broadcom BCM2837 CPU : 4× ARM Cortex-A53, 1.2GHz GPU : Broadcom Video Core IV RAM : 1GB LPDDR2 (900 MHz) Networking: 10/100 Ethernet, 2.4GHz 802.11n wireless Bluetooth : Bluetooth 4.1 Classic, Bluetooth Low Energy Storage : micro SD GPIO : 40-pin header, populated Ports : HDMI, 3.5mm analogue audio-video jack 2) Power supply:- All electronicscomponent required electrical energy for their working. Basically we have to convert main power supply from 230v to 12v & 5v respectively for the raspberry pi, motor drivers & other components 3) Sensors:- A) Soil Moisture Sensor:- The moisture sensor uses immersion gold which protect nickel from oxidation. This sensor reads the moisture sensor in a soil and judge a water level .It is two port device. Features: 1 .Work up to 5v 2 .Working current is less than 20 mA 3 .High sensitivity B) Temperature sensor:- It is an integrated circuit which gives linear output in degree. Features: 1 .Operating voltage 4-30 volt 2 .Current drain 50 micro amp. 3 .Junction temperature 150 degree Celsius C) Light Dependent Resistor:- It contains two cadmium sulphide cells. The cell resistance falls with increasing temperature. Features:- 1 .Power dissipation 100mW 2 .cell resistance 400ohm 4) Motor:- Relay is used for control a motor. Whenever water level in a soil is decreases belowgiventhresholdvaluemotor will be automatically ON by the motor driver circuit. We can also control it by manually. 5) Camera:- Camera is used for capturing images of a playhouse for certain fixed time duration. These images are send to the farmer.
- 3. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395 -0056 Volume: 04 Issue: 03 | Mar -2017 www.irjet.net p-ISSN: 2395-0072 © 2017, IRJET | Impact Factor value: 5.181 | ISO 9001:2008 Certified Journal | Page 2786 6) Android application:- We develop anandroidapplicationforthefarmer.In these application all the data isprovidedtofarmerwhichcan be seen by anywhere. Also farmer can control the soil moisture by using motor if the value of moisture in soil is below threshold value. These application also shows the surveillance images to farmer. 3. CONCLUSIONS Precision agriculture is a comprehensive system designed to optimize agriculture production. Using the technology human work will be reduced. These agriculture increases production efficiency, improve product quality, improve the efficiency of crop, conserve energy, and protect the environment. In a playhouse environment using IOE our test shows clearly that automatic irrigation is more efficient compared to manual irrigation. Automatic irrigation will control the usage of water and maintain the moisture level and healthiness of the plant. Also the surveillance to the farmer is provided. REFERENCES [1] Jackson T, Mansfield K, Saafi M, etal. “Measuring soil temperature and moisture using wireless MEMS sensors”, Journal ofMeasurement,41(4):381-390,2007. M. Young, The Technical Writer’s Handbook. Mill Valley, CA: University Science, 1989. [2] Soil moisture monitoringstandards[S] SL000-2005.The People's Republic of China Ministry of Water Resources ,2005-00 -00 promulgated, China Water Power Press Publishing ,2007-6-1. [3] Adams, M.L., Cook, S. & Corner, R. , “Managing Uncertainty in Site-Specific Management: What is the Best Model?” Precision Agriculture. 2, 39-54, 2000 [4] J. Burrell et al. Vineyard computing: sensor networks in agricultural production. IEEE Pervasive Computing, 3(1):38–45, Jan-Mar 2004. [5] W. Zhang, G. Kantor, and S. Singh Integrated wireless sensor/actuator networks in agricultural applications. In Second ACM International Conference on Embedded Networked Sensor Systems (SenSys), page 317, Baltimore, Maryland, USA, Nov. 2004. [6] J. Thelen et al. Radio wave propagation in potato fields. In First workshop on Wireless Network Measurements (located with WiOpt 2005), Riva del Garda, Italy, Apr. 2005. [7] V.I. Adamchuk, J.W. Hummel, M.T. Morgan and S.K. Upadhyaya, “On the-go soil sensors for precision agriculture”, Computers and Electronics in Agriculture, 44, 71–91, 2004.