Wireless Communications Resource Management
Wiley - IEEE
1. Auflage Januar 2009
368 Seiten, Hardcover
Wiley & Sons Ltd
Traditional wireless communication books have focused on point-to-point communication, dealing with wireless channel capacity, link performance, delay performance. However, recent advances in wireless resource management techniques have not yet been deeply treated even though they are very hot research topics in academic areas and become very crucial in implementing commercial wireless communication systems such as CDMA 1x-EVDO, WiMax, and 3GPP LTE, etc. Lee, Park and Seo provide a comprehensive discussion on the state-of-the-art technologies of resource management in wireless communications. The subject is arranged in two parts: The first part provides basic concepts and background knowledge (including mathematical tools) required for understanding resource management. The second part provides detailed discussions on resource management techniques which play key roles in current and future wireless communication systems. In particular, resource management techniques are categorized into four classes - namely, bandwidth, power, antenna, and inter-cell resource managements - according to their objectives and focal points, and discussed in systematic structure.
* Presents the latest resource allocation techniques for new and next generation air interface technologies
* Arms readers with the necessary fundamentals and mathematical tools
* Illustrates the theoretical background in a concrete manner
* Gives detailed coverage on scheduling, power management, and MIMO techniques
* Comes with presentation files of book figures for instructor use
Part I. Concepts And Background
Chapter 1. Introduction
1.1 Evolution Of Wireless Communications
1.2 Wireless Resource Management
1.3 Organization Of The Book
Chapter 2. Characteristics Of Wireless Channels
2.1 Channel Gain
2.2 Large-Scale Fading
2.2.1. Path Loss
2.2.2. Shadowing
2.3 Small-Scale Fading
2.3.1. Fading In Time Domain
2.3.2. Fading In Frequency Domain
2.4 Technologies Against Channel Fading
2.4.1. Diversity
2.4.2. Hybrid Arq
2.4.3. Adaptive Modulation And Coding
Chapter 3. Basic Concepts For Resource Management
3.1 Definition Of Resource Management
3.1.1 Wireless Resources
3.1.2 Problem Formulation
3.2 Multiple Access Methods
3.2.1 Frequency Division Multiple Access
3.2.2 Time Division Multiple Access
3.2.3 Code Division Multiple Access
3.2.4 Orthogonal Frequency Division Multiple Access
3.3 Quality Of Services
3.3.1 Qos Classification
3.3.2 Prioritization And Fairness
3.4 Resource Management In Protocol Layers
3.4.1 Classical Protocol Layering
3.4.2 Cross-Layer Design In Wireless Resource Management
Chapter 4 Mathematical Tools For Resource Management
4.1 Convex Optimization
4.1.1 Basic Concepts
4.1.2 Constrained Optimization
4.1.3 Lagrange Dual Function
4.1.4 Karush-Kuhn-Tucker Optimality Condition
4.1.5 Application Of Convex Optimization
4.2 Dynamic Programming
4.2.1 Sequential Optimization
4.2.2 Markov Decision Process
4.3 Analogy Of Economics And Wireless Resource Management
4.3.1 Economics Model
4.3.2 Wireless Resource Allocation - Examples
Part II. Wireless Resource Management Technologies
Chapter 5. Bandwidth Management
5.1 Differences Between Wired And Wireless Communications
5.1.1 Statistical Multiplexing In Wired Networks
5.1.2 Multi-User Diversity In Wireless Networks
5.2 Schedulers Based On Generalized Processor Sharing
5.2.1 Generalized Processor Sharing
5.2.2 Modifications Of Gps For Wireless Channels
5.3 Schedulers For Throughput Maximization
5.3.1 Maximal Rate Scheduling
5.3.2 Proportional Fairness Scheduling
5.3.3 Temporal Fairness Scheduling
5.3.4 Utilitarian Fairness Scheduling
5.3.5 Cumulative Distribution Function Based Scheduling
5.3.6 Comparison Among Scheduling Algorithms
5.4 Delay Performance Of Wireless Schedulers
5.4.1 Throughput Optimality
5.4.2 Modified Largest Weight Delay First Scheduling
5.4.3 Exponential Rule Scheduling
5.5 Qos In Wireless Scheduling And Admission Control
5.5.1 Effective Bandwidth And Effective Capacity
5.5.2 Qos Provision
Chapter 6. Transmission Power Management
6.1 Transmission Power Management For Interference Regulation
6.1.1 Power Control With Strict Sinr Requirement
6.2.2 Utility-Based Power Control
6.2.3 Power Control Along With Rate Control
6.2.4 Power Control For Hybrid Arq
6.2 Transmission Power Management For Multiple Parallel Channels
6.2.1 Single-User Case
6.2.2 Multiple-User Case I: Throughput Maximization
6.2.3 Multiple-User Case Ii: Utility Maximization
6.2.4 Multiple-User Case Iii: With Time Diversity
6.3 Transmission Power Adaptation To Time-Varying Environments
6.3.1 Capacity Of Time-Varying Channels
6.3.2 Transmission Time And Energy Efficiency
6.3.3 Power Adaptation Based On Buffer And Channel States
Chapter 7. Antenna Management
7.1 Capacity Of Mimo Channels
7.1.1 Capacity Of Deterministic Channel
7.1.2 Ergodic Capacity
7.1.3 Outage Capacity
7.2 Mimo Transmission
7.2.1 Diversity Transmission
7.2.2 Spatial Multiplexing
7.2.3 Diversity-Multiplexing Tradeoff
7.3 Multiuser Mimo
7.3.1 Uplink Channel
7.3.2 Dirty Paper Coding
7.3.3 Downlink Channel
7.3.4 Downlink-Uplink Duality
7.3.5 Downlink Precoding Schemes
Chapter 8. Inter-Cell Resource Management
8.1 Inter-Cell Interference Management
8.1.1 Fixed Channel Allocation (Fca)
8.1.2 Dynamic Channel Allocation (Dca)
8.1.3 Channel Allocation Based On Sinr Measurement
8.1.4 Channel Allocation With Inter-Cell Power Control
8.2 Handoff Management
8.3.1 Handoff Procedure And Performance
8.3.2 Resource Reservation Via Guard Channel Policy
8.3.3 Handoff Request Queuing And Soft Handoff
8.3.4 Advanced Handoff Management Schemes
Abbreviations
About The Authors
