Your search keyword '"Gao, Jiabao"' showing total 24 results

1. Deep unfolding based channel estimation for wideband terahertz near-field massive MIMO systems

Author

Gao, Jiabao, Chen, Xiaoming, and Li, Geoffrey Ye

Published

2024

2. Water-nitrogen Managements for Spring Maize at Tuquan, Inner Mongolia Based on APSIM

Author

Guo Erjing, Yang Feiyun, Wu Lu, Sun Shuang, Gao Jiabao, Zhang Chaoqun, and Zhang Ling

Subjects

spring maize, yield, water productivity, agronomic efficiency of applied nitrogen, water-nitrogen management, Meteorology. Climatology, QC851-999

Abstract

Water and nitrogen are critical factors that constrain the sustainable production of dryland agriculture. With increasingly severe crisis of water and nitrogen resources and environment, exploring and optimizing water-nitrogen managements, and hence achieving coordinated and unified resource conservation, high and stable grain production, and high efficiency are of great significance for agricultural development. Key parameters of APSIM (agricultural production system simulator) are calibrated and validated based on spring maize phenology, yield, and field management data from Tuquan, Inner Mongolia Autonomous Region from 2013 to 2022. Combined with meteorological data from 1981 to 2022 at Tuquan, water-nitrogen management scenarios are designed under different water deficit levels. Optimal water-nitrogen managements for spring maize at Tuquan are proposed based on indicators including spring maize yield, irrigation amount, nitrogen application amount, water productivity, and agronomic efficiency of applied nitrogen. Furthermore, the suitable irrigation and nitrogen application amounts for spring maize under different precipitation year types are analyzed. Results show that normalized root mean squared errors of the simulated and observed days from emergence to flowering, days from emergence to maturity, and yield of spring maize are 1.3%, 1.2% and 2.8%, respectively. APSIM can quantitatively simulate the growth period and yield of spring maize. Based on the principle that yield, water productivity, and agronomic efficiency of applied nitrogen of spring maize do not significantly decrease compared to the maximum values of all scenarios, and irrigation and nitrogen application amounts do not significantly increase compared to the minimum values of all scenarios, four management measures with no significant differences can be selected, namely, starting automatic irrigation when water deficit reaches 40%, 50%, 60% at the depth of 0-100 cm, and when the water deficit reaches 60% at the depth of 0-60 cm. Among them, the optimal auto-irrigation management for spring maize at Tuquan is to apply irrigation when the water deficit reaches 60% at the depth of 0-100 cm. In this scenario, the irrigation amount is 171.0 mm, and the nitrogen application amount is 197.8 kg·hm-2. When the precipitation during the spring maize growing season is 200-400 mm, the appropriate irrigation amount is 233.0-283.5 mm, and the nitrogen application amount is 176.9-219.3 kg·hm-2. When the precipitation during the spring maize growing season is 401-600 mm, the appropriate irrigation amount is 110.5-148.4 mm, and the nitrogen application amount is 218.3-241.5 kg·hm-2, respectively. When the precipitation during the spring maize growing season is 601-800 mm, the suitable irrigation amount is 125.0-155.0 mm, and the nitrogen application amount is 211.8-249.9 kg·hm-2. This study provides a quantitative reference for utilizing crop mechanism models in real-time monitoring, diagnosis, and precise management of crop water and nitrogen.

Published

2024

3. Deep Unfolding-Based Channel Estimation for Wideband TeraHertz Near-Field Massive MIMO Systems

Author

Gao, Jiabao, Cheng, Xiaoming, and Li, Geoffrey Ye

Subjects

Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing

Abstract

The combination of Terahertz (THz) and massive multiple-input multiple-output (MIMO) is promising to meet the increasing data rate demand of future wireless communication systems thanks to the huge bandwidth and spatial degrees of freedom. However, unique channel features such as the near-field beam split effect make channel estimation particularly challenging in THz massive MIMO systems. On one hand, adopting the conventional angular domain transformation dictionary designed for low-frequency far-field channels will result in degraded channel sparsity and destroyed sparsity structure in the transformed domain. On the other hand, most existing compressive sensing-based channel estimation algorithms cannot achieve high performance and low complexity simultaneously. To alleviate these issues, in this paper, we first adopt frequency-dependent near-field dictionaries to maintain good channel sparsity and sparsity structure in the transformed domain under the near-field beam split effect. Then, a deep unfolding-based wideband THz massive MIMO channel estimation algorithm is proposed. In each iteration of the unitary approximate message passing-sparse Bayesian learning algorithm, the optimal update rule is learned by a deep neural network (DNN), whose structure is customized to effectively exploit the inherent channel patterns. Furthermore, a mixed training method based on novel designs of the DNN structure and the loss function is developed to effectively train data from different system configurations. Simulation results validate the superiority of the proposed algorithm in terms of performance, complexity, and robustness.

Published

2023

4. AMP-SBL Unfolding for Wideband MmWave Massive MIMO Channel Estimation

Author

Gao, Jiabao, Zhong, Caijun, and Li, Geoffrey Ye

Subjects

Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing

Abstract

In wideband millimeter wave (mmWave) massive multiple-input multiple-output (MIMO) systems, channel estimation is challenging due to the hybrid analog-digital architecture, which compresses the received pilot signal and makes channel estimation a compressive sensing (CS) problem. However, existing high-performance CS algorithms usually suffer from high complexity. On the other hand, the beam squint effect caused by huge bandwidth and massive antennas will deteriorate estimation performance. In this paper, frequency-dependent angular dictionaries are first adopted to compensate for beam squint. Then, the expectation-maximization (EM)-based sparse Bayesian learning (SBL) algorithm is enhanced in two aspects, where the E-step in each iteration is implemented by approximate message passing (AMP) to reduce complexity while the M-step is realized by a deep neural network (DNN) to improve performance. In simulation, the proposed AMP-SBL unfolding-based channel estimator achieves satisfactory performance with low complexity.

Published

2023

5. Spatially Sparse Precoding in Wideband Hybrid Terahertz Massive MIMO Systems

Author

Gao, Jiabao, Zhong, Caijun, Li, Geoffrey Ye, Soriaga, Joseph B., and Behboodi, Arash

Subjects

Computer Science - Information Theory

Abstract

In terahertz (THz) massive multiple-input multiple-output (MIMO) systems, the combination of huge bandwidth and massive antennas results in severe beam split, thus making the conventional phase-shifter based hybrid precoding architecture ineffective. With the incorporation of true-time-delay (TTD) lines in the hardware implementation of the analog precoders, delay-phase precoding (DPP) emerges as a promising architecture to effectively overcome beam split. However, existing DPP approaches suffer from poor performance, high complexity, and weak robustness in practical THz channels. In this paper, we propose a novel DPP approach in wideband THz massive MIMO systems. First, the optimization problem is converted into a compressive sensing (CS) form, which can be solved by the extended spatially sparse precoding (SSP) algorithm. To compensate for beam split, frequency-dependent measurement matrices are introduced, which can be approximately realized by feasible phase and delay codebooks. Then, several efficient atom selection techniques are developed to further reduce the complexity of extended SSP. In simulation, the proposed DPP approach achieves superior performance, complexity, and robustness by using it alone or in combination with existing DPP approaches.

Published

2022

6. Learn to Adapt to New Environment from Past Experience and Few Pilot

Author

Wang, Ouya, Gao, Jiabao, and Li, Geoffrey Ye

Subjects

Computer Science - Information Theory, Computer Science - Machine Learning

Abstract

In recent years, deep learning has been widely applied in communications and achieved remarkable performance improvement. Most of the existing works are based on data-driven deep learning, which requires a significant amount of training data for the communication model to adapt to new environments and results in huge computing resources for collecting data and retraining the model. In this paper, we will significantly reduce the required amount of training data for new environments by leveraging the learning experience from the known environments. Therefore, we introduce few-shot learning to enable the communication model to generalize to new environments, which is realized by an attention-based method. With the attention network embedded into the deep learning-based communication model, environments with different power delay profiles can be learnt together in the training process, which is called the learning experience. By exploiting the learning experience, the communication model only requires few pilot blocks to perform well in the new environment. Through an example of deep-learning-based channel estimation, we demonstrate that this novel design method achieves better performance than the existing data-driven approach designed for few-shot learning., Comment: 11 pages, 8 figures

Published

2022

7. A Deep Learning-Based Framework for Low Complexity Multi-User MIMO Precoding Design

Author

Zhang, Maojun, Gao, Jiabao, and Zhong, Caijun

Subjects

Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing

Abstract

Using precoding to suppress multi-user interference is a well-known technique to improve spectra efficiency in multiuser multiple-input multiple-output (MU-MIMO) systems, and the pursuit of high performance and low complexity precoding method has been the focus in the last decade. The traditional algorithms including the zero-forcing (ZF) algorithm and the weighted minimum mean square error (WMMSE) algorithm failed to achieve a satisfactory trade-off between complexity and performance. In this paper, leveraging on the power of deep learning, we propose a low-complexity precoding design framework for MU-MIMO systems. The key idea is to transform the MIMO precoding problem into the multiple-input single-output precoding problem, where the optimal precoding structure can be obtained in closed-form. A customized deep neural network is designed to fit the mapping from the channels to the precoding matrix. In addition, the technique of input dimensionality reduction, network pruning, and recovery module compression are used to further improve the computational efficiency. Furthermore, the extension to the practical MIMO orthogonal frequency-division multiplexing (MIMO-OFDM) system is studied. Simulation results show that the proposed low-complexity precoding scheme achieves similar performance as the WMMSE algorithm with very low computational complexity.

Published

2022

8. Deep Learning-based Channel Estimation for Wideband Hybrid MmWave Massive MIMO

Author

Gao, Jiabao, Zhong, Caijun, Li, Geoffrey Ye, Soriaga, Joseph B., and Behboodi, Arash

Subjects

Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing

Abstract

Hybrid analog-digital (HAD) architecture is widely adopted in practical millimeter wave (mmWave) massive multiple-input multiple-output (MIMO) systems to reduce hardware cost and energy consumption. However, channel estimation in the context of HAD is challenging due to only limited radio frequency (RF) chains at transceivers. Although various compressive sensing (CS) algorithms have been developed to solve this problem by exploiting inherent channel sparsity and sparsity structures, practical effects, such as power leakage and beam squint, can still make the real channel features deviate from the assumed models and result in performance degradation. Also, the high complexity of CS algorithms caused by a large number of iterations hinders their applications in practice. To tackle these issues, we develop a deep learning (DL)-based channel estimation approach where the sparse Bayesian learning (SBL) algorithm is unfolded into a deep neural network (DNN). In each SBL layer, Gaussian variance parameters of the sparse angular domain channel are updated by a tailored DNN, which is able to effectively capture complicated channel sparsity structures in various domains. Besides, the measurement matrix is jointly optimized for performance improvement. Then, the proposed approach is extended to the multi-block case where channel correlation in time is further exploited to adaptively predict the measurement matrix and facilitate the update of Gaussian variance parameters. Based on simulation results, the proposed approaches significantly outperform existing approaches but with reduced complexity.

Published

2022

9. Abnormal grain growth behavior in gradient nanostructured titanium investigated by coupled quasi-in-situ EBSD experiments and phase-field simulations

Author

Peng, Wei, Li, Xiao, Gao, Jiabao, He, Chenyun, Zhang, Yong, Lu, Tiwen, Zhang, Xiancheng, Zhang, Lijun, Sun, Binhan, and Tu, Shantung

Published

2024

10. Online Deep Neural Network for Optimization in Wireless Communications

Author

Gao, Jiabao, Zhong, Caijun, Li, Geoffrey Ye, and Zhang, Zhaoyang

Subjects

Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing

Abstract

Recently, deep neural network (DNN) has been widely adopted in the design of intelligent communication systems thanks to its strong learning ability and low testing complexity. However, most current offline DNN-based methods still suffer from unsatisfactory performance, limited generalization ability, and poor interpretability. In this article, we propose an online DNN-based approach to solve general optimization problems in wireless communications, where a dedicated DNN is trained for each data sample. By treating the optimization variables and the objective function as network parameters and loss function, respectively, the optimization problem can be solved equivalently through network training. Thanks to the online optimization nature and meaningful network parameters, the proposed approach owns strong generalization ability and interpretability, while its superior performance is demonstrated through a practical example of joint beamforming in intelligent reflecting surface (IRS)-aided multi-user multiple-input multiple-output (MIMO) systems. Simulation results show that the proposed online DNN outperforms conventional offline DNN and state-of-the-art iterative optimization algorithm, but with low complexity.

Published

2022

11. Deep Learning based Channel Estimation for Massive MIMO with Hybrid Transceivers

Author

Gao, Jiabao, Zhong, Caijun, Li, Geoffrey Ye, and Zhang, Zhaoyang

Subjects

Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing

Abstract

Accurate and efficient estimation of the high dimensional channels is one of the critical challenges for practical applications of massive multiple-input multiple-output (MIMO). In the context of hybrid analog-digital (HAD) transceivers, channel estimation becomes even more complicated due to information loss caused by limited radio-frequency chains. The conventional compressive sensing (CS) algorithms usually suffer from unsatisfactory performance and high computational complexity. In this paper, we propose a novel deep learning (DL) based framework for uplink channel estimation in HAD massive MIMO systems. To better exploit the sparsity structure of channels in the angular domain, a novel angular space segmentation method is proposed, where the entire angular space is segmented into many small regions and a dedicated neural network is trained offline for each region. During online testing, the most suitable network is selected based on the information from the global positioning system. Inside each neural network, the region-specific measurement matrix and channel estimator are jointly optimized, which not only improves the signal measurement efficiency, but also enhances the channel estimation capability. Simulation results show that the proposed approach significantly outperforms the state-of-the-art CS algorithms in terms of estimation performance and computational complexity.

Published

2022

12. An Attention-Aided Deep Learning Framework for Massive MIMO Channel Estimation

Author

Gao, Jiabao, Hu, Mu, Zhong, Caijun, Li, Geoffrey Ye, and Zhang, Zhaoyang

Subjects

Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing

Abstract

Channel estimation is one of the key issues in practical massive multiple-input multiple-output (MIMO) systems. Compared with conventional estimation algorithms, deep learning (DL) based ones have exhibited great potential in terms of performance and complexity. In this paper, an attention mechanism, exploiting the channel distribution characteristics, is proposed to improve the estimation accuracy of highly separable channels with narrow angular spread by realizing the "divide-and-conquer" policy. Specifically, we introduce a novel attention-aided DL channel estimation framework for conventional massive MIMO systems and devise an embedding method to effectively integrate the attention mechanism into the fully connected neural network for the hybrid analog-digital (HAD) architecture. Simulation results show that in both scenarios, the channel estimation performance is significantly improved with the aid of attention at the cost of small complexity overhead. Furthermore, strong robustness under different system and channel parameters can be achieved by the proposed approach, which further strengthens its practical value. We also investigate the distributions of learned attention maps to reveal the role of attention, which endows the proposed approach with a certain degree of interpretability.

Published

2021

13. Deep Reinforcement Learning for Joint Beamwidth and Power Optimization in mmWave Systems

Author

Gao, Jiabao, Zhong, Caijun, Chen, Xiaoming, Lin, Hai, and Zhang, Zhaoyang

Subjects

Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing

Abstract

This paper studies the joint beamwidth and transmit power optimization problem in millimeter wave communication systems. A deep reinforcement learning based approach is proposed. Specifically, a customized deep Q network is trained offline, which is able to make real-time decisions when deployed online. Simulation results show that the proposed approach significantly outperforms conventional approaches in terms of both performance and complexity. Besides, strong generalization ability to different system parameters is also demonstrated, which further enhances the practicality of the proposed approach.

Published

2020

14. Unsupervised Learning for Passive Beamforming

Author

Gao, Jiabao, Zhong, Caijun, Chen, Xiaoming, Lin, Hai, and Zhang, Zhaoyang

Subjects

Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing

Abstract

Reconfigurable intelligent surface (RIS) has recently emerged as a promising candidate to improve the energy and spectral efficiency of wireless communication systems. However, the unit modulus constraint on the phase shift of reflecting elements makes the design of optimal passive beamforming solution a challenging issue. The conventional approach is to find a suboptimal solution using the semi-definite relaxation (SDR) technique, yet the resultant suboptimal iterative algorithm usually incurs high complexity, hence is not amenable for real-time implementation. Motivated by this, we propose a deep learning approach for passive beamforming design in RIS-assisted systems. In particular, a customized deep neural network is trained offline using the unsupervised learning mechanism, which is able to make real-time prediction when deployed online. Simulation results show that the proposed approach maintains most of the performance while significantly reduces computation complexity when compared with SDR-based approach., Comment: 5 pages, 6 figures, 2 tables

Published

2020

15. Deep Learning for Spectrum Sensing

Author

Gao, Jiabao, Yi, Xuemei, Zhong, Caijun, Chen, Xiaoming, and Zhang, Zhaoyang

Subjects

Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing

Abstract

In cognitive radio systems, the ability to accurately detect primary user's signal is essential to secondary user in order to utilize idle licensed spectrum. Conventional energy detector is a good choice for blind signal detection, while it suffers from the well-known SNR-wall due to noise uncertainty. In this letter, we firstly propose a deep learning based signal detector which exploits the underlying structural information of the modulated signals, and is shown to achieve the state of the art detection performance, requiring no prior knowledge about channel state information or background noise. In addition, the impacts of modulation scheme and sample length on performance are investigated. Finally, a deep learning based cooperative detection system is proposed, which is shown to provide substantial performance gain over conventional cooperative sensing methods., Comment: 4 pages, 6 figures

Published

2019

16. Integrated Localization and Communication for IRS-Assisted Multi-User mmWave MIMO Systems

Author

Peng, Xingyu, Hu, Xiaoling, Gao, Jiabao, Jin, Richeng, Chen, Xiaoming, and Zhong, Caijun

Abstract

This paper delves into the potential of intelligent reflecting surfaces (IRSs) in enabling integrated sensing and communication (ISAC) in multi-user multi-path scenarios. We introduce a three-dimensional (3D) multi-user ISAC framework with distributed IRSs, which offers simultaneous signal demodulation, channel estimation, and localization. The transmission is divided into a user access stage and a downlink transmission stage. In the first stage, we propose an algorithm for simultaneous uplink signal demodulation and angles of arrival (AoA) estimation at the semi-passive IRS. Moreover, a joint active and passive beamforming scheme inspired by radar-communication, is proposed to enhance both communication and localization performance in the downlink stage, while eliminating the need for distinct localization reference signals. Numerical results demonstrate that the proposed ISAC framework achieves centimeter-level localization accuracy while maintaining comparable communication performance to communication-only systems, thus validating its effectiveness.

Published

2024

17. Self-Adaptive Measurement Matrix Design and Channel Estimation in Time-Varying Hybrid MmWave Massive MIMO-OFDM Systems

Author

Lin, Chenlan, Gao, Jiabao, Jin, Richeng, and Zhong, Caijun

Abstract

Channel estimation in hybrid massive multiple input multiple output (MIMO) orthogonal frequency division multiplexing (OFDM) systems is challenging as only low-dimensional channel measurement can be obtained at the receiver while the true channel is high-dimensional. In the compressed sensing (CS) based channel estimation algorithms, a well-designed measurement matrix will contribute to better estimation performance. Therefore, a temporal correlation-based self-adaptive measurement matrix design (TC-SAMMD) method is proposed, and the corresponding frame structure and channel estimation technique are developed in this paper. Specifically, pilots are transmitted twice during each block, and the process of channel estimation contains three steps: time-varying channel estimation by Kalman filtering, self-adaptive measurement matrix design, and two pilots-based channel estimation via the simultaneous orthogonal matching pursuit (SOMP) algorithm. Simulation results demonstrate that the proposed TC-SAMMD method outperforms conventional measurement matrix design approaches in terms of the channel estimation error, thanks to the “adaptiveness” to the channel’s characteristics in consecutive blocks. Besides, it is shown that the TC-SAMMD strategy with a full-ranged innovation noise can effectively mitigate the performance degradation caused by the angle shifts.

Published

2024

18. Deep Learning-based Channel Estimation for Wideband Hybrid MmWave Massive MIMO

Author

Gao, Jiabao, primary, Zhong, Caijun, additional, Li, Geoffrey Ye, additional, Soriaga, Joseph B., additional, and Behboodi, Arash, additional

Published

2023

19. Self-Adaptive Measurement Matrix Design and Channel Estimation in Time-Varying Hybrid MmWave Massive MIMO-OFDM Systems

Author

Lin, Chenlan, primary, Gao, Jiabao, additional, Jin, Richeng, additional, and Zhong, Caijun, additional

Published

2023

20. Rapid Microstructure Homogenization of a Laser Melting Deposition Additive Manufactured Ti-6.5Al-3.5Mo-1.5Zr-0.3Si Alloy by Electropulsing

Author

Ben, Dandan, primary, Yang, Huajie, additional, Gao, Jiabao, additional, Yang, Bingyu, additional, Dong, Yu’ang, additional, Liu, Xiangyu, additional, Wang, Xuegang, additional, Duan, Qiqiang, additional, Zhang, Peng, additional, and Zhang, Zhefeng, additional

Published

2022

21. Arsenic speciation transformation in soils with high geological background: New insights from the governing role of Fe

Author

Gao, Manshu, primary, Su, Yue, additional, Gao, Jiabao, additional, Zhong, Xinwei, additional, Li, Hao, additional, Wang, Haoji, additional, Lü, Changwei, additional, and He, Jiang, additional

Published

2022

22. An Efficient Channel-Aware Sparse Binarized Neural Networks Inference Accelerator

Author

Liu, Qingliang, primary, Lai, Jinmei, additional, and Gao, Jiabao, additional

Published

2022

23. An Approach of Binary Neural Network Energy-Efficient Implementation

Author

Gao, Jiabao, primary, Liu, Qingliang, additional, and Lai, Jinmei, additional

Published

2021

24. SAFS: Object Tracking Algorithm Based on Self-Adaptive Feature Selection

Author

Guo, Wenhua, primary, Gao, Jiabao, additional, Tian, Yanbin, additional, Yu, Fan, additional, and Feng, Zuren, additional

Published

2021