Jianhua Zhang scite author profile

This paper provides an overview of the features of fifth generation (5G) wireless communication systems now being developed for use in the millimeter wave (mmWave) frequency bands. Early results and key concepts of 5G networks are presented, and the channel modeling efforts of many international groups for both licensed and unlicensed applications are described here. Propagation parameters and channel models for understanding mmWave propagation, such as line-of-sight (LOS) probabilities, large-scale path loss, and building penetration loss, as modeled by various standardization bodies, are compared over the 0.5-100 GHz range.

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Emotion recognition using multi-modal data and machine learning techniques: A tutorial and review

Zhang

et al. 2020

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Deep Learning for Physical-Layer 5G Wireless Techniques: Opportunities, Challenges and Solutions

Huang

Guo

Gui

et al. 2020

IEEE Wireless Commun.

349

161

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The new demands for high-reliability and ultra-high capacity wireless communication have led to extensive research into 5G communications. However, the current communication systems, which were designed on the basis of conventional communication theories, significantly restrict further performance improvements and lead to severe limitations. Recently, the emerging deep learning techniques have been recognized as a promising tool for handling the complicated communication systems, and their potential for optimizing wireless communications has been demonstrated. In this article, we first review the development of deep learning solutions for 5G communication, and then propose efficient schemes for deep learning-based 5G scenarios. Specifically, the key ideas for several important deep learningbased communication methods are presented along with the research opportunities and challenges.In particular, novel communication frameworks of non-orthogonal multiple access (NOMA), massive 2 multiple-input multiple-output (MIMO), and millimeter wave (mmWave) are investigated, and their superior performances are demonstrated. We vision that the appealing deep learning-based wireless physical layer frameworks will bring a new direction in communication theories and that this work will move us forward along this road.

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Propagation Models and Performance Evaluation for 5G Millimeter-Wave Bands

Sun

Rappaport

Shafi³

et al. 2018

IEEE Trans. Veh. Technol.

243

146

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Fifth-generation (5G) wireless networks are expected to operate at both microwave and millimeter-wave (mmWave) frequency bands, including frequencies in the range of 24 to 86 GHz. Radio propagation models are used to help engineers design, deploy, and compare candidate wireless technologies, and have a profound impact on the decisions of almost every aspect of wireless communications. This paper provides a comprehensive overview of the channel models that will likely be used in the design of 5G radio systems. We start with a discussion on the framework of channel models, which consists of classical models of path loss versus distance, large-scale, and small-scale fading models, and multipleinput multiple-output channel models. Then, key differences between mmWave and microwave channel models are presented, and two popular mmWave channel models are discussed: the 3rd Generation Partnership Project model, which is adopted by the International Telecommunication Union, and the NYUSIM model, which was developed from several years of field measurements in New York City. Examples on how to apply the channel models are then given for several diverse applications demonstrating the wide impact of the models and their parameter values, where the performance comparisons of the channel models are done with promising hybrid beamforming approaches, including leveraging coordinated multipoint transmission. These results show that the answers to channel performance metrics, such as spectrum efficiency, coverage, hardware/signal processing requirements, etc., are extremely sensitive to the choice of channel models.

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Recognition of emotions using multimodal physiological signals and an ensemble deep learning model

Yin

Zhao

Wang

et al. 2017

Computer Methods and Programs in Biomedicine

344

123

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Jianhua Zhang

Overview of Millimeter Wave Communications for Fifth-Generation (5G) Wireless Networks—With a Focus on Propagation Models

Emotion recognition using multi-modal data and machine learning techniques: A tutorial and review

Deep Learning for Physical-Layer 5G Wireless Techniques: Opportunities, Challenges and Solutions

Propagation Models and Performance Evaluation for 5G Millimeter-Wave Bands

Recognition of emotions using multimodal physiological signals and an ensemble deep learning model

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