Feature Articles: Space Integrated Computing Network

Vol. 20, No. 12, pp. 36–40, Dec. 2022. https://doi.org/10.53829/ntr202212fa4

Satellite Sensing Platform

Fumihiro Yamashita, Kiyohiko Itokawa, Yosuke Fujino, and Kenji Suzuki

Abstract

This article introduces a 920-MHz Internet of Things (IoT) platform via a low Earth orbit (LEO) satellite using feeder-link multiple-input multiple-output (MIMO) technology. In this platform, the LEO satellite captures the IoT radio waves transmitted from terrestrial low-power wide-area terminals onboard then downlinks them to the base station when it passes over the station. Since the received signals are directly digitalized as wave data, the amount of data stored is huge. To downlink this huge amount of data within the limited period in which the moving LEO satellite passes over the base station, we propose applying MIMO technology to the downlink from the LEO satellite to the base station.

Keywords: satellite MIMO, satellite IoT, satellite blind beamforming

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1. Introduction

Various Internet of Things (IoT) services are rapidly spreading worldwide [1]. Satellite communications is widely used in places a terrestrial network cannot cover, so it is an effective approach to provide IoT services to such areas. Several satellite IoT services accommodate IoT traffic using devices and frequencies provided by the satellite operators [2, 3]. However, the initial and running costs are so high that the number of users is currently small. To address the cost issues, we propose using terrestrial 920-MHz low-power wide-area (LPWA) terminals for satellite IoT systems. We aim to lower the cost of IoT services via satellite by using terrestrial LPWA terminals and shared unlicensed frequency bands.

2. Satellite sensing platform

2.1 Concept

Figure 1 shows the system configuration of our IoT platform [4]. The power-regulated terrestrial LPWA terminals can be used freely without a license in the 920-MHz frequency band. The radio waves emitted from the LPWA terminals are captured by a low Earth orbit (LEO) satellite. The captured waves are then digitalized and stored in the onboard memory. Finally, the stored data are downlinked to the base station. Demodulation is not carried out onboard, so our satellite IoT platform does not specify the communication protocol; it can correspond to any type of protocol. The stored data need to be downlinked in the limited time when the LEO satellite passes over the base station. Therefore, we propose applying multiple-input multiple-output (MIMO) technology to the feeder-link between the LEO satellite and base station. As Fig. 1 shows, the satellite MIMO technology executes spatial multiplexing transmission from a single satellite with multiple antennas to the base station connected with multiple remote antennas. The technical points and operational principles are introduced later.


Fig. 1. Satellite sensing platform.

2.2 Key technologies

(1) Satellite blind beamforming

Since many terrestrial LPWA terminals share the unlicensed 920-MHz band, onboard receiver (Rx) antennas receive both the desired satellite IoT signals and undesired interference emitted from a huge number of terrestrial LPWA terminals. Therefore, they need to extract the desired satellite IoT signals and suppress interference. To achieve this, several Rx antennas are implemented onboard and downlink the received signals they capture to the base station. The desired signal is then extracted offline while interference-cancellation software suppresses undesired signals [5]. Figure 2 shows the concept of maximizing the power of a desired signal while suppressing the power of undesired signals. Multiple onboard antennas help channel the null directivity in the direction from which a large amount of undesired interference is emitted, simultaneously forming the peak directivity toward the desired LPWA terminal. This signal processing is carried out offline by using downlinked onboard wave data in the base station. This technique is called “satellite blind beamforming.” Since demodulation is also carried out using software, our platform can flexibly accommodate any type of LPWA protocol by installing the appropriate demodulator.


Fig. 2. Satellite blind beamforming.

Our platform is based on the condition that signals of terrestrial 920-MHz LPWA terminals can be captured by the LEO satellite. Therefore, it needs to confirm that those received signals satisfy the required signal-to-noise ratio (SNR) for demodulation. Therefore, we investigate the coverage area of a satellite IoT terminal by calculating its link budget.

A dipole antenna is assumed for the LPWA terminal antenna. The transmitter (Tx) power is 20 mW, the same regulation as a typical terrestrial LPWA terminal. LoRa (long range radio) (spreading factor: 12, bandwidth: 125 kHz) is used as a protocol so that its required SNR is 6 dB. The antenna gain depends on how the dipole antenna is set. We set the boresight directivity of the dipole antenna to be vertical to the Earth.

We do not consider the undesired/unknown interference from other LPWA terminals for the fundamental link-budget calculation. There are three onboard Rx antennas, each of which is a circular, patch-type antenna with a peak gain of 6.5 dBi, and the –3-dB-bandwidth is 80 degrees. Since we do not consider the undesired signals in this calculation, we apply maximal ratio combining to the three received signals. Under the above condition, the maximal radius of the service coverage area (SNR > 6 dB) is about 640 km.

(2) Satellite MIMO

Figure 3 shows the operational principle of satellite MIMO [6]. By using a control channel for multiple Tx antennas, the Doppler frequency is removed and symbol timing is detected in the Rx. The channel matrix is then estimated, which is used to cancel the MIMO interference.

The channel matrix and received SNR of LEO satellites are expected to change at each ground-antenna elevation angle and visible path. Because an LEO satellite moves around the Earth, it takes different positions when connecting to a ground station. The changes between the propagation distance, received SNR, and relationship between the Tx/Rx antenna positions are complicated for each visibility time and path. Therefore, the elements of the LEO-MIMO channel matrix must be analyzed at each visibility time to evaluate the capacity of the channel [7].


Fig. 3. Satellite MIMO.

Figure 4 illustrates an example of the capacity enhancement using LEO-MIMO. Two antennas are mounted on the satellite with an interval of 70 cm and the interval between the two base stations is 70 km. For comparison, a conventional single-antenna satellite system, i.e., single input single output (SISO), is also being evaluated. The right side of Fig. 4 shows the capacity comparison while the LEO satellite is moving over Japan. The X axis shows time and Y axis shows capacity. The MIMO capacity is about double that of the SISO capacity. This means the MIMO technology can improve communications capacity corresponding to the number of antennas.


Fig. 4. Capacity enhancement using LEO-MIMO.

3. Satellite experiments

Experiments to confirm the practicality of a 920-MHz IoT platform via an LEO satellite using satellite MIMO technology are being considered. Figure 5 shows an experimental configuration with a scale model. Three antennas are implemented on the satellite as onboard 920-MHz IoT Rxes. We will also conduct 3 × 3 MIMO experiments. On the basis of our experience, we plan to use the X band for MIMO experiments. For IoT experiments, our plan is to evaluate satellite IoT performance under various conditions, as shown in Fig. 6.


Fig. 5. Configuration of satellite experiments.


Fig. 6. Conditions for IoT experiments.

4. Summary

We proposed a 920-MHz IoT platform via a LEO satellite using feeder-link MIMO technology. We presented fundamental feasibility studies of the link budget calculation and estimation of MIMO channel capacity.

References

[1] U. Raza, P. Kulkarni, and M. Sooriyabandara, “Low Power Wide Area Networks: An Overview,” IEEE Communications Surveys & Tutorials, Vol. 19, No. 2, pp. 855–873, 2017.
[2] B. Di, H. Zhang, L. Song, Y. Li, and G. Y. Li, “Ultra-dense LEO: Integrating Terrestrial-satellite Networks into 5G and Beyond for Data Offloading,” IEEE Transactions on Wireless Communications, Vol. 18, No. 1, pp. 47–62, 2018.
[3] Z. Qu, G. Zhang, H. Cao, and J. Xie, “LEO Satellite Constellation for Internet of Things,” IEEE Access, Vol. 5, pp. 18391–18401, 2017.
[4] F. Yamashita, D. Goto, Y. Kojima, M. Matsui, K. Itokawa, K. Yoshizawa, Y. Fujino, C. Kato, and M. Nakadai, “920-MHz IoT Platform via LEO Satellite Employing Feeder-link MIMO Technology,” International Conference on Emerging Technologies for Communications (ICETC) 2020, A1-2, 2020.
[5] Y. Fujino, D. Uchida, T. Fujita, O. Kagami, and K. Watanabe, “A Subspace Estimation Method based on Eigenvalue Decomposition for Multi-target Constant Modulus Algorithm,” Proc. of IEEE Wireless Communications and Networking Conference (WCNC) 2007, pp. 1232–1236, 2007.
[6] D. Goto, K. Itokawa, F. Yamashita, C. Kato, and M. Nakadai, “Clock Timing Synchronization among Distributed Multiple Antennas for LEO-MIMO Communications System,” ICETC 2020, B1-4, 2020.
[7] C. Kato, M. Nakadai, D. Goto, H. Shibayama, and F. Yamashita, “Channel Capacity Analysis of Satellite MIMO System Depending on the Orbital Altitude,” Proc. of the 37th AIAA International Communications Satellite Systems Conference (ICSSC 2019), 2019.
Fumihiro Yamashita
Senior Research Engineer, Supervisor, NTT Access Network Service Systems Laboratories.
He received a B.E., M.E., and Ph.D. from Kyoto University in 1996, 1998, and 2006. He worked on modulation and demodulation schemes for broadband mobile satellite communications systems. He has also been a part-time lecturer at the Kanto Gakuin University and the Muroran Institute of Technology since 2018. His current interests include the research and development of disaster-relief and remote island satellite communications systems and satellite MIMO and IoT systems using LEO satellites.
Kiyohiko Itokawa
Senior Research Engineer, NTT Access Network Service Systems Laboratories.
He received a B.E. and M.E. in electrical and electronic engineering from the University of Tsukuba, Ibaraki, in 1998 and 2000. He joined NTT Access Network Service Systems Laboratories in 2000 and has been involved in developing wireless access systems such as 802.11a wireless LAN systems, and 26-GHz-band subscriber fixed wireless access systems. His current research interests include the research and development of satellite MIMO and IoT systems using LEO satellites.
Yosuke Fujino
Senior Research Engineer, NTT Network Innovation Laboratories.
He received a B.E. and M.E. in electrical and electronic engineering from Shizuoka University in 2002 and 2004. He joined NTT Network Innovation Laboratories in 2004 and engaged in research on physical layer signal design, transceiver architecture, and signal processing for IoT wireless systems. The current focus of his research is wireless communications technology in non-terrestrial areas such as underwater, underground, and space.
Kenji Suzuki
Senior Research Engineer, Supervisor, NTT Network Innovation Laboratories.
He received a B.E. and M.E. in electrical and electronic engineering from Tokyo Institute of Technology in 1999 and 2001. In 2001, he joined NTT Telecommunications Energy Laboratories, where he worked on a wireless transceiver large-scale integrated circuit architecture for low power dissipation. His interests include analog and radio-frequency integrated circuit design for wireless communications. The current focus of his research is wireless communications technology in non-terrestrial areas such as underwater, underground, and space.

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