Smart Irrigation System Using IOT

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Smart Irrigation System Using IOT
Vishakha Khot1, Akanksha Sutar2, Snehal Pallakhe3,Vaishnavi Desai4
1,2,3,4Students, Department of Computer Science & Engineering, Sanjeevan Engineering and Technology Institute
Panhala (Maharashtra, India)
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Abstract - Because of the large population, human
requirements are also growing daily. The issues are growing
at the same time. Water scarcity is one of the most significant
issues, and it has an impact on agriculture. It consumesalotof
water. Consequently, a system that uses water in the required
amount efficiently is needed. An example of this kind of system
is a "SMART IRRIGATION SYSTEM."ItisbuiltontheInternetof
Things, or IOT. Both water and labour are saved by this
approach. According to the needs of the crops, water will be
delivered in this method. The soil moisture sensor will detect
moisture for this autonomous system, and the outcome will be
passed to the ESP8266 Wi-Fi.
Key Words: Wi-Fi Module, Soil Moisture Sensor,
Submersible Water Pump, Relay
INTRODUCTION
One of the industries that generates revenue forournation's
economy is agriculture. According to their motto,
"agriculture is life for more than 85%," the government has
increased funding for technology development to boost
agricultural output. In drylands, conserving water is the
most crucial issue. It is crucial for the survival of the plants
as well. We made the decision to attempt and increase the
effectiveness of water consumption in irrigation systems in
light of these facts in order to address a portion of the issue.
Recent technology advancements can improve or replace
traditional water distributionmethods.Weintendtouseitto
increase the effectiveness of water distribution, simplify the
process of managing irrigation, and offer simple
programming.
1.1 Problem Statement
Traditionally, humans carried out each stage. Nowadays,
some systems make use of technology to cut downonlabour
costs or plant-watering times. Such systems have extremely
limited control, and a lot of resources are still being
squandered. Water savings are not taken into account when
using standard irrigation systems. Because the water is
applied directly to the soil, plants are put under a lot of
stress by changes in soil moisture, which reduces plantlook.
There are currently rising global water crises, anditisnowa
significant responsibility to manage the scarcity of water.
Countries with a lack of water resources and weak
economies can observe this expansion. Therefore, this is a
significant issue for agriculture.
1.2 Objective
The key goal is to use the system to improve thesoil'shealth,
which will benefit the plant as a result. Recently, farmers
have come to rely on remotely controlled integrated
irrigation systems in order to save energy, time, and money.
2. Need of Smart Irrigation System
Compared to conventional irrigation systems, smart
irrigation systems have a number of benefits. By taking into
account factors like soil moisture, intelligent irrigation
systems can adjust water levels. Wireless moisture sensors
are used for this, which assist the systemdeterminewhether
or not the landscape requires watering by communicating
with the smart irrigation controls. Your landscape and
irrigation demands will be easier to manage thanks to the
smart irrigation system, and you'll also have peace of mind
knowing that it can make decisions on its own if you're not
there. Your smart irrigation system will optimize resources
so that everything gets what it needs without causing
unnecessary waste, which will result in significant savings
on your water bills.
3. Literature Survey
Alagupandi et al. (2014): propose a simpleand cost-effective
smart irrigation system. The system is modelled in an
outdoor environment using Tiny OS-based IRIS motes to
measure the moisture level of the paddy field. Moisture
sensors measure the soil moisture level. The system sets a
threshold value, and if the voltage exceeds that threshold,
then it represents the driest soil. The proposed system has a
better visualization and monitoring GUI. The motor
automatically switches on by pressing the button on the
visualization panel. AIS works with the help of the
MOTEWORKS visualization tool. The visualization tool
optimizes the use of water and fertilizer and maintains soil
moisture.
Vidadala et al. (2015): The implementation of agricultural
automation systems using WEB and GSM technologies. This
embedded project is todesignanddevelopa low-costsystem
that is based on an embedded platform for agricultural
automation. Optimum usage of wateristhemainobjectiveof
this system. This project uses soil moisture sensors and
temperature sensors to detect the water quantity present in
agriculture, and a water level sensor is used to detect the
water level in a tank. In this system, we monitor the statusof
International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 10 Issue: 07 | Jul 2023 www.irjet.net p-ISSN: 2395-0072

the sensors through Web and GSM technologies. Here,
temperature, soil moisture, and water level can be
monitored on a web page through a microcontroller, and
information will be sent by SMS. This page contains all the
information about the status ofthesensors.Thisinformation
will be viewed at a remote location using GPRS technology.
Rayala et al. (2016): found the system to be feasible and
cost-effective for optimizing water resources for agriculture
production. These systems can be adjusted to a variety of
crops and improve maintenance. This system is feasible for
all types of crops. We can use these systems for large-scale
greenhouses and open fields.
In short, in the existing system, we can only turn on and off
the motor through the GSM module or using Wi-Fi. They can
also get the current status of the field through GSM
technology.
4. Proposed System
The major goal of our "Smart Irrigation System," which we
proposed, is to lessen water wastage. It ispossibletousethis
technology for drip irrigation. The Android app is used to
deliver water to the field in a smart irrigation system. In the
Android app, we have the option to select a certain crop,and
the crop has already set a water level, or the amount of
water needed for that specific crop. As a result, the roots of
plants will only receive the necessary amount of water. The
motor will shut off whenever the water quantity reaches a
certain threshold, and the app will show the current state.
With the aid of this technology, the farm can supply water
without having to go there.
4.1. Smart Irrigation System
Fig 4.1: Smart Irrigation System
(Use an image from Google)In the block diagramabove,after
providing electricity, theESP8266Wi-Fimodulereceivesthe
instructions to turn on the motor via the app or manually
using a switch. A comprehensive and self-contained Wi-Fi
network solution that cantransportsoftwareprogrammesis
the ESP8266 Wi-Fi module. A relay will be used to turn on
the motor in accordance with the programme that was
burned into the Wi-Fi module. A relay is an electromagnetic
component that connects two electrically isolated circuits
magnetically.
The ESP8266 Wi-Fi module receives input from the soil
moisture sensor. The farm's moisture level was detected
using the soil moisture sensor. Once it reaches the soil, it
determines the amount of moisture there is.
4.2. Data Flow Diagram
Fig 4.2: Data Flow Diagram
(Use an image from Google)A data flow diagram (DFD)
models the process features of an information system by
graphically depicting the "flow" of data through it. A DFD is
frequently used as a first step to develop a system overview
without going into great depth that can then be developed.
DFDs can also be used forstructureddesign,whichvisualises
data processing. Data flows in Fig. 4.2 begin at the user
interface. The suggested system is linked to the user
interface. A request () is sent to the suggested system
whenever users provide instructions through the user
interface. The signal is sent to the motor in response to the
request, and the motor serves as an outputdevice.Analertis
given to the target to process the command.

4.3. Flowchart
Fig 4.3: Flowchart
(Use an image from Google)A diagrammatic illustration of a
solution model for a specific problem is shown in Figure 4.3.
In many different industries, flowcharts areusedforprocess
analysis, design, documentation, and programme
management.
In a flowchart, the two most frequent box kinds are: i) a
processing step, which is typically referred to as an activity
and is shown by a rectangular box; and ii) a choice, typically
represented by a diamond. The user needs configuretheWi-
Fi hotspot before the process can begin because it depends
on their connection. After username and password
configuration is complete, the user can usetheapptochoose
the necessary crop and start the engine. The user should try
again if the Wi-Fi hotspot generates an error due to
improper configuration.5. Details of Implementation
5.1. System Implementation
The Hardware and Software utilised in this project are
explained as follows:
5.1.1. Hardware Equipment
5.1.1.1 ESP8266 Wi-Fi module
5.1.1.2. Soil moisture Sensor
5.1.1.3. Relay
5.1.1.4. Submersible water pump.
5.1.1.1. ESP8266 Wi-Fi module
Fig.5.1.1.1:ESP8266 Wi-Fi module
(An image from Google)The ESP8266 is a comprehensive
and self-contained Wi-Fi network solution that can run
software applications or disable all Wi-Fi networking
features using a different application processor. When the
device is mounted, the flash memory can be started straight
from an external Move and is the only application of the
application processor. System performance will be
enhanced, and memory requirements will be decreased,
thanks to built-in cache memory. Another instanceiswhena
Wi-Fi adaptor performs the function of wireless internet
access. Any microcontroller-based designcanincorporateit,
and connecting to it is straightforward using an SPI/SDIO
interface or a central processor AHB bridge interface. GPIO
ports, sensors, and other application-specific hardware
enable the ESP8266's powerful component to incorporate
processing and storage capability.
5.1.1.2. Soil Moisture Sensor
Fig.5.1.1.2: Soil Moisture Sensor
(An image from Google)The soil's wetness can be measured
using this sensor. The output of the module is high when
there is a water scarcity in the soil; otherwise, it is low. One
can automatically water the flower plant or any other plant
that needs automatic watering by utilising this sensor.
Modules have three different output modes: simple digital
output, accurate analogue output, and precise serial output.

5.1.1.3. Relay
Fig.5.1.1.3: Relay
A relay is an electromagnetic switch that can turn on or off a
considerably greater electric current and is driven by a
relatively modest electric current. An electromagnet, which
is a coil of wire that turns into a temporary magnet when
electricity passes through it, is the brain of a relay. Relaysfill
in the space, allowing smaller currents to activate bigger
ones. As a result, relays have two different functions:
switches (which turn things on and off) and amplifiers
(which increase small currents). (An image from Google)
5.1.1.4. Submersible Water Pump
Fig.5.1.1.4: Submersible water pump
An electric submersible pump (or subs pump, for short) is a
machine with a hermetically sealed motor that is tightly
attached to the pump body (see figure d). The entire
assembly is dipped in the liquid that has to be pumped. This
type of pump's primary benefit is that it avoids pump
cavitation, a problem brought on by a significant elevation
difference between the pump andthefluidsurface.Unlikejet
pumps, which must drag fluids, small DC submersible water
pumps push fluids to the surface. Jet pumpsarelesseffective
than submersibles. It typically runs on voltages between 3
and 12.
5.1.2. Software Equipment
1. Arduino IDE
2. Blynk app
5.1.3. Application of project
• Depending on the crop and kind of soil, the system
must be able to control every last drop and
determine the actual amount of water needed. This
is a highly useful feature that enables waste-free
water conservation.
• Both small and large fields can be used with this
technique.
• A trustworthy and effective method for monitoring
environmental parameters;
• Easy and convenient garden maintenance.
6. Future Scope
In the future, a wireless component like a wireless soil
moisture sensor can take the place of a wired network. RFID
technology can also be used to create wireless systems. At
each phase, we can add an electric solenoid valve thatcanbe
automatically controlled by an Arduino board or by an
ESP8266 Wi-Fi module.
7. Conclusion
With the help of a soil moisture sensor and a Esp8266 Wi-Fi
module, the "Smart Irrigation System" project optimises the
use of water in agricultural fields without the need for
human intervention from farmers. The motor is turned on
and off in accordance with commands from an Android app.
Only the necessary amount of water is providedtoeachcrop
in this method, and the Android app displays the field's
present condition.
References
[1]Smart irrigation system survey in the International
Journal of Engineering Sciences and Research Technology
(IJESRT) Dr. P.H. ZopeandH.N.KamalaskarISSN:2277-9655
[2]Sensor Based Automated Irrigation System With IoT: A
Technical Review by Karan Kanasura, Vijal Zaveri, Babu
Madhav Institute of Technology, Uka Tasadia University,
Bardoli, and Gujarat, India.
[3]Automatic Irrigation BasedonSoil MoistureforVegetable
Crops, Rafael Muoz-Carpena and Michael D. Dukes, IFAS
Extension, 2005.
[4] VeenaDivya K. IACSIT1, 2, 3, and 5 member. a real-time
implementation of a drip irrigation methodology-based
automated irrigationcontrol system.Instrument Technology
Department, R. V. College of Engineering, Bengaluru,
Karnataka. 2013; 4(5). ISSN: 2229-5518
[5]R. Suresh, S. Gopinath, K. Govindaraju, T. Devika, and N.
Suthanthira Vanitha, "GSM based Automated Irrigation
Control Using Raingun Irrigation System," International
Journal of Advanced Research in Computer and
Communication Engineering, Volume 3, Issue 2, February
2014.

Smart Irrigation System Using IOT

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