Deep Convolutional Neural Network-Based Detector for Index Modulation

被引：25

作者：

Wang, Tengjiao ^{[1
,2
]}

Yang, Fang ^{[1
,2
]}

Song, Jian ^{[1
,2
]}

Han, Zhu ^{[3
,4
,5
]}

机构：

[1] Tsinghua Univ, Beijing Natl Res Ctr Informat Sci & Technol, Dept Elect Engn, Beijing 100084, Peoples R China

[2] Tsinghua Univ, Key Lab Digital TV Syst Guangdong Prov & Shenzhen, Res Inst, Shenzhen 518057, Peoples R China

[3] Univ Houston, Elect & Comp Engn Dept, Houston, TX 77004 USA

[4] Univ Houston, Comp Sci Dept, Houston, TX 77004 USA

[5] Kyung Hee Univ, Dept Comp Sci & Engn, Seoul 446701, South Korea

来源：

IEEE WIRELESS COMMUNICATIONS LETTERS | 2020年 / 9卷 / 10期

基金：

中国国家自然科学基金;

关键词：

Detectors; Training; Neural networks; OFDM; Indexes; Wireless communication; Signal to noise ratio; Convolutional neural network; deep learning; index modulation; polar coordinates; maximum likelihood; CHANNEL ESTIMATION; SIGNAL-DETECTION; OFDM; SCHEME;

D O I：

10.1109/LWC.2020.3001731

中图分类号：

TP [自动化技术、计算机技术];

学科分类号：

0812 ;

摘要：

In this letter, a convolutional neural network-based detection framework is proposed for the wireless communication systems using orthogonal frequency-division multiplexing with index modulation (OFDM-IM). In the proposed framework, the received symbols are transformed to polar coordinates to help the neural network detect the indices of the activated subcarriers. We parallel the amplitude and the phase of the received symbols to form 2-dimensional matrices and use 2-dimensional convolutional layers to fully exploit the inherent information in the OFDM-IM symbols. After offline training, the proposed detector can be employed to implement online detection of the OFDM-IM symbols. Simulation results demonstrate that the proposed detector is capable of achieving near maximum likelihood detection performance with much lower complexity.

引用

页码：1705 / 1709

页数：5

共 15 条

[1] Index Modulation Techniques for Next-Generation Wireless Networks [J].

Basar, Ertugrul ;

Wen, Miaowen ;

Mesleh, Raed ;

Di Renzo, Marco ;

Xiao, Yue ;

Haas, Harald .

IEEE ACCESS, 2017, 5 :16693-16746

[2] Orthogonal Frequency Division Multiplexing With Index Modulation [J].

Basar, Ertugrul ;

Aygolu, Umit ;

Panayirci, Erdal ;

Poor, H. Vincent .

IEEE TRANSACTIONS ON SIGNAL PROCESSING, 2013, 61 (22) :5536-5549

[3]

Crawford J, 2015, 2015 IEEE 26TH ANNUAL INTERNATIONAL SYMPOSIUM ON PERSONAL, INDOOR, AND MOBILE RADIO COMMUNICATIONS (PIMRC), P688, DOI 10.1109/PIMRC.2015.7343386

[4] ComNet: Combination of Deep Learning and Expert Knowledge in OFDM Receivers [J].

Gao, Xuanxuan ;

Jin, Shi ;

Wen, Chao-Kai ;

Li, Geoffrey Ye .

IEEE COMMUNICATIONS LETTERS, 2018, 22 (12) :2627-2630

[5] OFDM and Its Wireless Applications: A Survey [J].

Hwang, Taewon ;

Yang, Chenyang ;

Wu, Gang ;

Li, Shaoqian ;

Li, Geoffrey Ye .

IEEE TRANSACTIONS ON VEHICULAR TECHNOLOGY, 2009, 58 (04) :1673-1694

[6] ImageNet Classification with Deep Convolutional Neural Networks [J].

Krizhevsky, Alex ;

Sutskever, Ilya ;

Hinton, Geoffrey E. .

COMMUNICATIONS OF THE ACM, 2017, 60 (06) :84-90

[7] An Introduction to Deep Learning for the Physical Layer [J].

O'Shea, Timothy ;

Hoydis, Jakob .

IEEE TRANSACTIONS ON COGNITIVE COMMUNICATIONS AND NETWORKING, 2017, 3 (04) :563-575

[8]

Paszke A., 2017, P 31 ANN C NEUR INF

[9] Deep learning [J].

Rusk, Nicole .

NATURE METHODS, 2016, 13 (01) :35-35

[10] Joint channel estimation and decoding in the presence of phase noise over time-selective flat-fading channels [J].

Shi, Qiaolin ;

Wu, Nan ;

Wang, Hua ;

Yuan, Weijie .

IET COMMUNICATIONS, 2016, 10 (05) :577-585

← 1 2 →