Analysis and design of an inset-feed microstrip antenna for a LEO satellite IoT ground station at 921 MHz

Authors

  • Rangga Taqwa Republic of Indonesian Defense University, Bogor, Indonesia
  • H.A. Danang Rimbawa Republic of Indonesia Defence University, Bogor, Indonesia
  • Apip Miptahudin Republic of Indonesia Defence University, Bogor, Indonesia
  • Bayu Nuar Khadapi Hasibuan Republic of Indonesia Defence University, Bogor, Indonesia
  • Aria Kusumah Sastradinata Republic of Indonesia Defence University, Bogor, Indonesia
  • Abbas Madani Bangun Republic of Indonesia Defence University, Bogor, Indonesia

DOI:

https://doi.org/10.35335/mandiri.v14i2.464

Keywords:

Ansys HFSS, Inset-Feed, Link Budget, LoRa, Microstrip Antenna

Abstract

The evolution of the Internet of Things (IoT) demands global connectivity that terrestrial networks alone cannot provide1. Low Earth Orbit (LEO) satellites equipped with Long Range (LoRa) communication technology offer a promising solution to bridge this connectivity gap2. This paper presents a specific case study calculation for a LoRa-based IoT satellite mission, defining the system's operational constraints based on selected hardware3. This analysis is framed by the RFM95W LoRa transceiver for the ground station and the Satlab Polaris receiver for the satellite4. The datasheet specifications of these components establish the critical link parameters that dictate performance: a maximum Transmit Power (Pt) ) of 20 dBm from the RFM95W 5and a Receiver Sensitivity threshold of -130 dBm for the Satlab Polaris6. The objectives are: (1) to conduct a comprehensive link budget analysis to validate the communication viability between a LEO satellite and a ground station 77, and (2) to design and predict the performance of an inset-feed microstrip antenna operating in the 920-925 MHz Indonesian LoRa frequency band using an FR-4 substrate. The detailed link budget analysis, performed for an uplink to a 500 km orbit 9, reveals that these specific parameters create a stringent performance requirement: while a reliable link margin of $+7.8 \text{ dB}$ is achieved at a 90°  elevation (best case) 10101010, the system reaches its theoretical critical threshold (0.0 dB margin) at 19.1° and enters link failure with a -2.8 dB margin at the target 10°  elevation. This failure is directly linked to the preliminary simulation of the initial antenna design, which shows a suboptimal return loss (S11) of -9.41 dB. This paper concludes that the system's target for low-elevation communication has not been met. The performance gap, defined by the hardware constraints, confirms that the initial antenna design is insufficient15. Therefore, systematic optimization of the antenna design is identified as the crucial next step to achieve a positive link margin at the 10° target elevation and ensure a robust communication link across all operational scenarios.

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Published

2025-10-24

How to Cite

Taqwa, R., Rimbawa, H. D., Miptahudin, A., Hasibuan, B. N. K., Sastradinata, A. K., & Bangun, A. M. (2025). Analysis and design of an inset-feed microstrip antenna for a LEO satellite IoT ground station at 921 MHz. Jurnal Mandiri IT, 14(2), 236–246. https://doi.org/10.35335/mandiri.v14i2.464

Issue

Vol. 14 No. 2 (2025): October: Computer Science and Field

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Articles

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Copyright (c) 2025 Rangga Taqwa, H.A. Danang Rimbawa, Apip Miptahudin, Bayu Nuar Khadapi Hasibuan, Aria Kusumah Sastradinata, Abbas Madani Bangun

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