Random wireless networks : an information theoretic perspective /
Saved in:
Author / Creator: | Vaze, Rahul, author. |
---|---|
Imprint: | Delhi, India : Cambridge University Press, 2015. |
Description: | 1 online resource : illustrations |
Language: | English |
Subject: | |
Format: | E-Resource Book |
URL for this record: | http://pi.lib.uchicago.edu/1001/cat/bib/12645539 |
Table of Contents:
- Cover; Title; Copyright; Dedication; Contents; List of Figures; Preface; Acknowledgments; Notation; Chapter 1 Introduction; 1.1 Introduction; 1.2 Point-to-Point Wireless Signal Propagation Model; 1.3 Shannon Capacity; 1.4 Outage Capacity; 1.5 Wireless Network Signal Model; 1.5.1 Information Theoretic Limits of Wireless Networks; 1.6 Connectivity in Wireless Networks; Bibliography; Chapter 2 Transmission Capacity of ad hoc Networks; 2.1 Introduction; 2.2 Transmission Capacity Formulation; 2.3 Basics of Stochastic Geometry; 2.4 Rayleigh Fading Model; 2.4.1 Derivation of Transmission Capacity
- 2.5 Path-Loss Model2.5.1 Upper Bound on the Transmission Capacity; 2.5.2 Lower Bound on the Transmission Capacity; 2.6 Optimal ALOHA Transmission Probability; 2.7 Correlations with ALOHA Protocol; 2.8 Transmission Capacity with Scheduling in Wireless Networks; 2.8.1 Guard Zone Strategy; 2.8.2 CSMA; 2.9 Reference Notes; Bibliography; Chapter 3 Multiple Antennas; 3.1 Introduction; 3.2 Role of Multiple Antennas in ad hoc Networks; 3.3 Channel State Information Only at Receiver; 3.3.1 Transmission CapacityWith Partial ZF Decoder; 3.3.2 No Interference Cancelation
- 3.4 Channel State Information at Both Transmitter and Receiver3.5 Spectrum-Sharing/Cognitive Radios; 3.6 Reference Notes; Bibliography; Chapter 4 Two-Way Networks; 4.1 Introduction; 4.2 Two-Way Communication; 4.2.1 Computing the Two-Way Transmission Capacity; 4.2.2 Lower Bound on the Success Probability; 4.2.3 Upper Bound on the Success Probability; 4.2.4 Two-Way Bandwidth Allocation; 4.3 Effect of Limited Feedback on Two-Way Transmission Capacity with Beamforming; 4.4 Reference Notes; Bibliography; Chapter 5 Performance Analysis of Cellular Networks; 5.1 Introduction
- 5.2 Random Cellular Network5.2.1 Connection Probability; 5.2.2 Average Rate per User; 5.3 Distance-Dependent Shadowing Model; 5.3.1 Cellular Network Model with Randomly Located Blockages; 5.3.2 Distribution of the Number of Blockages on link Ln; 5.3.3 Connection Probability; 5.3.4 Average Rate per User; 5.4 Reference Notes; Bibliography; Chapter 6 Delay Normalized Transmission Capacity; 6.1 Introduction; 6.2 Delay Normalized Transmission Capacity; 6.2.1 Single Hop Transmission with ARQ Protocol; 6.3 Fixed Distance Dedicated Relays Multi-Hop Model with ARQ
- 6.3.1 Deriving Delay Normalized Transmission Capacity6.3.2 Lower Bound on the Delay Normalized Transmission Capacity; 6.4 Shared Relays Multi-Hop Communication Model; 6.4.1 Spatial Progress Capacity; 6.5 Reference Notes; Bibliography; Chapter 7 Percolation Theory; 7.1 Introduction; 7.2 Discrete Percolation; 7.2.1 Square Lattice Percolation; 7.2.2 Percolation on the Hexagonal Grid; 7.3 Continuum Percolation; 7.3.1 Gilbert's Disc Model; 7.3.2 Connectivity in Gilbert's Disc Model; 7.3.3 Gilbert's Random Disc Model; 7.3.4 Incorporating Fading using Gilbert's Random Disc Model; 7.4 Reference Notes