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公开(公告)号:US20190013983A1
公开(公告)日:2019-01-10
申请号:US15744909
申请日:2016-10-31
Applicant: SOUTHEAST UNIVERSITY
Inventor: Xiqi GAO , Li YOU , Wenjin WANG
IPC: H04L27/26 , H04L5/00 , H04B7/01 , H04B7/06 , H04B7/0408 , H04B7/0413
CPC classification number: H04L27/2655 , H04B7/01 , H04B7/0408 , H04B7/0413 , H04B7/0617 , H04L5/0048 , H04W56/005
Abstract: Signal transmitting/receiving electronic devices or terminals in the present disclosure are configured to conduct per-beam signal synchronization in massive MIMO communication with a signal receiving/transmitting device or base station. During the massive MIMO communication, the devices or terminals are configured to transmit/receive signals via a set of beams to or from the signal receiving/transmitting device or base station. For beam domain signal of each individual beam of the plurality beams, the devices or terminals are configured to determine target time adjustments based on time shifts of the beam domain signals induced by multipath effect and target frequency adjustments based on frequency offsets of the beam domain signals induced by the Doppler effect; adjust time independent variables of the beam domain signals by the time adjustments; and adjust frequency independent variables of the beam domain signals by the frequency adjustments. Further, per-beam synchronized BDMA massive MIMO transmission method is disclosed, which provides a solution to efficient and reliable wireless communications with high mobility and/or high carrier frequency.
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公开(公告)号:US20240195462A1
公开(公告)日:2024-06-13
申请号:US17786380
申请日:2021-10-12
Applicant: Southeast University
Inventor: Li YOU , Xiaoyu QIANG , Yuqi YE , Yan HUANG , Wenjin WANG , Xiqi GAO
IPC: H04B7/0456 , H04B7/185
CPC classification number: H04B7/0456 , H04B7/18513
Abstract: Disclosed is a transmit method based on satellite massive Multiple-Input Multiple-Output (MIMO) integrated sensing and communication, where a satellite end is equipped with a massive MIMO array to implement an integrated sensing and communication system. The satellite end sends a communication signal to multiple user terminals based on statistical properties of electromagnetic wave propagation, and detects multiple targets simultaneously, thus realizing simultaneous communication of the satellite end with the user terminals and sensing for the targets. The present disclosure fully utilizes the spectrum resources, implements a flexible switch between wireless communication and target sensing functions based on a satellite, and mitigates the effects of the beam squint on system performance, thus greatly improving communication performance and radar resolution and being applicable for construction of an integrated network of space, air, ground and sea to achieve global coverage.
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公开(公告)号:US20220263554A1
公开(公告)日:2022-08-18
申请号:US17629181
申请日:2020-04-22
Applicant: SOUTHEAST UNIVERSITY
IPC: H04B7/06 , H04B7/0417
Abstract: The present invention discloses a massive multiple-input multiple-output (MIMO) beam domain robust precoding transmission method and system. The method is based on base station (BS)-side and user-side refined sampling steering vector matrices, and considers the influence of channel aging caused by mobility, where obtained channel state information is refined beam domain a posteriori statistical channel information including channel mean and variance information. In the present invention, the BS performs robust precoding transmission by using the refined beam domain a posteriori statistical channel information, where a channel model on which the adopted refined beam domain a posteriori statistical channel information depends is a channel model which corresponds to a refined sampling space angle and adopts a steering vector matrix; the used statistical channel information is more sufficient and accurate, so that the problem of universality of massive MIMO to various typical mobile scenarios under the condition that the antenna size is limited can be solved; and high spectral efficiency is achieved, and the provided robust precoding design utilizes the sparsity of a beam domain channel and the structural characteristics of a sampling steering vector matrix, so that the calculation complexity can be greatly reduced.
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公开(公告)号:US20210368455A1
公开(公告)日:2021-11-25
申请号:US17256656
申请日:2020-02-20
Applicant: SOUTHEAST UNIVERSITY
Inventor: Xiqi GAO , Li YOU , Xu CHEN , Yufei HUANG , Xueyuan SHI , Siran HE , Wenjin WANG
IPC: H04W52/42 , H04B7/0452 , H04W72/04 , H04W56/00
Abstract: A large-scale MIMO (Multiple-Input Multiple-Output) wireless transmission method for millimeter wave/Terahertz networks is provided. In order to reduce the interruption of propagation in the millimeter wave/Terahertz band, a plurality of cells are combined into a wireless transmission network, the base station in each cell is equipped with a large-scale antenna array, and a unitary transformation matrix is used to achieve large-scale beam coverage for user terminals in the entire network. Moreover, in order to reduce the influence of the multipath and Doppler effects on transmission performance, received signals are synchronized for time and frequency in each receiving beam of a user terminal. The method allocates power for signal transmission according to the statistic information of synchronized equivalent channels, and gives an optimal power allocation matrix by iterative solution based on the CCCP (concave-convex procedure) and the deterministic equivalent method.
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公开(公告)号:US20210288715A1
公开(公告)日:2021-09-16
申请号:US17268336
申请日:2019-10-10
Applicant: SOUTHEAST UNIVERSITY
Inventor: Xiqi GAO , Li YOU , Kexin LI , Jiaheng WANG , Wenjin WANG
IPC: H04B7/185 , H04B7/0408 , H04B7/0456 , H04W72/04
Abstract: The present invention discloses a large-scale MIMO satellite mobile communication method and system. A satellite or gateway station uses spatial angle information of user terminals to group the users to be served in the coverage area to form space division user groups, wherein the user terminals in the same group use the same time-frequency resources to communicate with the satellite, while the user terminals in different groups use different time-frequency resources to communicate with the satellite. For the user terminals in the same space division user group, the satellite or gateway station uses statistical channel information of each user terminal to calculate a downlink precoding vector and an uplink receiving processing vector corresponding to each user terminal, and then uses the obtained vectors to perform downlink precoding transmission and uplink received signal processing. The user terminal uses Doppler frequency shift resulted from the movement of the satellite and minimum propagation time delay of long-distance propagation to make compensation for the frequency and time of the signal received and sent by the user terminal. The present invention can greatly improve the spectrum efficiency and power efficiency of a satellite mobile communication system and reduce the implementation complexity of the satellite mobile communication system.
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公开(公告)号:US20180115912A1
公开(公告)日:2018-04-26
申请号:US15506750
申请日:2014-08-28
Applicant: Southeast University
IPC: H04W16/28 , H04B7/0456 , H04B7/06 , H04B7/0408 , H04L1/06
CPC classification number: H04W16/28 , H04B7/0408 , H04B7/0413 , H04B7/0452 , H04B7/0456 , H04B7/0465 , H04B7/0617 , H04B7/0669 , H04L1/00 , H04L1/0042 , H04L1/0668 , H04L25/03898
Abstract: Described herein is an omni-directional transmission scheme allowing signals to transmit from a base station to multiple users in massive MIMO systems with reduced pilot overhead and system complexity. The transmission scheme uses a low-dimensional space-time coding scheme to generate a K-dimensional vector signal, and based on the K-dimensional vector signal, using an omni-directional precoding matrix W to generate an M-dimensional vector signal for transmission over a large number of transmitting antennas, wherein the matrix W comprises M rows and K columns, and K is much smaller than M.
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公开(公告)号:US20220393730A1
公开(公告)日:2022-12-08
申请号:US17762195
申请日:2020-04-22
Applicant: Southeast University
IPC: H04B7/0456 , H04L25/02 , H04B17/391 , H04B7/08
Abstract: Disclosed are a method and system for acquiring massive MIMO beam domain statistical channel information. A refined beam domain channel model involved in the disclosed method is based on a refined sampling steering vector matrix. Compared with a traditional DFT matrix-based beam domain channel model, when antenna size is limited, said model is closer to a physical channel model, and provides a model basis for solving the problem of the universality of massive MIMO for various typical mobile scenarios under a constraint on antenna size. The present invention provides a method for acquiring massive MIMO refined beam domain a priori statistical channel information and a posteriori statistical channel information, the a posteriori statistical channel information comprising mean and variance information of the a posteriori channel. The method of the present invention has low complexity, can be applied to an actual massive MIMO system, provides support for a robust precoding transmission method, and has large application value.
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公开(公告)号:US20220376750A1
公开(公告)日:2022-11-24
申请号:US17597778
申请日:2020-12-21
Applicant: SOUTHEAST UNIVERSITY
Inventor: Xiqi GAO , Xianglong YU , Anan LU
IPC: H04B7/0456 , H04B7/22 , H04B17/391 , H04L27/26
Abstract: The present disclosure relates to a skywave large-scale MIMO communication method, model, and system. A skywave communication base station in a short waveband is constructed using a large-scale antenna array, wherein skywave large-scale MIMO communication is carried out between the skywave communication base station and a user terminal in a coverage area by ionospheric reflection. The skywave communication base station determines a spacing of the large-scale antenna array according to a maximum operating frequency, and communicates with the user terminal based on a TDD communication mode, wherein a skywave large-scale MIMO signal is transmitted based on an OFDM modulation mode or a power efficiency improvement modulation mode. The skywave communication base station selects a communication carrier frequency within a short waveband range according to a real-time ionospheric channel characteristic, and adaptively selects an OFDM modulation parameter and a signal frame structure.
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公开(公告)号:US20220245634A1
公开(公告)日:2022-08-04
申请号:US17617577
申请日:2020-06-16
Applicant: SOUTHEAST UNIVERSITY
Inventor: Xintong LING , Yuwei LE , Bowen ZHANG , Jiaheng WANG , Xiqi GAO
IPC: G06Q20/40 , H04W12/08 , H04W12/122 , H04L9/00 , G06Q20/38
Abstract: A blockchain-enhanced open Internet of Things (IoT) access architecture includes an access point, a number of IoT devices, a hash access mechanism, a blockchain mining network, and a blockchain enabling mechanism that manages network access of the IoT device. The blockchain-enhanced open IoT access architecture provided in the present invention provides a secure, reliable, fair, and short-packet access service for a plurality of devices in an IoT network by using features of a blockchain such as distributed storage, tamper-proofing, and traceability, thereby promoting the trust and cooperation between the devices and ensuring the security and efficiency of the network in the large-scale untrustworthy IoT network. The blockchain-enhanced open IoT access architecture in the present invention can provide secure and reliable IoT access with low latency and a high value in practice.
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公开(公告)号:US20210226721A1
公开(公告)日:2021-07-22
申请号:US16302676
申请日:2017-09-22
Applicant: SOUTHEAST UNIVERSITY
Abstract: The invention discloses a beam domain optical wireless communication method and system. A base station is equipped with an array of optical transceiver ports or transmitter/receiver ports and a lens, each optical transceiver port forms a beam with centralized energy through the lens, and the base station generates beams in different directions by using the optical transceiver port array and the lens, thereby realizing multi-beam coverage or large-scale beam coverage in a communication region. The base station transmits/receives signals of multiple or a large number of user terminals by using channel state information of each user terminal, and different optical transceiver ports transmit/receive signals in different directions, thereby realizing simultaneous communication and bidirectional communication between the base station and different user terminals.
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