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4g, lte-advanced pro and the road to 5g / Erik Dahlman, Stefan Parkvall, Johan Skold.

EBSCOhost Academic eBook Collection (North America) Available online

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Format:
Book
Author/Creator:
Dahlman, Erik, author.
Parkvall, Stefan, author.
Johan Skold, author.
Language:
English
Subjects (All):
Long-Term Evolution (Telecommunications).
Physical Description:
1 online resource
Edition:
Third edition.
Place of Publication:
Amsterdam, Netherlands : Elsevier : Academic Press, 2016.
Summary:
The upcoming 5G specifications from 3GPP, to be available in 2018, will include LTE-Advanced Pro as well as a new 5G radio-access technology.This practical and very successful book, written by engineers working closely with 3GPP, gives insight into the newest technologies and standards adopted by 3GPP, with detailed explanations of the specific.
Contents:
Front Cover
4G, LTE-Advanced Pro and The Road to 5G
Copyright
Contents
Preface
Acknowledgments
Abbreviations and Acronyms
1 - INTRODUCTION
1.1 1G AND 2G-VOICE-CENTRIC TECHNOLOGIES
1.2 3G AND 4G-MOBILE BROADBAND
1.3 5G-BEYOND MOBILE BROADBAND-NETWORKED SOCIETY
1.4 OUTLINE
2 - SPECTRUM REGULATION AND STANDARDIZATION FROM 3G TO 5G
2.1 OVERVIEW OF STANDARDIZATION AND REGULATION
2.2 ITU-R ACTIVITIES FROM 3G TO 5G
2.2.1 THE ROLE OF ITU-R
2.2.2 IMT-2000 AND IMT-ADVANCED
2.2.3 IMT-2020
2.3 SPECTRUM FOR MOBILE SYSTEMS
2.3.1 SPECTRUM DEFINED FOR IMT SYSTEMS BY THE ITU-R
2.3.2 FREQUENCY BANDS FOR LTE
2.3.3 NEW FREQUENCY BANDS
2.4 SPECTRUM FOR 5G
2.4.1 NEW FREQUENCY BANDS TO BE STUDIED BY WRC
2.4.2 RF EXPOSURE ABOVE 6GHZ
2.5 3GPP STANDARDIZATION
2.5.1 THE 3GPP PROCESS
2.5.2 SPECIFYING 5G IN 3GPP
3 - LTE RADIO ACCESS: AN OVERVIEW
3.1 LTE BASIC TECHNOLOGIES
3.1.1 TRANSMISSION SCHEME
3.1.2 CHANNEL-DEPENDENT SCHEDULING AND RATE ADAPTATION
3.1.3 INTER-CELL INTERFERENCE COORDINATION
3.1.4 MULTI-ANTENNA TRANSMISSION
3.1.5 SPECTRUM FLEXIBILITY
3.1.5.1 Flexibility in duplex arrangements
3.1.5.2 Bandwidth flexibility
3.1.6 MULTICAST AND BROADCAST SUPPORT
3.1.7 POSITIONING
3.2 LTE EVOLUTION
3.3 SPECTRUM FLEXIBILITY
3.3.1 CARRIER AGGREGATION
3.3.2 LICENSE-ASSISTED ACCESS
3.4 MULTI-ANTENNA ENHANCEMENTS
3.4.1 EXTENDED MULTI-ANTENNA TRANSMISSION
3.4.2 MULTI-POINT COORDINATION AND TRANSMISSION
3.4.3 ENHANCED CONTROL-CHANNEL STRUCTURE
3.5 DENSIFICATION, SMALL CELLS, AND HETEROGENEOUS DEPLOYMENTS
3.5.1 RELAYING
3.5.2 HETEROGENEOUS DEPLOYMENTS
3.5.3 SMALL-CELL ON-OFF
3.5.4 DUAL CONNECTIVITY
3.5.5 DYNAMIC TDD
3.5.6 WLAN INTERWORKING
3.6 DEVICE ENHANCEMENTS
3.7 NEW SCENARIOS.
3.7.1 DEVICE-TO-DEVICE COMMUNICATION
3.7.2 MACHINE-TYPE COMMUNICATION
3.8 DEVICE CAPABILITIES
4 - RADIO-INTERFACE ARCHITECTURE
4.1 OVERALL SYSTEM ARCHITECTURE
4.1.1 CORE NETWORK
4.1.2 RADIO-ACCESS NETWORK
4.2 RADIO PROTOCOL ARCHITECTURE
4.2.1 PACKET-DATA CONVERGENCE PROTOCOL
4.2.2 RADIO-LINK CONTROL
4.2.3 MEDIUM-ACCESS CONTROL
4.2.3.1 Logical Channels and Transport Channels
4.2.3.2 Scheduling
4.2.3.3 Hybrid ARQ with Soft Combining
4.2.4 PHYSICAL LAYER
4.3 CONTROL-PLANE PROTOCOLS
4.3.1 STATE MACHINE
5 - PHYSICAL TRANSMISSION RESOURCES
5.1 OVERALL TIME-FREQUENCY STRUCTURE
5.2 NORMAL SUBFRAMES AND MBSFN SUBFRAMES
5.3 ANTENNA PORTS
5.3.1 QUASI-CO-LOCATED ANTENNA PORTS
5.4 DUPLEX SCHEMES
5.4.1 FREQUENCY-DIVISION DUPLEX
5.4.2 TIME-DIVISION DUPLEX
5.4.3 LTE AND TD-SCDMA COEXISTENCE
5.4.4 LICENSE-ASSISTED ACCESS
5.5 CARRIER AGGREGATION
5.6 FREQUENCY-DOMAIN LOCATION OF LTE CARRIERS
6 - DOWNLINK PHYSICAL-LAYER PROCESSING
6.1 TRANSPORT-CHANNEL PROCESSING
6.1.1 PROCESSING STEPS
6.1.1.1 CRC Insertion per Transport Block
6.1.1.2 Code-Block Segmentation and per-Code-Block CRC Insertion
6.1.1.3 Channel Coding
6.1.1.4 Rate Matching and Physical-Layer Hybrid-ARQ Functionality
6.1.1.5 Bit-Level Scrambling
6.1.1.6 Data Modulation
6.1.1.7 Antenna Mapping
6.1.1.8 Resource-Block Mapping
6.1.2 LOCALIZED AND DISTRIBUTED RESOURCE MAPPING
6.2 DOWNLINK REFERENCE SIGNALS
6.2.1 CELL-SPECIFIC REFERENCE SIGNALS
6.2.1.1 Structure of a Single Reference Signal
6.2.1.2 Multiple Reference Signals
6.2.2 DEMODULATION REFERENCE SIGNALS
6.2.2.1 DM-RS for PDSCH
6.2.2.2 DM-RS for EPDCCH
6.2.3 CSI REFERENCE SIGNALS
6.2.3.1 CSI-RS Structure
6.2.3.2 CSI-RS and PDSCH Mapping
6.2.3.3 Zero-Power CSI-RS
6.2.4 QUASI-COLOCATION RELATIONS.
6.3 MULTI-ANTENNA TRANSMISSION
6.3.1 TRANSMISSION MODES
6.3.2 TRANSMIT DIVERSITY
6.3.2.1 Transmit Diversity for Two Antenna Ports
6.3.2.2 Transmit Diversity for Four Antenna Ports
6.3.3 CODEBOOK-BASED PRECODING
6.3.3.1 Closed-Loop Precoding
6.3.3.2 Open-Loop Precoding
6.3.4 NON-CODEBOOK-BASED PRECODING
6.3.5 DOWNLINK MU-MIMO
6.3.5.1 MU-MIMO within Transmission Modes 8/9
6.3.5.2 MU-MIMO Based on CRS
6.4 DOWNLINK L1/L2 CONTROL SIGNALING
6.4.1 PHYSICAL CONTROL FORMAT INDICATOR CHANNEL
6.4.2 PHYSICAL HYBRID-ARQ INDICATOR CHANNEL
6.4.3 PHYSICAL DOWNLINK CONTROL CHANNEL
6.4.4 ENHANCED PHYSICAL DOWNLINK CONTROL CHANNEL
6.4.5 BLIND DECODING OF PDCCHS AND EPDCCHS
6.4.6 DOWNLINK SCHEDULING ASSIGNMENTS
6.4.6.1 Signaling of Downlink Resource-Block Allocations
6.4.6.2 Signaling of Transport-Block Sizes
6.4.7 UPLINK SCHEDULING GRANTS
6.4.7.1 Signaling of Uplink Resource-Block Allocations
6.4.8 POWER-CONTROL COMMANDS
7 - UPLINK PHYSICAL-LAYER PROCESSING
7.1 TRANSPORT-CHANNEL PROCESSING
7.1.1 PROCESSING STEPS
7.1.2 MAPPING TO THE PHYSICAL RESOURCE
7.1.3 PUSCH FREQUENCY HOPPING
7.1.3.1 Hopping Based on Cell-Specific Hopping/Mirroring Patterns
7.1.3.2 Hopping Based on Explicit Hopping Information
7.2 UPLINK REFERENCE SIGNALS
7.2.1 DEMODULATION REFERENCE SIGNALS
7.2.1.1 Time-Frequency Structure
7.2.1.2 Base Sequences
7.2.1.3 Phase-Rotation and Orthogonal Cover Codes
7.2.1.4 Base-Sequence Assignment
7.2.1.5 Assignment of Phase Rotation and OCC
7.2.2 SOUNDING REFERENCE SIGNALS
7.2.2.1 Periodic SRS Transmission
7.2.2.2 Aperiodic SRS Transmission
7.3 UPLINK MULTI-ANTENNA TRANSMISSION
7.3.1 PRECODER-BASED MULTI-ANTENNA TRANSMISSION FOR PUSCH
7.3.2 UPLINK MULTI-USER MIMO
7.3.3 PUCCH TRANSMIT DIVERSITY
7.4 UPLINK L1/L2 CONTROL SIGNALING.
7.4.1 BASIC PUCCH STRUCTURE
7.4.1.1 PUCCH Format 1
7.4.1.2 PUCCH Format 2
7.4.1.3 PUCCH Format 3
7.4.1.4 PUCCH Format 4
7.4.1.5 PUCCH Format 5
7.4.1.6 Resource-Block Mapping for PUCCH
7.4.2 UPLINK CONTROL SIGNALING ON PUCCH
7.4.2.1 Hybrid-ARQ Acknowledgments
7.4.2.2 Scheduling Request
7.4.2.3 Hybrid-ARQ Acknowledgments and Scheduling Request
7.4.2.4 Channel-State Information
7.4.2.5 Hybrid-ARQ Acknowledgments and CSI
7.4.2.6 Scheduling Request and CSI
7.4.2.7 Hybrid-ARQ Acknowledgments, CSI and Scheduling Request
7.4.3 UPLINK L1/L2 CONTROL SIGNALING ON PUSCH
7.5 UPLINK POWER CONTROL
7.5.1 UPLINK POWER CONTROL: SOME BASIC RULES
7.5.2 POWER CONTROL FOR PUCCH
7.5.3 POWER CONTROL FOR PUSCH
7.5.4 POWER CONTROL FOR SRS
7.6 UPLINK TIMING ALIGNMENT
8 - RETRANSMISSION PROTOCOLS
8.1 HYBRID ARQ WITH SOFT COMBINING
8.1.1 DOWNLINK HYBRID ARQ
8.1.2 UPLINK HYBRID ARQ
8.1.3 HYBRID-ARQ TIMING
8.1.3.1 Hybrid-ARQ Timing for FDD
8.1.3.2 Hybrid-ARQ Timing for TDD
8.2 RADIO-LINK CONTROL
8.2.1 SEGMENTATION, CONCATENATION, AND REASSEMBLY OF RLC SDUS
8.2.2 RLC RETRANSMISSION
8.2.3 IN-SEQUENCE DELIVERY
8.2.4 RLC OPERATION
9 - SCHEDULING AND RATE ADAPTATION
9.1 SCHEDULING STRATEGIES
9.2 DOWNLINK SCHEDULING
9.3 UPLINK SCHEDULING
9.3.1 UPLINK PRIORITY HANDLING
9.3.2 SCHEDULING REQUESTS
9.3.3 BUFFER STATUS REPORTS
9.3.4 POWER HEADROOM REPORTS
9.4 TIMING OF SCHEDULING ASSIGNMENTS/GRANTS
9.4.1 DOWNLINK SCHEDULING TIMING
9.4.2 UPLINK SCHEDULING TIMING
9.5 SEMI-PERSISTENT SCHEDULING
9.6 SCHEDULING FOR HALF-DUPLEX FDD
9.7 DISCONTINUOUS RECEPTION
10 - CHANNEL-STATE INFORMATION AND FULL-DIMENSION MIMO
10.1 CSI REPORTS
10.2 PERIODIC AND APERIODIC CSI REPORTS
10.2.1 APERIODIC CSI REPORTS
10.2.2 PERIODIC CSI REPORTS.
10.3 INTERFERENCE ESTIMATION
10.4 CHANNEL-QUALITY INDICATOR
10.5 RANK INDICATOR AND PRECODER MATRIX INDICATOR
10.6 FULL-DIMENSION MIMO
10.6.1 CSI FEEDBACK FOR MASSIVE ANTENNA ARRANGEMENTS
10.6.2 CSI REPORTING CLASS A
10.6.3 CSI REPORTING CLASS B
11 - ACCESS PROCEDURES
11.1 ACQUISITION AND CELL SEARCH
11.1.1 OVERVIEW OF LTE CELL SEARCH
11.1.2 PSS STRUCTURE
11.1.3 SSS STRUCTURE
11.2 SYSTEM INFORMATION
11.2.1 MIB AND BCH TRANSMISSION
11.2.2 SYSTEM-INFORMATION BLOCKS
11.3 RANDOM ACCESS
11.3.1 STEP 1: RANDOM-ACCESS PREAMBLE TRANSMISSION
11.3.1.1 PRACH Time-Frequency Resources
11.3.1.2 Preamble Structure and Sequence Selection
11.3.1.3 PRACH Power Setting
11.3.1.4 Preamble Sequence Generation
11.3.1.5 Preamble Detection
11.3.2 STEP 2: RANDOM-ACCESS RESPONSE
11.3.3 STEP 3: DEVICE IDENTIFICATION
11.3.4 STEP 4: CONTENTION RESOLUTION
11.4 PAGING
12 - CARRIER AGGREGATION
12.1 OVERALL PROTOCOL STRUCTURE
12.2 PRIMARY AND SECONDARY COMPONENT CARRIERS
12.3 SELF-SCHEDULING AND CROSS-CARRIER SCHEDULING
12.3.1 SCHEDULING TIMING FOR AGGREGATION OF FDD CARRIERS
12.3.2 SCHEDULING TIMING FOR AGGREGATION OF TDD CARRIERS
12.3.3 SCHEDULING TIMING FOR AGGREGATION OF FDD AND TDD CARRIERS
12.4 DRX AND COMPONENT-CARRIER DEACTIVATION
12.5 DOWNLINK CONTROL SIGNALING
12.5.1 PCFICH
12.5.2 PHICH
12.5.3 PDCCH AND EPDCCH
12.6 UPLINK CONTROL SIGNALING
12.6.1 HYBRID-ARQ ACKNOWLEDGMENTS ON PUCCH
12.6.2 CSI REPORTING ON PUCCH
12.6.3 CONTROL SIGNALING ON PUSCH
12.7 TIMING ADVANCE AND CARRIER AGGREGATION
13 - MULTI-POINT COORDINATION AND TRANSMISSION
13.1 INTER-CELL INTERFERENCE COORDINATION
13.2 MULTI-POINT COORDINATION/TRANSMISSION
13.2.1 MULTI-POINT COORDINATION
13.2.1.1 Coordinated Link Adaptation
13.2.1.2 Coordinated Scheduling.
13.2.2 MULTI-POINT TRANSMISSION.
Notes:
Includes bibliographical references and index.
Description based on print version record.
Description based on publisher supplied metadata and other sources.
ISBN:
9780128046111
0128046112
9780128045756
0128045752
OCLC:
956646290

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