DEVELOPMENT AND IMPLEMENTATION OF DATA COMPRESSION TECHNIQUE FOR IOT SENSOR DATA TRANSMISSION IN AQUACULTURE ISOLATED FROM INTERNET NETWORK THROUGH LORAWAN GATEWAY ANTARES TELKOM
Aquaculture in isolated areas often challenges in terms of monitoring and management due to limited internet network access. In an effort to solve this problem, the research was conducted by developing and implementing a LoRa- based IoT communication system. The communication system is expected...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/85104 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Aquaculture in isolated areas often challenges in terms of monitoring and
management due to limited internet network access. In an effort to solve this
problem, the research was conducted by developing and implementing a LoRa-
based IoT communication system. The communication system is expected to be able
to transmit sensor data efficiently and reliably in areas with limited internet
network access. This system consists of LoRa RFM95W module and ESP32
microcontroller. The system also uses a backhaul connection in LoRaWAN gateway
Antares Telkom.
The selection of the LoRa RFM95W module is based on its ability to operate in the
920-923 MHz frequency band in accordance with Indonesian regulations. This
module offers long-range communication with low power consumption. In LoRa
class settings, the author chose class A because of the power efficiency it offers.
Devices in class A are only active when sending or receiving data, so they can save
battery life significantly. This is especially important for IoT devices that often have
to operate for long periods of time without frequent charging.
One important technical aspect in the use of LoRa is the selection of the Spreading
Factor (SF). A higher SF extends the airtime for each data transmission, which in
turn increases the communication range. However, it also slows down the data rate.
Therefore, SF selection should be adjusted according to application needs and
operational environment conditions to achieve a balance between range, data rate,
and power consumption.
This research also includes the development of data compression techniques that
aim to minimize data loss during the compression and decompression process, as
well as reduce the size of transmitted data without compromising quality and
accuracy. These techniques are important for optimizing bandwidth usage and
ensuring accurate and real-time data integration. In addition, this system also
provides a backup mechanism for decompressed data to ensure data reliability.
There are 2 types of tests carried out, namely data transmission testing with
variations in compression algorithms and data transmission testing with variations
in distance. Data transmission with compression algorithms is conducted to find
the best compression algorithm with the largest compression ratio. From this
experiment, it was found that the unishox2 compression algorithm can send data
up to 347 bytes with a compression ratio of more than 1. Data transmission testing
with distance variations was carried out with the best compression algorithm,
namely unishox2. Tests with distance variations obtained by sending with SF9
parameters get low signal loss with data sizes that can be sent up to 347 bytes. |
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