Design and Implementation of Eco Green System for Plant
Monitoring Based Internet of Things
Legowo Sulistijono and Junia Maulidya Nata
Politeknik Elektronika Negeri Surabaya, Indonesia
Keyword: Internet of Things, Singlehop Communication, Eco Green.
Abstract: Indonesia is an agrarian country where most of the population lives as farmers, but currently, farmers are still
using conventional methods that are not able to increase their agricultural output. In addition, many problems
occur in agriculture, such as changes in weather conditions, lack of labor, dry land, irregular irrigation
processes, and so on. In the process of watering plants, special attention is needed, because if there is an
excess of water or a lack of water, the quality of the harvest will be less than optimal. Thus, an Eco Green
System was created with automatic watering and fertilization features. There is also monitoring to monitor
the condition of agricultural land. Both from soil moisture and temperature in the land. This is a way to save
time and energy. The application of a communication system with the Singlehop Communication method is
an effective way of monitoring the automatic plant watering process because it uses calculations that have
been adjusted to the level of soil demand. By using a capacitive soil moisture sensor V1.2 and a temperature
sensor DHT 11, it will be able to read data on the land. To get real-time data, and Internet of Things system
is needed to connect to the internet and communicate with each other. The results of the temporary test show
that the error value between the sensor and measuring instrument is around 0-6%, while the communication
system is running well and can read the humidity value at each node.
1 INTRODUCTION
Indonesia is an agricultural country that has extensive
agricultural land, and diverse and abundant natural
resources. In an agrarian country, agriculture has a
very important role both in the fulfillment of basic
needs, besides that agriculture plays a major role in
boosting the social sector, economic sector, and trade.
In addition to the large natural potential that
Indonesia has, there are other reasons, namely the
agricultural sector is still the leader of the Indonesian
economic sector and most of the population still
works in the agricultural sector, but there are still
various problems that make the Indonesian
agricultural sector seem to be running in place and not
experiencing rapid development such as other
agricultural countries. Such as the agricultural system
which still uses conventional systems, where the
system has many weaknesses such as technological
limitations, depending on the process and yields on
the season, only involving family labor, limited
availability of scarce fertilizers, and the most
important thing is the process of watering and
fertilizing which is still lacking. well scheduled.
In addition, current technological advances will
also have a major impact, especially on the
agricultural sector. By connecting automatic
monitoring, watering, and fertilization system that is
connected to the internet network, it is hoped that it
can solve problems in the environment of the farmers
and produce good quality products. In addition, it can
also minimize crop failures caused by weather
factors. By utilizing the internet of things for
agricultural technology, this step is very appropriate
to monitor and control crop conditions to produce
better products and avoid crop failure (F. Tongke
2013), (Norakmar 2019). he internet of things makes
observing or monitoring plants easier and more
efficient to increase the productivity of crops and
benefit the farmers. (D. D. Sreekantha and A. Kayva
2017).
2 SYSTEM OVERVIEW
Eco Green is one of the concepts of material
management and production that is strived to always
Sulistijono, L. and Nata, J.
Design and Implementation of Eco Green System for Plant Monitoring Based Internet of Things.
DOI: 10.5220/0011884600003575
In Proceedings of the 5th International Conference on Applied Science and Technology on Engineering Science (iCAST-ES 2022), pages 787-793
ISBN: 978-989-758-619-4; ISSN: 2975-8246
Copyright © 2023 by SCITEPRESS – Science and Technology Publications, Lda. Under CC license (CC BY-NC-ND 4.0)
787
Figure 1: Basic overview of eco green.
be environmentally friendly which is suitable for
farmers. Eco green is closely related to plants where
plants are living things that need water and fertilizer
for the development of their lives. This Eco Green
concept can be applied in life by combining livestock
and agriculture so that a good ecosystem occurs. In
addition, the energy used is obtained from solar
panels so that it will be more environmentally
friendly.
In Figure 1 above, every farm must have waste,
namely the results of the livestock manure, where the
results of the waste can be used for agriculture as
fertilizer which is commonly referred to as manure.
So that when agriculture is given fertilizer, the plants
planted will become fertile and will increase crop
yields because one of the factors causing increased
crop yields is fertilization. In addition, checking soil
conditions is also very important for plant growth
which must have optimal humidity between 60%-
80% so that it is not too dry or wet (J. Ristaino 2010).
The agricultural land used is peanut farming land,
this is because peanuts are one of the plants that can
build a good eco-green because apart from the leaves
being used for animal feed, the peanuts can also be
used for the benefit of the farmers, besides that
peanuts are also easy to use. planted and has many
benefits for society.
This system will use Wireless Sensor Network
(WSN) communication. WSN is a system where one
node to another can make contact and exchange data.
(Y. Nishikawa 2018), (M. Walid et al., 2019), (A. S.
Editya 2017).
Based on Figure 2, there is a master note that
controls all systems. When the master note asks for
the monitoring value, the system will read the sensor
data and send the data to the master node.
Figure 2: Flowchart of system monitoring.
3 EXPERIMENTAL RESULT
3.1 System Design
Figure 3: System diagram.
Based on the block diagram in Figure 3, there is a
system that will be created, namely the Main System
installed on the tool. The Main System consists of an
ESP32 microcontroller as a microcontroller that
functions to control all systems. Several inputs will be
processed later, namely the Soil Moisture sensor
which functions to detect moisture levels in the soil
for the watering process and there is also a Real-Time
Clock (RTC) which functions to set the timer in the
fertilization process and there is an ESP32 Cam
Camera Module which functions for monitoring
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plants. All of these inputs will be processed on the
ESP 32 microcontroller which is commonly referred
to as a server node.
The data that has been processed on the server
node will be sent to the master-slave using the wifi
access point contained in the ESP32 feature. Data
from the node will be sent to the master-slave which
also uses the ESP32 microcontroller. This master-
slave serves as a central control for incoming data
from all server nodes. Both node 1, node 2, node 3,
and node 4 will all be processed on the master-slave.
This master-slave also functions as the central control
of all settings, both the watering process and the
fertilization process. To be able to connect to android,
this master-slave sends data to the web server using
firebase.
Figure 4: Flowchart system.
Based on the data in Figure 3 which describes the
workings of the whole system, this system uses two
pumps, namely for watering and for fertilizing.
Fertilization is done by using liquid fertilizer. When
the sensor reads soil moisture data, the data obtained
will be processed whether the data is by the specified
set points. The set point here is determined with a
range of 1 to 100. When the soil moisture is more than
60% of the maximum range, the watering process will
take place, so the water pump will turn on. The sensor
will always work until when it exceeds the set point
or is below 60% of the data, the watering will stop,
this indicates that the soil is already moist and there
is no need for watering, so the water pump will turn
off. This condition will be the same between node 1
to node 4. For the way the fertilization process works,
it can be set using the Real-Time Clock because the
fertilization process is carried out routinely and
simultaneously so it is only necessary to set the timer
value on the RTC. When the RTC value matches the
input, the fertilization process will take place and the
fertilization pump will turn on so that fertilization is
active. This can be adjusted to the conditions of the
agricultural land used. When the delay in fertilization
time is over, the pump will automatically shut down
and the fertilization process is complete.
3.2 Singlehop Communication
Wireless Sensor Networks (WSN) are a very popular
technology in this decade. WSN is a system where
one node to another can make contact and exchange
data. In addition, WSN is a cheap, fast, and quality
data transmission technology without the cost and
mess of cables. WSN can be used in many fields,
including use in smart homes, tracking systems,
agriculture, the military, the environment, and many
more. One of the most important of these is the
implementation in the environment (A. S. Editya
2017). The wireless sensor network has the following
characteristics:
1. Limited manpower resources. WSN does not
have a continuous power source. WSN power
can be obtained with batteries and adapters,
but it should be noted that WSN has a
maximum limit of 3.3V. 14
2. The ability to survive in an environment that
has conditions that tend to change such as
temperature, rainfall, humidity, light intensity,
and so on.
3. Ability to resolve errors on the node
(decentralized management). This is
necessary because the nodes used by WSN
will be outside the scope of user control, so the
ability to automatically resolve errors is vital.
4. Node mobility, the nodes used in the WSN can
be placed anywhere as long as they are within
the range of the WSN. Nodes are not related to
the position, so they can be moved even when
they are working.
5. Dynamic network topology, WSN does not
have certain limitations or criteria in designing
its topology. The topology can be designed
according to the wishes and goals intended by
the user.
6. Large-scale deployment, WSN can be used for
monitoring a very large area and for various
purposes.
In its development, wireless sensors have been
developed with several network topologies such as:
Design and Implementation of Eco Green System for Plant Monitoring Based Internet of Things
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1. Topologi jaringan Single Hop Star.
2. Topologi jaringan Multi Hop Mesh dan Grid.
3. Topologi jaringan Two Tier Hierarchical
Cluster.
Figure 5: Single hop star topology.
Single hop star is a very simple WSN topology
technology. In this topology, each node leads directly
to the gateway or data collector. (M. Walid et al.,
2019). Because this topology is centered on a minimal
and simple network. This topology is very easy to
implement. However, in this topological design, the
biggest problem is the limitation on scalability
problems. Nodes far from the Gateway will have poor
connections. This topology is good for use on WSN
networks that have fewer nodes and a small area (J.
M. Nassar et al., 2018).
With the technology that is growing agriculture
will also be able to see other sectors, namely the
existence of a land management system in a modern
way that can be used using modern systems and not
using conventional methods. The soil management
system in the form of a watering system and plant
fertilization automatically uses a soil moisture sensor
as a soil moisture detector, and a microcontroller as a
program brain, while Android is used to receive soil
moisture results based on soil pH that is already by
plant needs, this tool is also equipped with a timer as
a timer. clock and date on the tool for the periodic
fertilization process, as for the relay as a water pump
Figure 6: Node design.
controller, the internet as a data receiver from
Arduino according to the program that has been set
on Arduino whether the soil moisture is moist or wet
according to reading from the soil moisture sensor in
the form of the value on Android.
Figure 7: Master design.
In the picture above are the components contained
in the master such as a 12V 5A power supply as the
main source to activate other components such as
pumps, RTC, and relays. Pump 1 acts as a tool to suck
water and will flow it to the solenoid valve from each
node that needs it. While pump 2 serves to drain
liquid fertilizer in the fertilization process. ESP 32
master as the main microcontroller from the master
which will receive data from other nodes. LCD 20 X
4 as a display of several values to be displayed such
as pump on/off conditions and soil moisture content
of each node. In the picture above are the components
contained in the master such as the 12V 5A power
supply as the main source to activate other
components such as pumps, RTCs, and relays. Pump
1 acts as a tool to suck water and will flow it to the
solenoid valve from each node that needs it. While
pump 2 serves to drain liquid fertilizer in the
fertilization process. ESP 32 master as the main
microcontroller from the master which will receive
data from other nodes. LCD 20 X 4 as a display of
several values to be displayed such as the condition
of the pump on/off and the soil moisture content of
each node.
3.3 Internet of Things
From the overall design above that, each node is
connected to the master and the master will be
connected to the access point with the ESP32 Cam
camera module where all data will be stored in the
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Figure 8: System design.
cloud and the data will be sent to android. So that
monitoring can be done easily and efficiently on
Android.
The ultrasonic sensor data acquisition software
uses programming to convert the echo signal into
digital data and send it to a personal computer via
serial communication. The data that has been
received by the personal computer will then be
displayed or plotted using graphics in the
software.Web Server (Firebase)
In this smartphone monitoring, data can be
monitored such as the state of each node, besides that
it is also programmed to be able to display camera
time settings obtained from the camera module for
fertilization which can be set on the smartphone. In
addition, it can also display the camera view obtained
from the camera module for fertilization that can be
set on a smartphone. In addition, it can also display
the camera view obtained from the camera module.
Figure 9: Firebase web server.
By using firebase as a web server, you will be able
to monitor the condition of each node. This condition
contains the level of soil moisture in each node. Data
from the web server will also be monitored using a
smartphone from the android studio software.Aplikasi
Monitoring
Figure 10: Monitoring application.
In this smartphone monitoring, data can be
monitored such as the state of each node, besides that
it is also programmed to be able to display camera
time settings obtained from the camera module for
fertilization which can be set on the smartphone. In
addition, it can also display the camera view obtained
from the camera module for fertilization that can be
set on a smartphone. In addition, it can also display
the camera view obtained from the camera module
Figure 11: Fertilization application settings.
Figures 12: Sensor testing with analog measuring devices.
Design and Implementation of Eco Green System for Plant Monitoring Based Internet of Things
791
Figures 13: DHT11 Sensor Testing with the digital
measuring instrument.
Table 1: Result from soil moisture test.
No. Soil moisture value ADC
1. 0.2 460
2. 1 438
3. 1.5 420
4. 3 372
5. 4.9 327
6. 5 313
7. 6 286
8. 6.5 272
9. 7 248
10. 0.2 460
Table 2: Digital measuring tool table list.
No. Parameter Sensor
Digital
measurin
g
tool
Error
1. Humidit
y
79 84 5.95%
2. Temperature 31.5 29.9 5.35%
Table 3: Pump test.
Node Relay 1 Relay 2 Relay 3 Relay 4
watering
rela
y
fertilization
rela
y
1 Active
Not
Active
Not
Active
Not
Active
Active Not Active
2
Not
Active
Active
Not
Active
Not
Active
Active Not Active
3
Not
Active
Not
Active
Active
Not
Active
Active Not Active
4
Not
Active
Not
Active
Not
Active
Active Active Not Active
This test is done by testing the watering and
fertilizing pump. This test will be triggered from the
relay which is for the watering pump. When one of
the 4 relays in each node is active, the watering pump
will be active and the fertilization pump will be
deactivated. On the other hand, when the time setting
schedule is appropriate, the fertilization pump will
turn on with a trigger from the relay, and the
fertilization pump will be active while the watering
pump will not be active.
Table 4: Soil Test.
Watering Conditions
Node
soil
condition
Valve 1 Valve 2 Valve 3 Valve 4
Node
1
Dry Active
Not
Active
Not
Active
Not
Active
Node
2
Dry
Not
Active
Active
Not
Active
Not
Active
Node
3
Dry
Not
Active
Not
Active
Active
Not
Active
Node
4
Dry
Not
Active
Not
Active
Not
Active
Active
Conditions during Fertilization
Node Dry Active Active Active Active
In this test, it is done with a relay, when the relay
is active, the solenoid will also be active, so the way
it works is almost the same as relay testing. When the
relay is active, the solenoid is active and will turn on
the pump. For the watering process using the input
from the sensor value and for fertilization with a
predetermined time setting value.
Figures 14: Whole system test.
Table 5: Watering System Test.
No. Node Humidity
Relay Valve
Watering
p
um
p
1. Node 1 72
Active Active Active
2. Node 2 34
Not
Active
Not
Active
Not Aktif
3. Node 3 69
Active Active Active
4. Node 4 10
Not
Active
Not
Active
Not Aktif
From the overall test results, it is found that the
value of each node will be different. As in the table
above. When the value is below the specified set
point, which is 60% of the humidity, then watering
will be active in the node that detects less humidity.
In this test, the active watering nodes are node 1 and
node 3. So that the relay from node 3 and node 1 will
activate the solenoid and the pump will drain the
water.
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Table 6: Fertilization System Testing.
No. Node Humidity Relay Valve
fertilization
p
ump
1. Node 1 42 Active Active Active
2. Node 2 43 Active Active Active
3. Node 3 40 Active Active Active
4. Node 4 10 Active Active Active
In the results of the data above that the value of
each node is different. Node 1 is 42, node 2 is 43, and
node 3 is 40, while node 4 is 1. From these 4 nodes,
automatic watering will be carried out. Which
watering is based on input from a predetermined time
setting? So that when the time is by the specified
setting then fertilization will be active for 1 minute
then it will automatically turn off the pump.
4 CONCLUSION
After carrying out the design and manufacture stage
of the system which is then followed by the testing
and analysis stage, it can be concluded that the soil
moisture sensor works well according to how it
works, this is evidenced by the error comparison
value with measuring instruments that have a fairly
small error, the more moist the soil quality then the
value of the ADC that is read will be smaller, the drier
the value of soil quality, the value of the ADC that
will be read will be greater, the measurement results
of this tool have an error range of 0-6% and the
system can work well there are only a few errors due
to the internet network.
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