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This book describes the next evolution of mobile wireless communications, Fifth Generation, explained both from network and device perspective. Chapters and sections are dedicated to illustrate the key stages involved in the development of new generation.
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This book describes the next evolution of mobile wireless communications, Fifth Generation, explained both from network and device perspective. Chapters and sections are dedicated to illustrate the key stages involved in the development of new generation.
Dieser Download kann aus rechtlichen Gründen nur mit Rechnungsadresse in A, B, BG, CY, CZ, D, DK, EW, E, FIN, F, GR, HR, H, IRL, I, LT, L, LR, M, NL, PL, P, R, S, SLO, SK ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis
- Seitenzahl: 354
- Erscheinungstermin: 20. Juli 2018
- Englisch
- ISBN-13: 9780429881343
- Artikelnr.: 56840555
- Verlag: Taylor & Francis
- Seitenzahl: 354
- Erscheinungstermin: 20. Juli 2018
- Englisch
- ISBN-13: 9780429881343
- Artikelnr.: 56840555
Saad Z. Asif has been associated with the field of telecommunication for more than 20 years. He gained experience through working with three of the top-tier telecommunication operators-Sprint (US), Jazz (Veon), and Telenor Pakistan, and also through the Ministry of Information Technology and Telecommunication, Pakistan, which is a public policy-making institute.
Asif is a strategic thinker, researcher, and telecommunications policy expert. He has been at the forefront of technology research and standardization and in providing strategic guidance throughout his career. He has led one of the first teams across the globe to evaluate state-of-the-art technologies such as 3G, 4G, Smart Antennas, e-band microwave radios, dense wavelength division multiplexing (DWDM), and many more. He played a key role in designing Sprint's wireless high-speed data strategy, Jazz's Broadband strategy, and Telenor's Pakistan's 3G and Transmission Network strategies.
He is one of the main authors of GSMA's (Global System for Mobile Association) award winning Pakistan's National Telecommunications Policy 2015. He was also one of the key players in the successful execution of two frequency spectrum auctions that generated more than US$700 million for the national exchequer. He was also instrumental in defending the country's scarce resource (frequency spectrum) at the World Radiocommunication Conference 2015. He has produced a Policy Directive on 5G and developed Pakistan's first 3-year rolling Frequency Spectrum strategy and Cyber Governance policy.
Asif has written two books and numerous peer-reviewed technical papers on telecommunications. He has been granted five patents as a co-patentee by the United States Patent & Trade Office. He has also been listed as a scientist in the Productive Scientists of Pakistan directory since 2009. He has also been a senior member of the IEEE (Institute of Electrical and Electronics Engineers) since 2004. He also served on the board of directors of Pakistan's National Radio & Telecommunication Corporation.
Asif earned a BS and an MS in electrical engineering from Oklahoma State University in 1996 and 1997, respectively. He also earned an MS in engineering management from the University of Kansas in 2001.
Asif is a strategic thinker, researcher, and telecommunications policy expert. He has been at the forefront of technology research and standardization and in providing strategic guidance throughout his career. He has led one of the first teams across the globe to evaluate state-of-the-art technologies such as 3G, 4G, Smart Antennas, e-band microwave radios, dense wavelength division multiplexing (DWDM), and many more. He played a key role in designing Sprint's wireless high-speed data strategy, Jazz's Broadband strategy, and Telenor's Pakistan's 3G and Transmission Network strategies.
He is one of the main authors of GSMA's (Global System for Mobile Association) award winning Pakistan's National Telecommunications Policy 2015. He was also one of the key players in the successful execution of two frequency spectrum auctions that generated more than US$700 million for the national exchequer. He was also instrumental in defending the country's scarce resource (frequency spectrum) at the World Radiocommunication Conference 2015. He has produced a Policy Directive on 5G and developed Pakistan's first 3-year rolling Frequency Spectrum strategy and Cyber Governance policy.
Asif has written two books and numerous peer-reviewed technical papers on telecommunications. He has been granted five patents as a co-patentee by the United States Patent & Trade Office. He has also been listed as a scientist in the Productive Scientists of Pakistan directory since 2009. He has also been a senior member of the IEEE (Institute of Electrical and Electronics Engineers) since 2004. He also served on the board of directors of Pakistan's National Radio & Telecommunication Corporation.
Asif earned a BS and an MS in electrical engineering from Oklahoma State University in 1996 and 1997, respectively. He also earned an MS in engineering management from the University of Kansas in 2001.
Chapter 1 The Beginning. Mobile Cellular Telephony Evolution. Hexagon Based
Mobile Cellular Telephony. Manuscript Overview. Section I. Chapter 2
Research and Technology Development. Basic versus Applied Research. R&D in
ICT. Strengthening the ICT R&D Ecosystem. Chapter 3 Radio Frequency
Spectrum. Radio Spectrum and Mobile Communications. Frequency Allocation
and Identification. Frequency Spectrum Needs of 5G. Section II. Chapter 4
Standardization. Key SDOs and their Standardization Processes. 5G
Standardization. ITU-T Guidelines for Establishing SDOs in Developing
Nations. Case Study-Lack of Research and Standardization in OIC Member
States. Chapter 5 5G Concepts. 5G Objectives and Usage Scenarios. 5G
Activities. Channel Access Method/Air Interface. Cognitive Radio. Massive
Centralized RAN. Vehicular Communications. Network Slicing. 5G Policy. 5G
Timelines. Section III. Chapter 6 Semiconductors in Mobile
Telecommunications. Background. 6.2 RF, Analog/Mixed-Signal (AMS), and MMW
Circuits. Examples (RFAMS). IoT-Next Growth Engine for Semiconductors. 6.5
Perspective-Semiconductor Business in Pakistan. Chapter 7 Product
Development. Multi-Standard, Multi-Mode, Multi-RAT Base Stations. Small
Cells. SSGN-MME Node. 5G Base Stations and Small Cells. Section IV. Chapter
8 Network Architecture, Mobility Management, and Deployment. 2G GSM Network
Architecture. 3G UMTS Network Architecture. LTE and 4G (LTE-Advanced)
Network Architecture. Potential 5G Network Architecture. Mobility
Management. Network Deployment. Chapter 9 4G/5G Radio Access Network. 3GPP
Releases. LTE-Advanced. LTE-Advanced Pro. 5G NR. Chapter 10 Transport
Network. 5G Transport Requirements. Mobile Backhaul. E-Band Microwave
Radios. Metro Transport Network. Core Transport Network. Chapter 11 Core
Network and Operational Support System. Evolved Packet Core. Evolution of
IMS. 5G Core Network. Content Delivery Network. Operations Support System.
Section V. Chapter 12 Connected Devices. Smart Phone Components. Batteries.
Device Processors. Massive MIMO. D2D Communications. Role of SDOs for
Connected Devices. Chapter 13 Mobile Applications. Delivery Platforms.
Advanced Value-Added Services. Mobile Financial Services. mHealth. Massive
Internet of Things. Section VI. Chapter 14 Burning Challenges. Signaling
Storm. Hyperdense HetNets. D2D Communications. Big Data. Chapter 15 Weak,
Good, and Best Industry Practices. Spectrum Management. Energy Management.
Patent Portfolio Management. Final Remarks. Chapter 16 The Way Forward:
Fast Forward to Year 2040. Current Picture. Why 2040? Key Big Trends. Final
Suggestions
Mobile Cellular Telephony. Manuscript Overview. Section I. Chapter 2
Research and Technology Development. Basic versus Applied Research. R&D in
ICT. Strengthening the ICT R&D Ecosystem. Chapter 3 Radio Frequency
Spectrum. Radio Spectrum and Mobile Communications. Frequency Allocation
and Identification. Frequency Spectrum Needs of 5G. Section II. Chapter 4
Standardization. Key SDOs and their Standardization Processes. 5G
Standardization. ITU-T Guidelines for Establishing SDOs in Developing
Nations. Case Study-Lack of Research and Standardization in OIC Member
States. Chapter 5 5G Concepts. 5G Objectives and Usage Scenarios. 5G
Activities. Channel Access Method/Air Interface. Cognitive Radio. Massive
Centralized RAN. Vehicular Communications. Network Slicing. 5G Policy. 5G
Timelines. Section III. Chapter 6 Semiconductors in Mobile
Telecommunications. Background. 6.2 RF, Analog/Mixed-Signal (AMS), and MMW
Circuits. Examples (RFAMS). IoT-Next Growth Engine for Semiconductors. 6.5
Perspective-Semiconductor Business in Pakistan. Chapter 7 Product
Development. Multi-Standard, Multi-Mode, Multi-RAT Base Stations. Small
Cells. SSGN-MME Node. 5G Base Stations and Small Cells. Section IV. Chapter
8 Network Architecture, Mobility Management, and Deployment. 2G GSM Network
Architecture. 3G UMTS Network Architecture. LTE and 4G (LTE-Advanced)
Network Architecture. Potential 5G Network Architecture. Mobility
Management. Network Deployment. Chapter 9 4G/5G Radio Access Network. 3GPP
Releases. LTE-Advanced. LTE-Advanced Pro. 5G NR. Chapter 10 Transport
Network. 5G Transport Requirements. Mobile Backhaul. E-Band Microwave
Radios. Metro Transport Network. Core Transport Network. Chapter 11 Core
Network and Operational Support System. Evolved Packet Core. Evolution of
IMS. 5G Core Network. Content Delivery Network. Operations Support System.
Section V. Chapter 12 Connected Devices. Smart Phone Components. Batteries.
Device Processors. Massive MIMO. D2D Communications. Role of SDOs for
Connected Devices. Chapter 13 Mobile Applications. Delivery Platforms.
Advanced Value-Added Services. Mobile Financial Services. mHealth. Massive
Internet of Things. Section VI. Chapter 14 Burning Challenges. Signaling
Storm. Hyperdense HetNets. D2D Communications. Big Data. Chapter 15 Weak,
Good, and Best Industry Practices. Spectrum Management. Energy Management.
Patent Portfolio Management. Final Remarks. Chapter 16 The Way Forward:
Fast Forward to Year 2040. Current Picture. Why 2040? Key Big Trends. Final
Suggestions
Chapter 1 The Beginning. Mobile Cellular Telephony Evolution. Hexagon Based
Mobile Cellular Telephony. Manuscript Overview. Section I. Chapter 2
Research and Technology Development. Basic versus Applied Research. R&D in
ICT. Strengthening the ICT R&D Ecosystem. Chapter 3 Radio Frequency
Spectrum. Radio Spectrum and Mobile Communications. Frequency Allocation
and Identification. Frequency Spectrum Needs of 5G. Section II. Chapter 4
Standardization. Key SDOs and their Standardization Processes. 5G
Standardization. ITU-T Guidelines for Establishing SDOs in Developing
Nations. Case Study-Lack of Research and Standardization in OIC Member
States. Chapter 5 5G Concepts. 5G Objectives and Usage Scenarios. 5G
Activities. Channel Access Method/Air Interface. Cognitive Radio. Massive
Centralized RAN. Vehicular Communications. Network Slicing. 5G Policy. 5G
Timelines. Section III. Chapter 6 Semiconductors in Mobile
Telecommunications. Background. 6.2 RF, Analog/Mixed-Signal (AMS), and MMW
Circuits. Examples (RFAMS). IoT-Next Growth Engine for Semiconductors. 6.5
Perspective-Semiconductor Business in Pakistan. Chapter 7 Product
Development. Multi-Standard, Multi-Mode, Multi-RAT Base Stations. Small
Cells. SSGN-MME Node. 5G Base Stations and Small Cells. Section IV. Chapter
8 Network Architecture, Mobility Management, and Deployment. 2G GSM Network
Architecture. 3G UMTS Network Architecture. LTE and 4G (LTE-Advanced)
Network Architecture. Potential 5G Network Architecture. Mobility
Management. Network Deployment. Chapter 9 4G/5G Radio Access Network. 3GPP
Releases. LTE-Advanced. LTE-Advanced Pro. 5G NR. Chapter 10 Transport
Network. 5G Transport Requirements. Mobile Backhaul. E-Band Microwave
Radios. Metro Transport Network. Core Transport Network. Chapter 11 Core
Network and Operational Support System. Evolved Packet Core. Evolution of
IMS. 5G Core Network. Content Delivery Network. Operations Support System.
Section V. Chapter 12 Connected Devices. Smart Phone Components. Batteries.
Device Processors. Massive MIMO. D2D Communications. Role of SDOs for
Connected Devices. Chapter 13 Mobile Applications. Delivery Platforms.
Advanced Value-Added Services. Mobile Financial Services. mHealth. Massive
Internet of Things. Section VI. Chapter 14 Burning Challenges. Signaling
Storm. Hyperdense HetNets. D2D Communications. Big Data. Chapter 15 Weak,
Good, and Best Industry Practices. Spectrum Management. Energy Management.
Patent Portfolio Management. Final Remarks. Chapter 16 The Way Forward:
Fast Forward to Year 2040. Current Picture. Why 2040? Key Big Trends. Final
Suggestions
Mobile Cellular Telephony. Manuscript Overview. Section I. Chapter 2
Research and Technology Development. Basic versus Applied Research. R&D in
ICT. Strengthening the ICT R&D Ecosystem. Chapter 3 Radio Frequency
Spectrum. Radio Spectrum and Mobile Communications. Frequency Allocation
and Identification. Frequency Spectrum Needs of 5G. Section II. Chapter 4
Standardization. Key SDOs and their Standardization Processes. 5G
Standardization. ITU-T Guidelines for Establishing SDOs in Developing
Nations. Case Study-Lack of Research and Standardization in OIC Member
States. Chapter 5 5G Concepts. 5G Objectives and Usage Scenarios. 5G
Activities. Channel Access Method/Air Interface. Cognitive Radio. Massive
Centralized RAN. Vehicular Communications. Network Slicing. 5G Policy. 5G
Timelines. Section III. Chapter 6 Semiconductors in Mobile
Telecommunications. Background. 6.2 RF, Analog/Mixed-Signal (AMS), and MMW
Circuits. Examples (RFAMS). IoT-Next Growth Engine for Semiconductors. 6.5
Perspective-Semiconductor Business in Pakistan. Chapter 7 Product
Development. Multi-Standard, Multi-Mode, Multi-RAT Base Stations. Small
Cells. SSGN-MME Node. 5G Base Stations and Small Cells. Section IV. Chapter
8 Network Architecture, Mobility Management, and Deployment. 2G GSM Network
Architecture. 3G UMTS Network Architecture. LTE and 4G (LTE-Advanced)
Network Architecture. Potential 5G Network Architecture. Mobility
Management. Network Deployment. Chapter 9 4G/5G Radio Access Network. 3GPP
Releases. LTE-Advanced. LTE-Advanced Pro. 5G NR. Chapter 10 Transport
Network. 5G Transport Requirements. Mobile Backhaul. E-Band Microwave
Radios. Metro Transport Network. Core Transport Network. Chapter 11 Core
Network and Operational Support System. Evolved Packet Core. Evolution of
IMS. 5G Core Network. Content Delivery Network. Operations Support System.
Section V. Chapter 12 Connected Devices. Smart Phone Components. Batteries.
Device Processors. Massive MIMO. D2D Communications. Role of SDOs for
Connected Devices. Chapter 13 Mobile Applications. Delivery Platforms.
Advanced Value-Added Services. Mobile Financial Services. mHealth. Massive
Internet of Things. Section VI. Chapter 14 Burning Challenges. Signaling
Storm. Hyperdense HetNets. D2D Communications. Big Data. Chapter 15 Weak,
Good, and Best Industry Practices. Spectrum Management. Energy Management.
Patent Portfolio Management. Final Remarks. Chapter 16 The Way Forward:
Fast Forward to Year 2040. Current Picture. Why 2040? Key Big Trends. Final
Suggestions