DESIGN AND IMPLEMENTATION OF LORA COMMUNICATION SYSTEM BASED ON SOFTWARE DEFINED RADIO FOR DIRECT-TO-SATELLITE INTERNET OF THINGS (DTS-IOT) APPLICATIONS ON EQUATORIAL LEO SATELLITE CONSTELLATIONS
The rapid growth of the Internet of Things (IoT) demands reliable and cost-effective communication solutions, particularly in remote areas. Low Earth Orbit (LEO) Satellite and Software Defined Radio (SDR) technology offer significant potential in supporting Direct-to-Satellite IoT (DtS-IoT) commu...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/84268 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The rapid growth of the Internet of Things (IoT) demands reliable and cost-effective
communication solutions, particularly in remote areas. Low Earth Orbit (LEO)
Satellite and Software Defined Radio (SDR) technology offer significant potential
in supporting Direct-to-Satellite IoT (DtS-IoT) communications. This research
develops an IoT communication system based on LoRa using SDR for DtS-IoT
applications on LEO satellites.
The results demonstrate that the SDR-based IoT LoRa Gateway can support reliable
LoRa communication. Testing showed optimal performance with LoRa parameters
SF7 with a bandwidth (BW) of 125 kHz, SF10 with BW 250 kHz, and SF12 with
BW 500 kHz at a frequency of 923 MHz, achieving a Packet Delivery Ratio (PDR)
greater than 98% for 50-byte data packets. In multi-user applications, the gateway
can receive and decrypt data from users with different LoRa parameters. The SDR-
based IoT Ground Terminal design was also successfully implemented, supporting
optimal LoRa modulation. The best performance was achieved at SF12 and BW
250 kHz, with a maximum transmission power of 6.94 dBm without a High Power
Amplifier (HPA) and 27.12 dBm with HPA, demonstrating high flexibility in multi-
user scenarios. The SDR-based LEO satellite communication channel simulator
developed in this research accurately replicates satellite channel conditions. It
recorded low error rates for Total Loss, with 2 dB at frequencies of 923 MHz and
2200 MHz. For Doppler effects, errors were 201 Hz (< 3%) for 923 MHz and 480
Hz (< 3%) for 2200 MHz. Latency errors were insignificant. This simulator is
effective in analyzing LoRa communication performance and can also emulate LEO
satellite communication channels at low or near-equatorial inclinations, particularly
in cases of low-inclination satellites. |
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