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High-density and de-densified smart campus communications : technologies, integration, implementation and applications / Daniel Minoli, Jo-Anne Dressendofer.

O'Reilly Online Learning: Academic/Public Library Edition Available online

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Format:
Book
Author/Creator:
Minoli, Daniel, 1952- author.
Dressendofer, Jo-Anne, author.
Language:
English
Subjects (All):
Wireless communication systems.
Smart materials.
Physical Description:
1 online resource (366 pages)
Place of Publication:
Hoboken, New Jersey : John Wiley & Sons, Inc., [2022]
Summary:
"High-density campus communications have traditionally been important in many environments, including airports; stadiums; convention centers; shopping malls; classrooms; hospitals; cruise ships; train and subway stations; evangelical megachurches; large multiple dwelling units; boardwalks; (special events in) parks; dense smart cities; and other venues. These communications span several domains: people-to-people, people-to-websites, people-to-applications, sensors-to-cloud analytics, and machines-to-machines/device-to-device. While the later Internet of Things (IoT) applications are generally (but not always) low speed, the former applications are typically high-speed. In many settings, people access videos (a la Over The Top [OTT] mode) or websites and applications that often include short videos or other high data-rate content. Deploying optimally-performing high-density campus communication systems is desired and required in many cases, but it can, at the same time, be a complex task to undertake successfully."-- Provided by publisher.
Contents:
Cover
Title Page
Copyright Page
Contents
Preface
About the Authors
Acknowledgments
Chapter 1 Background and Functional Requirements for High-Density Communications
1.1 BACKGROUND
1.2 REQUIREMENTS FOR HIGH-DENSITY COMMUNICATIONS
1.2.1 Pre-pandemic/Long-term Requirements for Airports
1.2.2 Pre-pandemic/Long-term Requirements for Stadiums
1.2.3 Pre-pandemic/Long-term Requirements for Convention Centers
1.2.4 Pre-pandemic/Long-term Requirements for Open Air Gatherings and Amusement Parks
1.2.5 Pre-pandemic/Long-term Requirements for Classrooms
1.2.6 Pre-pandemic/Long-term Requirements for Train and Subway Stations
1.2.7 Pre-pandemic/Long-term Requirements for Dense Office Environments
1.2.8 Ongoing Requirements for Dense Smart Warehouses and Distribution Centers
1.2.9 Pre-pandemic/Long-term Requirements for Dense Smart Cities
1.3 PANDEMIC-DRIVEN SOCIAL DISTANCING
1.3.1 Best Practices
1.3.2 Heuristic Density for the Pandemic Era
1.4 THE CONCEPT OF A WIRELESS SUPERNETWORK
REFERENCES
Chapter 2 Traditional WLAN Technologies
2.1 OVERVIEW
2.2 WLAN STANDARDS
2.3 WLAN BASIC CONCEPTS
2.3.1 PHY Layer Operation
2.3.2 MAC Layer Operation
2.4 HARDWARE ELEMENTS
2.5 KEY IEEE 802.11ac MECHANISMS
2.5.1 Downlink Multi-User MIMO (DL-MU-MIMO)
2.5.2 Beamforming
2.5.3 Dynamic Frequency Selection
2.5.4 Space-Time Block Coding
2.5.5 Product Waves
2.6 BRIEF PREVIEW OF IEEE 802.11ax
Chapter 3 Traditional DAS Technologies
3.1 OVERVIEW
3.2 FREQUENCY BANDS OF CELLULAR OPERATION
3.2.1 Traditional RF Spectrum
3.2.2 Citizens Broadband Radio Service (CBRS)
3.2.3 Freed-up Satellite C-Band
3.2.4 5G Bands
3.2.5 Motivations for Additional Spectrum
3.2.6 Private LTE/Private CBRS
3.2.7 5G Network Slicing
3.2.8 Supportive Technologies.
3.3 DISTRIBUTED ANTENNA SYSTEMS (DASs)
3.3.1 Technology Scope
3.3.2 More Detailed Exemplary Arrangement
3.3.3 Traffic-aware DAS
3.3.4 BBU and DAS/RRU Connectivity
3.3.5 Ethernet/IP Transport Connectivity of DAS
Chapter 4 Traditional Sensor Networks/IoT Services
4.1 OVERVIEW And ENVIRONMENT
4.2 ARCHITECTURAL CONCEPTS
4.3 WIRELESS TECHNOLOGIES FOR THE IoT
4.3.1 Pre-5G Wireless Technologies for the IoT
4.3.2 NB-IoT
4.3.3 LTE-M
4.3.4 5G Technologies for the IoT
4.3.5 WAN-Oriented IoT Connectivity Migration Strategies
4.4 EXAMPLES OF SEVEN-LAYER IoT PROTOCOL STACKS
4.4.1 UPnP
4.4.2 ZigBee
4.4.3 Bluetooth
4.5 GATEWAY-BASED IoT OPERATION
4.6 EDGE COMPUTING IN THE IoT ECOSYSTEM
4.7 SESSION ESTABLISHMENT EXAMPLE
4.8 IoT SECURITY
4.8.1 Challenges
4.8.2 Applicable Security Mechanisms
4.8.3 Hardware Considerations
4.8.4 Other Approaches: Blockchains
Chapter 5 Evolved Campus Connectivity
5.1 ADVANCED SOLUTIONS
5.1.1 802.11ax Basics
5.1.2 Key 802.11ax Processes
5.1.3 Summary
5.2 VOICE OVER WI-FI (VOWI-FI)
5.3 5G TECHNOLOGIES
5.3.1 Emerging Services
5.3.2 New Access and Core Elements
5.3.3 New 5GC Architecture
5.3.4 Frequency Spectrum and Propagation Challenges
5.3.5 Resource Management
5.3.6 Requirements for Small Cells
5.3.7 Comparison to Wi-Fi 6
5.4 IOT
5.5 5G DAS SOLUTIONS
5.6 INTEGRATED SOLUTIONS
Chapter 6 De-densification of Spaces and Work Environments
6.1 OVERVIEW
6.2 BASIC APPROACHES
6.3 RTLS METHODOLOGIES AND TECHNOLOGIES
6.3.1 RFID Systems
6.3.2 Wi-Fi-based Positioning System (WPS)
6.3.3 Bluetooth
6.3.4 UWB
6.3.5 Automatic Vehicle Location (AVL)
6.4 STANDARDS
6.5 APPLICATIONS
REFERENCES.
Chapter 7 UWB-Based De-densification of Spaces and Work Environments
7.1 REVIEW OF UWB TECHNOLOGY
7.2 CARRIAGE OF INFORMATION IN UWB
7.2.1 Pulse Communication
7.2.2 UWB Modulation
7.3 UWB STANDARDS
7.4 IOT APPLICATIONS FOR UWB
7.5 UWB APPLICATIONS FOR SMART CITIES AND FOR REAL-TIME LOCATING SYSTEMS
7.5.1 Applications for Smart Cities
7.5.2 UWB Applications to Real-Time Location Systems
7.6 OSD/ODCMA APPLICATIONS
Chapter 8 RTLSs and Distance Tracking Using Wi-Fi, Bluetooth, and Cellular Technologies
8.1 OVERVIEW
8.2 RF FINGERPRINTING METHODS
8.3 WI-FI RTLS APPROACHES
8.3.1 Common Approach
8.3.2 Design Considerations
8.3.3 Drawbacks and Limitations
8.3.4 Potential Enhancements
8.3.5 Illustrative Examples
8.4 BLE
8.4.1 Bluetooth and BLE Background
8.4.2 RTLS Applications
8.4.3 BLE-Based Contact Tracing
8.4.4 Illustrative Examples
8.5 CELLULAR APPROACHES
8.6 SUMMARY
Chapter 9 Case Study of an Implementation and Rollout of a High-Density High-Impact Network
9.1 THURGOOD MARSHALL BWI AIRPORT DESIGN REQUIREMENTS
9.1.1 Broad Motivation
9.1.2 Status Quo Challenges
9.1.3 RFP Requirements
9.2 OVERVIEW OF THE FINAL DESIGN
9.2.1 DAS Solutions
9.2.2 Broadband, BLE, IoT
Chapter 10 The Age of Wi-Fi and Rise of the Wireless SuperNetwork (WiSNET)
10.1 WHAT PRECEDED THE WiSNET
10.2 WHAT COMES NEXT
10.3 THE SUPER-INTEGRATION CONCEPT OF A WIRELESS SUPERNETWORK (WiSNET)
10.4 THE MULTIDIMENSIONALITY OF A SUPERNETWORK (WiSNET)
10.5 THE GENESIS OF THE WiSNET CONCEPT DEFINED IN THIS TEXT
10.6 THE DEFINITION AND CHARACTERIZATION OF A WiSNET
10.6.1 Architectural Aspects of a WiSNET
10.6.2 Technology Aspects of a WiSNET
10.6.3 Management Aspects of a WiSNET
10.7 ECONOMIC ADVANTAGES OF A WiSNET SYSTEM.
10.8 5G SLICE CAPABILITIES
10.8.1 Motivations and Approaches for 5G Network Slicing
10.8.2 Implementation
10.8.3 Wi-Fi Slicing
10.9 CONCLUSION
Index
EULA.
Notes:
Description based on print version record.
Other Format:
Print version: Minoli, Daniel High-Density and de-Densified Smart Campus Communications
ISBN:
9781119716082
111971608X
9781119716075
1119716071
9781119716068
1119716063
OCLC:
1286070179

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