The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. ex. Some numerals are expressed as "XNUMX".
Copyrights notice
The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. Copyrights notice
pandangan teks lengkap
134
Sistem Perkongsian Spektrum Dinamik (DSS), yang menggunakan jalur frekuensi yang diperuntukkan kepada sistem sedia ada (iaitu, pengguna utama) telah menarik perhatian untuk mengembangkan lebar jalur tersedia bagi sistem komunikasi mudah alih (5G) generasi kelima dalam jalur sub-6GHz. Di Jepun, sistem DSS dalam jalur 2.3GHz, di mana Unit Pickup Medan (FPU) berasaskan ARIB STD-B57 ditetapkan sebagai sistem penyandang, telah dikaji untuk kegunaan kedua sistem 5G. Dalam kes ini, FPU penyandang ialah sistem mudah alih, dan oleh itu, sistem DSS perlu menggunakan bukan sahaja pangkalan data perkongsian spektrum tetapi juga penderia radio untuk mengesan isyarat utama dengan ketepatan tinggi, melindungi sistem utama daripada gangguan dan mencapai lebih selamat perkongsian spektrum. Makalah ini mencadangkan kaedah penderiaan yang sangat cekap untuk mengesan isyarat FPU berasaskan ARIB STD-B57 dalam jalur 2.3GHz. Kaedah yang dicadangkan boleh digunakan untuk dua jenis isyarat FPU; yang menggunakan perintis mod Pilot Berterusan (CP) dan perintis mod Pilot Tersebar (SP). Selain itu, kami menggunakan kaedah penambahan sampel dan kaedah penambahan simbol untuk meningkatkan prestasi pengesanan. Walaupun dalam persekitaran saluran 3GPP EVA, kaedah yang dicadangkan boleh, dengan kebarangkalian lebih daripada 99%, mengesan isyarat FPU dengan SNR sebanyak -10dB. Di samping itu, kami mencadangkan isyarat rujukan terkuantisasi untuk mengurangkan kerumitan pelaksanaan litar korelasi silang kompleks. Isyarat rujukan yang dicadangkan boleh mengurangkan bilangan bit pengkuantitian isyarat rujukan kepada 2 bit untuk fasa dalam dan 3 bit untuk komponen ortogon.
Atomu SAKAI
Kyoto University
Keiichi MIZUTANI
Kyoto University
Takeshi MATSUMURA
Kyoto University
Hiroshi HARADA
Kyoto University
The copyright of the original papers published on this site belongs to IEICE. Unauthorized use of the original or translated papers is prohibited. See IEICE Provisions on Copyright for details.
Salinan
Atomu SAKAI, Keiichi MIZUTANI, Takeshi MATSUMURA, Hiroshi HARADA, "Highly Efficient Sensing Methods of Primary Radio Transmission Systems toward Dynamic Spectrum Sharing-Based 5G Systems" in IEICE TRANSACTIONS on Communications,
vol. E104-B, no. 10, pp. 1227-1236, October 2021, doi: 10.1587/transcom.2020DSP0008.
Abstract: The Dynamic Spectrum Sharing (DSS) system, which uses the frequency band allocated to incumbent systems (i.e., primary users) has attracted attention to expand the available bandwidth of the fifth-generation mobile communication (5G) systems in the sub-6GHz band. In Japan, a DSS system in the 2.3GHz band, in which the ARIB STD-B57-based Field Pickup Unit (FPU) is assigned as an incumbent system, has been studied for the secondary use of 5G systems. In this case, the incumbent FPU is a mobile system, and thus, the DSS system needs to use not only a spectrum sharing database but also radio sensors to detect primary signals with high accuracy, protect the primary system from interference, and achieve more secure spectrum sharing. This paper proposes highly efficient sensing methods for detecting the ARIB STD-B57-based FPU signals in the 2.3GHz band. The proposed methods can be applied to two types of the FPU signal; those that apply the Continuous Pilot (CP) mode pilot and the Scattered Pilot (SP) mode pilot. Moreover, we apply a sample addition method and a symbol addition method for improving the detection performance. Even in the 3GPP EVA channel environment, the proposed method can, with a probability of more than 99%, detect the FPU signal with an SNR of -10dB. In addition, we propose a quantized reference signal for reducing the implementation complexity of the complex cross-correlation circuit. The proposed reference signal can reduce the number of quantization bits of the reference signal to 2 bits for in-phase and 3 bits for orthogonal components.
URL: https://global.ieice.org/en_transactions/communications/10.1587/transcom.2020DSP0008/_p
Salinan
@ARTICLE{e104-b_10_1227,
author={Atomu SAKAI, Keiichi MIZUTANI, Takeshi MATSUMURA, Hiroshi HARADA, },
journal={IEICE TRANSACTIONS on Communications},
title={Highly Efficient Sensing Methods of Primary Radio Transmission Systems toward Dynamic Spectrum Sharing-Based 5G Systems},
year={2021},
volume={E104-B},
number={10},
pages={1227-1236},
abstract={The Dynamic Spectrum Sharing (DSS) system, which uses the frequency band allocated to incumbent systems (i.e., primary users) has attracted attention to expand the available bandwidth of the fifth-generation mobile communication (5G) systems in the sub-6GHz band. In Japan, a DSS system in the 2.3GHz band, in which the ARIB STD-B57-based Field Pickup Unit (FPU) is assigned as an incumbent system, has been studied for the secondary use of 5G systems. In this case, the incumbent FPU is a mobile system, and thus, the DSS system needs to use not only a spectrum sharing database but also radio sensors to detect primary signals with high accuracy, protect the primary system from interference, and achieve more secure spectrum sharing. This paper proposes highly efficient sensing methods for detecting the ARIB STD-B57-based FPU signals in the 2.3GHz band. The proposed methods can be applied to two types of the FPU signal; those that apply the Continuous Pilot (CP) mode pilot and the Scattered Pilot (SP) mode pilot. Moreover, we apply a sample addition method and a symbol addition method for improving the detection performance. Even in the 3GPP EVA channel environment, the proposed method can, with a probability of more than 99%, detect the FPU signal with an SNR of -10dB. In addition, we propose a quantized reference signal for reducing the implementation complexity of the complex cross-correlation circuit. The proposed reference signal can reduce the number of quantization bits of the reference signal to 2 bits for in-phase and 3 bits for orthogonal components.},
keywords={},
doi={10.1587/transcom.2020DSP0008},
ISSN={1745-1345},
month={October},}
Salinan
TY - JOUR
TI - Highly Efficient Sensing Methods of Primary Radio Transmission Systems toward Dynamic Spectrum Sharing-Based 5G Systems
T2 - IEICE TRANSACTIONS on Communications
SP - 1227
EP - 1236
AU - Atomu SAKAI
AU - Keiichi MIZUTANI
AU - Takeshi MATSUMURA
AU - Hiroshi HARADA
PY - 2021
DO - 10.1587/transcom.2020DSP0008
JO - IEICE TRANSACTIONS on Communications
SN - 1745-1345
VL - E104-B
IS - 10
JA - IEICE TRANSACTIONS on Communications
Y1 - October 2021
AB - The Dynamic Spectrum Sharing (DSS) system, which uses the frequency band allocated to incumbent systems (i.e., primary users) has attracted attention to expand the available bandwidth of the fifth-generation mobile communication (5G) systems in the sub-6GHz band. In Japan, a DSS system in the 2.3GHz band, in which the ARIB STD-B57-based Field Pickup Unit (FPU) is assigned as an incumbent system, has been studied for the secondary use of 5G systems. In this case, the incumbent FPU is a mobile system, and thus, the DSS system needs to use not only a spectrum sharing database but also radio sensors to detect primary signals with high accuracy, protect the primary system from interference, and achieve more secure spectrum sharing. This paper proposes highly efficient sensing methods for detecting the ARIB STD-B57-based FPU signals in the 2.3GHz band. The proposed methods can be applied to two types of the FPU signal; those that apply the Continuous Pilot (CP) mode pilot and the Scattered Pilot (SP) mode pilot. Moreover, we apply a sample addition method and a symbol addition method for improving the detection performance. Even in the 3GPP EVA channel environment, the proposed method can, with a probability of more than 99%, detect the FPU signal with an SNR of -10dB. In addition, we propose a quantized reference signal for reducing the implementation complexity of the complex cross-correlation circuit. The proposed reference signal can reduce the number of quantization bits of the reference signal to 2 bits for in-phase and 3 bits for orthogonal components.
ER -