Скачать книгу

2009.

      12. Rosen, K.H., Number Theory and Cryptography, in: Discrete Mathematics and its Applications, 7th ed, pp. 237–294, McGraw-Hill press, New York, USA, 2011.

      13. Rabah, K., Elliptic Curve ElGamal Encryption and Signature Schemes. Inf. Technol. J. (ITJ), 4, 3, 299–306, Pakistan, 2005.

      14. Yanofsky, N.S. and Mannucci, M.A., Complex Numbers, in: Quantum Computing for Computer Scientists, pp. 7–15, Cambridge University Press, Cambridge, UK, 2008.

      15. Yanofsky, N.S. and Mannucci, M.A., Complex Vector Spaces, in: Quantum Computing for Computer Scientists, pp. 29–66, Cambridge University Press, Cambridge, UK, 2008.

      16. Yanofsky, N.S. and Mannucci, M.A., Basic Quantum Theory, in: Quantum Computing for Computer Scientists, pp. 103–132, Cambridge University Press, Cambridge, UK, 2008.

      17. Yanofsky, N.S. and Mannucci, M.A., Cryptography, in: Quantum Computing for Computer Scientists, pp. 262–283, Cambridge University Press, Cambridge, UK, 2008.

      1 *Corresponding author: [email protected]

      2 †Corresponding author: [email protected]

      5

      Application of Machine Learning Framework for Next-Generation Wireless Networks: Challenges and Case Studies

       Satyendra Singh Yadav1, Shrishail Hiremath2*, Pravallika Surisetti2, Vijay Kumar3 and Sarat Kumar Patra4

       1Department of ECE, National Institute of Technology Meghalaya, Meghalaya, India

       2Department of ECE, National Institute of Technology Rourkela, Odisha, India

       3Centre for Nano Science and Engineering, Indian Institute of Science, Bangalore, India

       4Indian Institute of Information Technology Vadodara, Gujarat, India

       Abstract

      Wireless communication has become an indispensable part of today’s life. Rapid growth in information and communication technologies (ICTs) along with advances in high-performance computing has witnessed a proliferation of efficient parallel and distributed computing algorithms. Presence of these with cloud computing platforms has provided a strong ecosystem for machine learning (ML) and deep learning (DL) techniques. These help to solve many of the problems like classification, optimization, and estimation, to name a few. This chapter highlights trends in fifth-generation (5G) wireless communication and beyond. This chapter further discusses use of ML algorithms in future wireless networks. These studies are expected to provide possible solutions to major challenges in the current and forthcoming wireless technology. 5G system is also expected to provide a foundation for intelligent wireless networks to handle converged applications. ML-based signal processing algorithms have the potential to solve network issues with 5G networks, thereby paving the way to the development of beyond 5G (B5G) intelligent wireless networks. This chapter presents a unified application of data science for wireless communication and analyzes the physical layer challenges for automatic modulation classification (AMC), resource allocation, channel estimation, and millimeter wave communication. Further case studies have been carried out on AMC and channel state information (CSI) feedback in massive multi-input and multi-output (MIMO) systems. The performance of the proposed DL methods has been presented through extensive simulation results.

      Keywords: 5G, beyond 5G, wireless communication, machine learning, modulation classification, MIMO, data science

      Recent advancement in computing systems has led to proliferation in use of machine learning (ML) and deep learning (DL) algorithms. These are used to solve the classification, estimation, and optimization problems for wireless systems which include modulation classification, signal detection, channel estimation, and resource allocation (RA) to name a few [1, 2]. Even though the ML is extensively applied in various application areas, its use in communications systems is still uncultivated [1, 3–5]. DL is the subset of ML paradigm. The key effect of applying the DL in the communications systems has been computational complexity issues and availability of benchmark data sets [6, 7]. DL typically consists of two stages named as training and testing. In the first stage, a huge data is passed through DL networks to generate a trained model, and training stage always runs with billions of computations. In the testing phase, data set other than the training data set is offered to the network model to deduce a outcome, and this stage needs to conclude in a desired time period [8, 9]. In practical implementation of real communications systems only the testing phase is applied. The training phase is usually completed offline. A trained DL model can thus achieve multiple objectives without the need for retraining [10, 11].

      With the increased demand for higher data rate services supporting multimedia, video, voice, and Internet of Things (IoT) application over wired and wireless links, new model-driven signal processing algorithms provide feasible solution to massive connectivity. These techniques should possess capability to provide high data rate at permissible Quality of Service (QoS), with ultra-reliable low latency (URLL) [12]. To meet the above requirements, future wireless network use ML algorithms as one of the key solutions. Artificial intelligence (AI)/ML algorithm potentially can provide intelligent future networks along with desired URLL [13, 14]. In wireless systems, a ML-based algorithm can be applied at the transmitter side, either to enhance the performance of single block or jointly at transmitter and receiver to develop an intelligent wireless system. Most of the present (4G) and future wireless systems (5G) are employed with orthogonal frequency division multiplexing (OFDM) in conjunction with massive multi-input multi-output (MIMO) technology to provide desired service standards [9, 15, 14]. The advancement of intelligent terminals and promising new applications (e.g., real-time and communicating services), wireless communication data traffic has radically enhanced, and existing wireless systems (even an upcoming 5G) cannot entirely meet the quickly rising technological requirements [13, 16, 17]. To meet these upcoming challenges, the beyond 5G (B5G) or sixth-generation (6G) wireless network is anticipated to explore the novel radio spectrum standards and energy-efficient transmission techniques along with intelligent wireless networks [2, 18].

      To address the future upcoming challenges, a comprehensive review of existing literature has been performed in this chapter. Further, case studies on automatic modulation classification (AMC) and channel state information (CSI) feedback for frequency division duplexing (FDD) massive MIMO system has been carried out using novel DL techniques. The simulation results for the proposed method for AMC shows up to 10% improvement in the prediction accuracy compared to the existing baseline model [19]. In case of CSI feedback in massive MIMO, implementation results using the proposed algorithm have shown superior recovery of the channel matrix with cosine similarity of around 5% and the reduction in normalized mean square error (NMSE) is approximately 2 dB for different compression ratios in comparison to the baseline network [20].

      A typical wireless communication

Скачать книгу