Fire Detection System in Peatland Area Using LoRa WAN
Communication
Evizal Abdul Kadir
1
, Hitoshi Irie
2
, and Sri Listia Rosa
1
1
Department of Informatics Engineering, Universitas Islam Riau, Pekanbaru, Indonesia
2
Center for Environmental Remote Sensing (CEReS) Chiba University Chiba, Japan
Keywords:
Smart Sensor Node, WSNs, Pollution, River Water.
Abstract:
Land and forest fires are one of the threats in a tropical country, especially in Indonesia with forestry land and
additional caused of type of land which peatland that easy to getting fire in the summer season. Currently,
many techniques to detect fire hotspot and land fire but some of the technique can not apply in peatland case.
This research proposes a new technique that can be applied to this case in Riau province, Indonesia which the
land with peat type. Long Range Wide Area Network (LoRa WAN) used in the detection land and forest fire,
with advantages of low power and long-range transmission in LoRA WAN very applicable in this detection
of fire with the distance of fore hotspot very far and large of an area. The simulation result shows good
performance and verification used mathematical modeling to check that the system is working and application
to implement. The sensors deployed in the area which indicate for a forest fire in the simulated distance to
detect the potential of fire then the information sent to the monitoring system in the data center. The proposed
LoRa WAN method gives good response and recommended to implement in the peatland area which located
in Riau Province, Indonesia.
1 INTRODUCTION
The significant emerging and development of tech-
nology in wireless network has expressively changed
and enhance the natural environment control system
compared to current methods that use satellite ground
detection methods, such as wireless sensor networks.
thread (WSN) (Khajuria and Gupta, 2015). This sys-
tem can provide new data for environmental and po-
tentially fatal warning applications such as land and
forest research and flood detection. The benefits of
ground level detection can be divided into three as-
pects (Chee-Yee and Kumar, 2003; Boubiche et al.,
2018; Jie et al., 2015).
Sensor button; low cost, low power, strong, low
pollution and environmental disturbance; communi-
cation; low data rate, remote detection and correction
and errors; Information processing; nodes, microcon-
trollers and small operating systems for low power
systems. With the advent of IoT technology and Long
Range (LoRa) (Wixted et al., 2016; Lavric and Pe-
trariu, 2018; Carvalho et al., 2018), WSN and connec-
tivity are becoming more reliable, stronger and faster.
With this technology it is possible to develop intelli-
gent monitoring systems to detect forest and land fires
(Lee and Ke, 2018; Kadir, 2017; Kadir et al., 2018).
Therefore, this research focuses on developing in-
telligent fire detection systems, especially in the peat
field, based on the detection and monitoring of envi-
ronmental behavior in terms of temperature, humid-
ity and gas. To provide new methods and technolo-
gies for detection and surveillance systems that use
low-power wireless data communications with LoRa
WAN technology. Sensor integration with LoRa
WAN technology affects local communities where
users have access to real-time database information
at any time.
The method for detecting the surface of the earth
will be used in other regions, regions and regions in
Indonesia. This solution is a faster and cheaper al-
ternative to obtaining satellite data currently in use,
which will certainly benefit social welfare and eco-
nomic development. In addition, developing real-
time perception will require some support from pol-
icy makers to understand how the system works and
at the same time to understand the outcome models to
take appropriate action.
130
Kadir, E., Irie, H. and Rosa, S.
Fire Detection System in Peatland Area using LoRa WAN Communication.
DOI: 10.5220/0009145101300134
In Proceedings of the Second International Conference on Science, Engineering and Technology (ICoSET 2019), pages 130-134
ISBN: 978-989-758-463-3
Copyright
c
2020 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
2 LORA WAN DETECTION AND
MONITORING SYSTEM
Detection and monitoring systems are widely used for
objects or parameters that require continuous time.
Currently, many types of monitoring systems are
based on the objectives and parameters to be moni-
tored. Fire detection and environmental monitoring
are carried out in different organizations or organi-
zations to verify the current environmental situation.
Commonly used technology is the use of satellite data
to detect fire points.
This technology has a number of drawbacks and
limitations, including proper fire detection and, in
some cases, no possibility of satellite imagery pass-
ing through the clouds. The new method proposed in
this system is designed to detect smoke, temperature,
particle changes, etc. LoRa sensor. He uses the LoRa
WAN, where he is placed in a high risk fire area to
collect data. Figure 1 shows a series of hot spots in
Riau province.
Figure 1: A map of Riau province with number of fire
hotspots used satellite images.
That information collect by the sensor is sent to
the sensor gateway as base station to transmit data
have been collect by the monitoring system, because
of the distance between the sensor and the base station
of the monitoring system. is far enough in some ar-
eas. For correct data, a large numbers of WAN LoRa
sensors are installed in the area because external sen-
sors can transmit up to 15 km. In addition to the LoRa
WAN sensor, it is mounted on each base station with a
high-resolution camera to analyze aerial imagery be-
fore and after the fire, then train the data to analyze
changes in the image of the environment.
Selected sites likely to cause high forest fires have
been identified in the peat area as shown in Figure
2, installed systems have been approved by local au-
thorities such as the Local Council of Ria and the
Indonesian Ministry of Agriculture. Browser. Envi-
ronment and Forests. Again, the links between Riau
Islamic University and local authorities should be in-
tegrated into the decision-making process and facil-
itate access to installation, monitoring, data analysis
and communication. Improving forest fire monitor-
ing with intelligent ground detection and LoRa WAN
technology can be an early indicator for better disas-
ter risk reduction decision making. This project ben-
efits from new designs and new developments thanks
to the latest LoRa WAN technology and research on
signal transmission.
Configuring sensor base stations in different areas
to gather information from the WAN LoRA sensor
network being developed in the peat area. The infor-
mation collected by the sensor base station is stored
in an internal database and sent to the data center be-
cause the sensor base station is located in remote rural
areas for more than 100 km. Sensors can be detected
and alerted immediately before a fire occurs with the
responsible agency for preventive measures. The next
step will be to configure some sensors and base sta-
tions that will cover the entire province of Riau and
build this project as a prototype system in another
Indonesian country. The proposed LoRa sensor sce-
narios also allow analysis of the behavior and envi-
ronment before and after the fire is analyzed through
a new image processing method, particle detection,
sensor data and system. the media. Data Figure 3
shows a proposal to implement a data network scheme
to monitor WAN and environmental sensors.
Figure 2: Actual condition of land and forest burn on the
field.
Fire Detection System in Peatland Area using LoRa WAN Communication
131
Figure 3: LoRa WAN block diagram for forest fire monitor-
ing system.
3 LORA WAN SOLUTION FOR
PEATLAND MONITORING
The recommended LoRa WAN solution uses a pow-
erful LoRa module made by Semtech technology for
long-term transactions. It is a standard of the LoRa
alliance that creates mechanisms for formatting, pro-
visioning, access agent, message security and protec-
tion, and device management. Figure 4 shows the
LoR WAN that forms a star topology around the gate-
way, which acts as a packet sender between the ter-
minal and the core Network Server (NS). The NS is
to control for manage the Medium Access Control
(MAC) layer for processing and perform as a gate be-
tween application that running to the end of devices
and application server. The standard of LoRa WAN
can be define in three classes; so the final device can
respond to various scenarios such as network topol-
ogy A, B and C (Abeele et al., 2017).
Class A devices often have their own transceiver
in deep sleep conditions and rarely wake up to send
data to NS. Wireless media access in the WAN LoRa
adheres to the ALOHA method, does not use listening
before speaking, and is therefore limited to most parts
of the world when used. In Europe, in sample, the 868
MHz band contains different subbands, with the CDR
between 0.1% and 10% and 1% most common (Zainal
et al., 2017).
3.1 LoRa WAN Networking
Recent technology for sensing system and network
technology is introduced by LoRa WAN with capa-
bility to send in long distance. Furthermore, the low
power transmission make power long life and good
for the maintenance device. As mention in the pre-
vious section, the recommended scenario for network
architecture in this WAN loop is a level network of
architecture that meets traditional internet standards,
such as Internet Protocol version 6 (IPv6). Expect
rapid integration of all LoRa WAN systems and sys-
tems. One-way nodes of the WAN ecosystem are fast
and heavy. However, the transmission capacity of the
WAN LoRa technology is very limited, which means
a limited throughput and a small package size. There-
fore, it is not easy to integrate an IPv6 datagram di-
rectly into LoRa-WAN packages and a compression
mechanism is required. The proposed solution pro-
vides an IPv6 connection to the LoRa node using
the LoRa WAN connection, while a multi-computer
(MEC) -based architecture is used to achieve this in-
tegration: network access, MEC node, bidirectional
flow can be created between LoRa and LoRa, as
shown in FIG. IPv6 is responsible for translating com-
pressed or uncompressed packages into network seg-
ments. WAN and IPv6 (Sanchez-Iborra et al., 2018).
The proposed solution can contribute to the exten-
sive LoRa network, including:
• A true extension of IPR6 in LoRa has been devel-
oped and tested.
• LoRa WAN button LoRa is used in bank testing to
deliver environmental data via IPv6 links to WAN
links.
• The LoR WAN environment for smart environ-
ment detection is configured to be ready for users.
3.2 LoRa WAN Physical Error Model
Physical error is one of parameter have to check, after
changing the Physical Signal Error Model (PHY), the
output data is cleared to increase the entropy of the
source. Note that in a small simulation the Bit Error
Rate (BER) information is obtained from a balanced
distribution, and therefore the entropy of the source
information is within the maximum limit. Before the
bleached current is sent to the modulator, the modu-
lator is mapped. It generates a whole sequence that
is sent to the LoRa WAN sensor button. At the LoRa
sensor node, the N number of the complex base se-
quence sample is changed to N with the time created
by the phase accumulators indicated by (1), where N
is the sample with a base band symbol equivalent to
2BF (fs. / BW) . An entire entry determines the time
shift (Abeele et al., 2017).
m(i) =
exp(− jπ), if i = 0
m(i − 1)exp( j f (i)), if i = 1, . . . , N − 1
(1)
where the instantaneous of frequency can write as
ICoSET 2019 - The Second International Conference on Science, Engineering and Technology
132
Figure 4: LoRa WAN overview in hierarchical architecture refer to Semtech technology.
Figure 5: The IPv6 Architecture of LoRa WAN networking solution stack.
f (i) is given by
f (i) = −π +
i
N
2π, for i = 1, . . . , N − 1 (2)
The number of samples in the WAN LoRa symbol
was then sent via Gaussian White Noise (AWGN) for
a given SNR parameter
c(i) = m(i) +
q
E
s
2SNR
[N (0; 1)+ jN (0;1)]
for i = 0, . . . , N − 1
(3)
where N (0; 1) is the normal of standard distribution
and SNR = 10SNRdB/10. Take note that the energy in
each symbol is one for the LoRa WAN sensor button.
Finally, the LoRa WAN decoding uses a demodule-
based relationship in decoding in which the receive
symbol as associated with all known LoRa symbols.
Symbolic decisions are shown by choosing the LoR
icon with the highest correlation value. The value
of correlation physical error to the model of LoRA
WAN application in land and forest fire detection can
Fire Detection System in Peatland Area using LoRa WAN Communication
133
be write as the number of area going to detect com-
pare to the number of sensor nodes in LoRA WAN
deploy.
4 CONCLUSIONS
A system for detection of land and forest fire use
LoRa WAN technology is proposed. Results show
the simulation and mathematical modeling based on
calculation gives good response and the system ap-
plicable to apply for the alert system in the detection
of the forest fire. LoRa WAN system can send in-
formation in long-distance over than 10 miles, thus
very applicable in the detection of forest fire in large
of an area. The system can be integrating to the sev-
eral sensing systems and collect the information to be-
come a group of information to send to the data center
for monitoring system.
ACKNOWLEDGEMENTS
Authors would like to say thank you very much to
KEMENRISTEKDIKTI Indonesia for funding this
research and Universitas Islam Riau as well as Chiba
University to support the facilities.
REFERENCES
Abeele, F. V. D., Haxhibeqiri, J., Moerman, I., and Hoe-
beke, J. (2017). Scalability analysis of large-scale lo-
rawan networks in ns-3. IEEE Internet of Things Jour-
nal, 4:2186–2198.
Boubiche, D. E., Pathan, A. S. K., Lloret, J., ZHOU, H.,
Hong, S., Amin, S. O., and Feki, M. A. (2018). Ad-
vanced industrial wireless sensor networks and intelli-
gent iot. IEEE Communications Magazine, 56:14–15.
Carvalho, D. F., Depari, A., Ferrari, P., Flammini, A., Ri-
naldi, S., and Sisinni, E. (2018). On the feasibility
of mobile sensing and tracking applications based on
lpwan. IEEE Sensors Applications Symposium (SAS),
pages 1–6.
Chee-Yee, C. and Kumar, S. P. (2003). Sensor networks:
evolution, opportunities, and challenges. In Proceed-
ings of the IEEE, volume 91, pages 1247–1256.
Jie, L., Ghayvat, H., and MUKHOPADHYAY, S. C. (2015).
Introducing intel galileo as a development platform of
smart sensor: Evolution, opportunities and challenges.
In 2015 IEEE 10th Conference on Industrial Electron-
ics and Applications (ICIEA), pages 1797–1802.
Kadir, E. A. (2017). A reconfigurable mimo antenna sys-
tem for wireless communications. In 2017 4th Inter-
national Conference on Electrical Engineering, Com-
puter Science and Informatics (EECSI), pages 1–4.
Kadir, E. A., Irie, H., Rahim, S. K. A., Arta, Y., and Rosa,
S. L. (2018). Reconfigurable mimo antenna for wire-
less communication based on arduino microcontroller.
In 2018 IEEE International RF and Microwave Con-
ference (RFM), pages 119–122. IEEE.
Kakhandki, A. L., Hublikar, S., and Kumar, P. (2017).
An efficient hop selection model to enhance lifetime
of wireless sensor network. In 2017 Innovations
in Power and Advanced Computing Technologies (i-
PACT), pages 1–5. IEEE.
Khajuria, R. and Gupta, S. (2015). Energy optimization and
lifetime enhancement techniques in wireless sensor
networks: A survey. In International Conference on
Computing, Communication and Automation, pages
396–402.
Lavric, A. and Petrariu, A. I. (2018). Lorawan communi-
cation protocol: The new era of iot. In 2018 Inter-
national Conference on Development and Application
Systems (DAS), pages 74–77.
Lee, H. C. and Ke, K. H. (2018). Monitoring of large-area
iot sensors using a lora wireless mesh network sys-
tem: Design and evaluation. In IEEE Transactions on
Instrumentation and Measurement, pages 1–11.
Sanchez-Iborra, R., Sanchez-Gomez, J., Santa, J., Fernan-
dez, P. J., and Skarmeta, A. F. (2018). Ipv6 commu-
nications over lora for future iov services. In 2018
IEEE 4th World Forum on Internet of Things (WF-
IoT), pages 92–97.
Wixted, A. J., Kinnaird, P., L. H., Tait, A., Ahmdinia, A.,
and Strachan, N. (2016). Evaluation of lora and lo-
rawan for wireless sensor networks. In 2016 IEEE
SENSORS, pages 1–3.
Zainal, N. A. B., H. M. H., Chowdhury, I., and Islam, M. R.
(2017). Sensor node clutter distribution in lora lpwan.
In 2017 IEEE 4th International Conference on Smart
Instrumentation, Measurement and Application (IC-
SIMA), pages 1–6.
ICoSET 2019 - The Second International Conference on Science, Engineering and Technology
134
