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5G Wireless: A Comprehensive Introduction [Pehme köide]

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  • Formaat: Paperback / softback, 672 pages, kõrgus x laius x paksus: 38x234x178 mm, kaal: 1120 g
  • Ilmumisaeg: 13-Jul-2021
  • Kirjastus: Addison Wesley
  • ISBN-10: 0136767141
  • ISBN-13: 9780136767145
Teised raamatud teemal:
5G Wireless: A Comprehensive IntroductionSuurem pilt
  • Formaat: Paperback / softback, 672 pages, kõrgus x laius x paksus: 38x234x178 mm, kaal: 1120 g
  • Ilmumisaeg: 13-Jul-2021
  • Kirjastus: Addison Wesley
  • ISBN-10: 0136767141
  • ISBN-13: 9780136767145
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780136767145.html
Märksõnad:
In 5G Wireless: A Comprehensive Introduction, renowned information technology author William Stallings presents a comprehensive and unified explanation of 5G’s key aspects, applications, and implications. Like Stallings’ other award-winning texts, this guide is designed to help students quickly find the information and gain the mastery they need to master this critical new technology. PowerPoint lecture slides will be available to instructors. Coverage includes:

  • Background and overview: A concise history of the development of cellular networks through 4G, introducing 5G’s motivation, characteristics, and technologies.
  • Application and use cases: A broad survey of both general application areas and specific use cases; includes coverage of implications for IoT, cloud, and fog computing. 
  • Air interface: A detailed survey of all aspects of radio transmission and the wireless interface.
  • 5G core: A survey of 5G core architecture and deployment. 
  • 5G security and privacy: Requirements, threats, vulnerabilities, security controls, security product and service solutions, and privacy.



Gain a Deep, Practical Understanding of 5G Technology, Applications, Architecture, Standards, and Ecosystem


The 5G ultra-high-speed wireless communication standard is a major technological leap forward--substantially increasing speed and capacity, enhancing current use cases, and making many new applications practical. For technical professionals, managers, and students, 5G requires significant new knowledge and expertise. In 5G Wireless: A Comprehensive Introduction, renowned information technology author William Stallings presents a comprehensive and unified explanation of 5G's key applications, technologies, and standards.


Like Stallings' other award-winning texts, this guide will help you quickly find the information and gain the mastery to succeed with critical new technology. Stallings first explains how cellular networks have evolved through 4G and now 5G, and surveys 5G's application areas and use cases. Next, he thoroughly introduces the 5G core network, covering SDN, NFV, network slicing, QoS, and edge computing--and provides a detailed coverage of the 5G air interface and radio access network. Throughout, key concepts are illuminated through realistic examples, review questions help you test your understanding, and references support further exploration.

  • Understand the 5G ecosystem, its building blocks, standards, and R&D roadmaps
  • Explore the Enhanced Mobile Broadband (eMBB) use case, where 5G enhances 4G in applications such as smart offices and dense urban communications
  • Learn how Massive Machine Type Communications (mMTC) and Ultra-Reliable and Low-Latency Communications (URLCC) support new applications such as fog, IoT, and cloud
  • Discover how 5G NextGen core (backbone) networks serve and interconnect wireless access networks that connect user devices
  • Master key 5G NR Air Interface and Radio Access Network (RAN) concepts, including millimeter-wave transmission, MIMO antennas, and OFDM multiplexing

Preface xxiv
Part I Overview
Chapter 1 Cellular Networks: Concepts And Evolution
2(34)
1.1 Evolution of Cellular Networks
2(2)
1.2 Cellular Network Concepts
4(10)
Cellular Organization
4(6)
Network System Elements
10(1)
Operation of Cellular Systems
11(3)
1.3 First Generation (1G)
14(1)
1.4 Second Generation (2G)
15(5)
Time-Division Multiple Access
16(1)
GSM Architecture
17(3)
Radio Link Aspects
20(1)
1.5 Third Generation (3G)
20(4)
Code-Division Multiple Access
21(1)
3G Architecture
21(3)
1.6 Fourth Generation (4G)
24(10)
E-UTRAN
26(3)
LTE-Advanced Transmission Characteristics
29(4)
Evolved Packet Core
33(1)
1.7 Key Terms and Review Questions
34(2)
Key Terms
34(1)
Review Questions
35(1)
Chapter 2 5G Standards And Specifications
36(40)
2.1 ITU-R and IMT-2020
37(20)
International Mobile Telecommunications
38(1)
Capabilities
38(3)
Usage Scenarios
41(2)
Use Cases
43(3)
Evaluation
46(11)
2.2 ITU-T and IMT-2020
57(8)
Requirements
57(2)
Network Slicing
59(2)
Fixed Mobile Convergence
61(1)
IMT-2020 Core Network Framework
62(3)
2.3 3GPP
65(7)
3GPP Releases
69(1)
Detailed Requirements
70(2)
2.4 Key Terms and Review Questions
72(2)
Key Terms
72(1)
Review Questions
73(1)
2.5 References and Documents
74(2)
References
74(1)
Documents
74(2)
Chapter 3 Overview Of 5G Use Cases And Architecture
76(26)
3.1 5G Use Cases
77(4)
ITU-R
77(1)
5G Americas
77(2)
NGMA Alliance
79(2)
3.2 NGMN 5G Architecture Framework
81(6)
Layered Functionality
82(3)
Network Slicing
85(2)
3.3 3GPP 5G Architecture
87(11)
5G Core Network Architecture
87(7)
Radio Access Network Architecture
94(3)
Session Establishment
97(1)
3.4 Key Terms and Review Questions
98(1)
Key Terms
98(1)
Review Questions
99(1)
3.5 References and Documents
99(3)
References
99(1)
Documents
100(2)
Part II Use Cases and Applications
Chapter 4 Enhanced Mobile Broadband
102(20)
4.1 eMBB Deployment Scenarios
103(2)
Indoor Hotspot
104(1)
Dense Urban
105(1)
Rural
105(1)
4.2 eMBB Performance Characteristics
105(5)
Data Rate Requirements
106(1)
Spectral Efficiency Requirements
107(1)
Latency Requirements
108(1)
Mobility Requirements
108(1)
System Requirements
109(1)
4.3 Smart Office: An Indoor Hotspot Use Case
110(1)
4.4 Dense Urban Information Society: A Dense Urban Use Case
111(2)
4.5 Radiocommunication Systems Between Train and Trackside: A Rural eMBB Use Case
113(5)
Elements of RSTT
114(1)
Applications of RSTT
114(2)
Broadband Connectivity for Passengers
116(1)
Linear Cell Architecture
117(1)
4.6 Key Terms and Review Questions
118(1)
Key Terms
118(1)
Review Questions
118(1)
4.7 References and Documents
119(3)
References
119(1)
Documents
119(3)
Chapter 5 Massive Machine Type Communications
122(44)
5.1 mMTC Performance Requirements
123(1)
5.2 The Internet of Things
124(9)
The Scope of the Internet of Things
125(3)
Things on the Internet of Things
128(1)
Components of IoT-Enabled Things
128(1)
Constrained Devices
129(1)
IoT and Cloud Context
130(3)
5.3 Relationship Between mMTC and the IoT
133(2)
5.4 Relationship Between mMTC and NB-IoT and eMTC
135(3)
Comparison of NB-IoT and eMTC
135(1)
Low-Power Wide Area (LPWA)
136(2)
5.5 Smart Agriculture
138(12)
Model of IoT Deployment
138(2)
Use Cases
140(5)
Precision Crop Management
145(5)
Network Performance Requirements
150(1)
5.6 Smart Cities
150(12)
Smart City Use Cases
151(7)
ICT Architecture for Smart Cities
158(2)
Network Performance Requirements
160(2)
5.7 Key Terms and Review Questions
162(1)
Key Terms
162(1)
Review Questions
163(1)
5.8 References and Documents
163(3)
References
163(1)
Documents
164(2)
Chapter 6 Ultra-Reliable And Low-Latency Communications
166(36)
6.1 URLLC Performance Requirements
167(4)
Latency
168(1)
Mobility
169(1)
Reliability
170(1)
NGMN Definitions
170(1)
6.2 URLLC Use Cases in Emerging Mission-Critical Applications
171(7)
Industrial Automation
171(1)
Ground Vehicles, Drones, and Robots
171(1)
Tactile Interaction
171(1)
Augmented Reality and Virtual Reality
172(4)
Emergencies, Disasters, and Public Safety
176(1)
Urgent Healthcare
176(1)
Intelligent Transportation
177(1)
6.3 URLLC Applications Based on Performance Requirements
178(4)
Higher Reliability and Lower Latency
179(1)
Higher Reliability, Higher Availability, and Lower Latency
180(1)
Very Low Latency
181(1)
Higher Accuracy Positioning
181(1)
Higher Availability
181(1)
Mission-Critical Services
182(1)
6.4 Industry 4.0
182(9)
Factory Automation Architecture
183(2)
Application Areas
185(2)
Use Cases
187(2)
Performance Requirements
189(2)
6.5 Unmanned Aircraft System Traffic Management
191(6)
UTM Architecture
192(2)
5G Performance Requirements for UTM
194(3)
6.6 Key Terms and Review Questions
197(2)
Key Terms
197(1)
Review Questions
198(1)
6.7 References and Documents
199(3)
References
199(1)
Documents
199(3)
Part III 5G NextGen Core Network
Chapter 7 Software-Defined Networking
202(32)
7.1 Evolving Network Requirements
203(1)
7.2 The SDN Approach
204(3)
Modern Network Requirements
204(1)
SDN Architecture
204(3)
Characteristics of Software-Defined Networking
207(1)
7.3 SDN Data Plane
207(2)
Data Plane Functions
207(2)
Data Plane Protocols
209(1)
7.4 OpenFlow
209(9)
Flow Table Structure
211(3)
Flow Table Pipeline
214(2)
The Use of Multiple Tables
216(1)
Group Table
217(1)
OpenFlow Protocol
217(1)
7.5 SDN Control Plane
218(7)
Control Plane Functions
218(2)
Southbound Interface
220(1)
Northbound Interface
220(3)
Eastbound Interface
223(1)
Westbound Interface
224(1)
7.6 SDN Application Plane
225(5)
Application Plane Architecture
225(1)
Northbound Interface
226(1)
Network Services Abstraction Layer
226(1)
Network Applications
226(4)
User Interface
230(1)
7.7 Key Terms and Review Questions
230(1)
Key Terms
230(1)
Review Questions
231(1)
7.8 References and Documents
231(3)
References
231(1)
Documents
232(2)
Chapter 8 Network Functions Virtualization
234(38)
8.1 Background and Motivation for NFV
235(1)
8.2 Virtual Machines and Containers
236(6)
Hypervisor
236(2)
Architectural Approaches
238(3)
Container Virtualization
241(1)
8.3 NFV Concepts
242(6)
Simple Example of the Use of NFV
245(1)
NFV Principles
246(1)
High-Level NFV Framework
246(2)
8.4 NFV Benefits and Requirements
248(2)
NFV Benefits
248(1)
NFV Requirements
249(1)
8.5 NFV Reference Architecture
250(2)
NFV Management and Orchestration
251(1)
Reference Points
251(1)
8.6 NFV Infrastructure
252(11)
Container Interface
253(3)
Deployment of NFVI Containers
256(1)
Logical Structure of NFVI Domains
257(1)
Compute Domain
258(2)
Hypervisor Domain
260(1)
Infrastructure Network Domain
261(2)
8.7 Virtualized Network Functions
263(4)
VNF Interfaces
263(1)
VNFC-to-VNFC Communication
264(2)
VNF Scaling
266(1)
8.8 SDN and NFV
267(2)
8.9 Key Terms and Review Questions
269(2)
Key Terms
269(1)
Review Questions
270(1)
8.10 References and Documents
271(1)
References
271(1)
Documents
271(1)
Chapter 9 Core Network Functionality, Qos, And Network Slicing
272(50)
9.1 Core Network Requirements
273(6)
Network Operational Requirements
273(2)
Basic Network Requirements
275(4)
9.2 Core Network Functional Architecture
279(12)
Tunneling
281(2)
PDU Session Establishment
283(4)
Policy Control Function
287(4)
9.3 Quality of Service
291(16)
QoS Capabilities
291(3)
QoS Architectural Framework
294(3)
QoS Classification, Marking, and Differentiation
297(1)
3GPP QoS Architecture
298(1)
QoS Parameters
299(2)
QoS Characteristics
301(2)
Standardized 5QI-to-QoS Characteristic Mapping
303(4)
9.4 Network Slicing
307(8)
Network Slicing Concepts
308(2)
Requirements for Network Slicing
310(2)
Identifying and Selecting a Network Slice
312(1)
Functional Aspects of Network Slicing
313(1)
Generic Slice Template
314(1)
9.5 SDN and NFV Support for 5G
315(4)
9.6 Key Terms and Review Questions
319(1)
Key Terms
319(1)
Review Questions
319(1)
9.7 References and Documents
320(2)
References
320(1)
Documents
320(2)
Chapter 10 Multi-Access Edge Computing
322(34)
10.1 MEC and 5G
323(1)
10.2 MEC Architectural Concepts
324(3)
10.3 ETSI MEC Architecture
327(6)
Design Principles
328(1)
MEC System Reference Architecture
329(3)
Related Elements
332(1)
10.4 MEC in NFV
333(2)
MEC Components Implemented as VNFs
333(2)
MEC Components Replaced by NFV Components
335(1)
MEC System-Level Components
335(1)
10.5 MEC Support for Network Slicing
335(1)
10.6 MEC Use Cases
336(13)
Consumer-Oriented Services
337(5)
Operator and Third-Party Services
342(2)
Network Performance and QoS Improvements
344(5)
10.7 3GPP Architecture for Enabling Edge Applications
349(4)
EDGEAPP Functional Architecture
350(2)
Synergized Mobile Edge Cloud Architecture
352(1)
10.8 Key Terms and Review Questions
353(1)
Key Terms
353(1)
Review Questions
353(1)
10.9 References and Documents
354(2)
References
354(1)
Documents
355(1)
Part IV 5G NR Air Interface and Radio Access Network
Chapter 11 Wireless Transmission
356(38)
11.1 Channel Capacity
357(4)
Nyquist Bandwidth
357(1)
Shannon Capacity Formula
358(3)
11.2 Line-of-Sight Transmission
361(3)
Refraction
362(1)
Optical and Radio Line of Sight
363(1)
11.3 Line-of-Sight Transmission Impairments
364(12)
Attenuation
364(1)
Free Space Loss
365(3)
Path Loss Exponent in Practical Cellular Systems
368(1)
Noise
369(3)
The Expression Eb/No
372(2)
Atmospheric Absorption
374(1)
Multipath
375(1)
Refraction
376(1)
11.4 Fading in the Mobile Environment
376(5)
Multipath Propagation
376(1)
The Effects of Multipath Propagation
377(1)
Types of Fading
378(1)
The Fading Channel
379(2)
11.5 Millimeter Wave Transmission for 5G
381(6)
Propagation Impairments
381(4)
Implications for 5G
385(2)
11.6 Key Terms and Review Questions
387(2)
Key Terms
387(1)
Review Questions
388(1)
11.7 References
389(1)
Annex 11A Decibels and Signal Strength
389(5)
Chapter 12 Antennas
394(30)
12.1 Channel Correction Mechanisms
394(5)
Adaptive Equalization
395(1)
Diversity Techniques
396(2)
Adaptive Modulation and Coding
398(1)
Forward Error Correction
398(1)
12.2 Introduction to Antennas
399(8)
Radiation Patterns
399(2)
Antenna Types
401(5)
Antenna Gain
406(1)
12.3 Multiple-Input/Multiple-Output (MIMO) Antennas
407(4)
MIMO Principles
408(2)
Multiple-User MIMO
410(1)
12.4 Advanced Cellular Antennas
411(9)
Evolution of Cellular Antennas
411(1)
Beamforming
412(4)
Active Antenna Systems
416(1)
Massive MIMO
417(3)
12.5 Key Terms and Review Questions
420(2)
Key Terms
420(1)
Review Questions
421(1)
12.6 References
422(2)
Chapter 13 Air Interface Physical Layer
424(32)
13.1 Modulation Schemes
424(14)
Modulation
425(1)
Amplitude-Shift Keying
425(1)
Frequency-Shift Keying
426(1)
Phase-Shift Keying
426(7)
Quadrature Amplitude Modulation
433(4)
π/2-BPSK
437(1)
13.2 OFDM, OFDMA, and SC-FDMA
438(10)
Orthogonal Frequency-Division Multiplexing
438(3)
OFDM Implementation
441(3)
Difficulties of OFDM
444(1)
Orthogonal Frequency-Division Multiple Access
445(1)
Single-Carrier FDMA
446(2)
13.3 Waveforms and Numerologies
448(3)
Numerology
448(1)
CP-OFDM
449(1)
DFT-S-OFDM
450(1)
13.4 Key Terms and Review Questions
451(2)
Key Terms
451(1)
Review Questions
452(1)
13.5 References and Documents
453(1)
References
453(1)
Documents
453(1)
Annex 13A Multiplexing and Multiple Access
453(3)
Multiplexing
453(2)
Multiple Access
455(1)
Chapter 14 Air Interface Channel Coding
456(38)
14.1 Transmission Errors
457(3)
Error Burst
457(1)
Data Transmission Channels
458(2)
14.2 Forward Error Correction
460(6)
Block Error Correction
460(2)
Hamming Distance
462(4)
14.3 Parity-Check Matrix Codes
466(5)
Encoding
469(1)
Error Detection
470(1)
Error Correction
470(1)
14.4 Low-Density Parity-Check Codes
471(7)
Code Construction
472(1)
Error Correction
473(3)
Encoding
476(2)
14.5 Polar Coding
478(6)
Polar Encoder
477(2)
Synthetic Channels
479(4)
Decoding
483(1)
14.6 3GPP Channel Coding Specification
484(4)
Quasi-Cyclic Low-Density Parity-Check Codes
485(1)
Polar Coding with CRC
486(2)
14.7 Hybrid Automatic Repeat Request
488(2)
14.8 Key Terms and Review Questions
490(1)
Key Terms
490(1)
Review Questions
490(1)
14.9 References and Documents
491(1)
References
491(1)
Documents
492(2)
Chapter 15 5G Radio Access Network
494(34)
15.1 Overall RAN Architecture
494(5)
15.2 RAN--Core Functional Split
499(3)
RAN Functional Areas
500(1)
Core Functional Areas
501(1)
15.3 RAN Channel Structure
502(3)
Logical Channel
503(1)
Transport Channels
503(1)
Physical Channels
504(1)
15.4 RAN Protocol Architecture
505(7)
Air Interface Protocol Architecture
505(3)
Channel Structure
508(1)
RAN--Core Network Interface Protocol Architecture
509(2)
Xn Interface Protocol Architecture
511(1)
15.5 NG RAN Transport Network
512(5)
15.6 Integrated Access and Backhaul
517(6)
IAB Architecture
519(1)
Parent/Child Relationship
520(1)
IAB Protocol Architecture
520(3)
15.7 Key Terms and Review Questions
523(2)
Key Terms
523(1)
Review Questions
524(1)
15.8 References and Documents
525(3)
References
525(1)
Documents
525(3)
Part V Appendixes
Appendix A Review Questions and Solutions 528(66)
Appendix B Glossary 594(10)
Appendix C Acronyms 604(4)
Index 608
Dr. William Stallings has made a unique contribution to understanding the broad sweep of technical developments in computer security, computer networking, and computer architecture. He has authored 20 textbooks, and, counting revised editions, more than 75 books on various aspects of these subjects. His writings have appeared in numerous ACM and IEEE publications, including the Proceedings of the IEEE and ACM Computing Reviews. He has 13 times received the award for the best computer science textbook of the year from the Text and Academic Authors Association. In over 30 years in the field, he has been a technical contributor, a technical manager, and an executive with several high-technology firms. He has designed and implemented both TCP/IP-based and OSIbased protocol suites on a variety of computers and operating systems, ranging from microcomputers to mainframes. Currently he is an independent consultant whose clients have included computer and networking manufacturers and customers, software development firms, and leading-edge government research institutions. He created and maintains the Computer Science Student Resource Site at ComputerScienceStudent.com. This site provides documents and links on a variety of subjects of general interest to computer science students (and professionals). He is a member of the editorial board of Cryptologia, a scholarly journal devoted to all aspects of cryptology. Dr. Stallings holds a PhD from M.I.T. in computer science and a B.S. from Notre Dame in electrical engineering.