Cellular Network Planning.
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| Author / Creator: | Alencar, Marcelo Sampaio de. |
|---|---|
| Imprint: | Aalborg : River Publishers, 2016. |
| Description: | 1 online resource (200 pages) |
| Language: | English |
| Series: | River Publishers Series in Communications River Publishers series in communications. |
| Subject: | |
| Format: | E-Resource Book |
| URL for this record: | http://pi.lib.uchicago.edu/1001/cat/bib/11911424 |
Table of Contents:
- Front Cover Page
- Half Title Page
- Cellular Network Planning
- RIVER PUBLISHERS SERIES IN COMMUNICATIONS
- Full Title Page
- Cellular Network Planning
- Copyright Page
- Dedication Page
- Contents
- Preface
- Acknowledgements
- List of Figures
- List of Tables
- List of Abbreviations
- Chapter 1
- Mobile Cellular Telephony
- 1.1 Introduction
- 1.2 First Systems to Enter Commercial Operation
- 1.3 Description of the Cellular System
- 1.3.1 Cellular Structure
- 1.3.2 Cellular Structures
- 1.4 Frequency Reuse
- 1.4.1 Cell Division
- 1.5 Management of Channel Utilization
- 1.5.1 Channel Allocation in the AMPS System
- 1.6 Constitution of the Cellular System
- 1.7 Characteristic Functions of a Cellular Network
- 1.7.1 Handoff
- 1.7.2 Roaming
- 1.7.3 Configuration of the Mobile Cellular System
- 1.7.4 Data Communication from the MSC to the BS
- 1.8 Radio Channel Types
- 1.9 Second Generation Systems
- 1.9.1 The European GSM Standard
- 1.9.2 Second Generation American Standards
- 1.9.2.1 TheTDMA standard
- 1.9.2.2 The CDMA standard
- 1.9.2.3 cdmaOne
- 1.9.2.4 The Japanese standard
- 1.10 Third Generation Systems
- 1.10.1 GPRS
- 1.10.2 UMTS
- 1.10.3 cdma2000
- 1.11 Fourth Generation Systems
- 1.11.1 The Long-term Evolution
- Chapter 2
- Cellular Communications Models
- 2.1 Basic Concepts
- 2.2 Non-Guided Channels
- 2.3 Effects on the Transmitted Signal
- 2.4 The Mobile Communication Channel
- 2.5 Multipath Effects
- 2.5.1 Statistical Modeling of the Mobile Channel
- 2.5.2 The Two-Ray Model of the Mobile Channel
- 2.5.3 Two-Ray Model with Frequency Selectivity
- 2.5.4 Effect of Multiple Rays
- 2.5.5 Time-Varying Channels
- 2.6 Urban Area Propagation Models
- 2.6.1 Propagation in Mobile Systems
- 2.7 Propagation Loss
- 2.7.1 Near Field Propagation Model
- 2.7.2 Equation for the Near Field.
- 2.7.2.1 Propagation plots
- 2.7.3 Far Field Propagation Model
- 2.7.4 Path Propagation Loss
- 2.7.5 Free Space Propagation Loss
- 2.7.6 Propagation Loss Along the Terrestrial Surface
- 2.7.7 Propagation OverWater
- 2.7.7.1 Fixed stations
- 2.7.7.2 Fixed and mobile stations
- 2.7.8 Foliage Loss
- 2.8 Standard Predicting Models
- 2.8.1 Okumura Model
- 2.8.2 Hata Model
- 2.8.3 Lee Model
- 2.8.3.1 Loss prediction plot
- 2.8.3.2 Area prediction model
- 2.8.3.3 General model
- 2.8.4 COST231-Hata Model
- 2.8.5 COST231-Walfish-Ikegami Model
- 2.8.6 Analytic Prediction Model for Urban and Suburban Environments
- 2.8.6.1 Simplified model for near field
- 2.8.6.2 Simplified model: Antenna above the obstacle
- 2.8.6.3 Simplified model: Antenna below the obstacle
- Chapter 3
- Cell Planning
- 3.1 Introduction
- 3.2 Network Planning
- 3.3 Introduction to Cell Planning
- 3.4 Cell-Planning Methodology
- 3.4.1 Planning Procedure
- 3.4.1.1 Expansion needs
- 3.4.1.2 Population density
- 3.4.1.3 Telephone tariff
- 3.4.1.4 Traffic demand
- 3.4.1.5 Quality of service
- 3.4.1.6 Access types
- 3.4.1.7 Spectral allocation
- 3.4.1.8 Coverage
- 3.4.2 Planning Methodology
- 3.4.3 Cell Planning
- 3.4.3.1 Propagation models
- 3.4.3.2 System in equilibrium
- 3.4.3.3 Determining the geographical area
- 3.4.3.4 Green field cell planning
- 3.4.3.5 Areas covered by the site
- 3.4.3.6 Antenna planning
- 3.4.4 Frequency Planning
- 3.4.4.1 Planning for the future
- 3.4.4.2 Transition from omnidirectional to sectorized
- 3.4.4.3 Interference and coverage analysis
- 3.5 Expansion of the Cellular System
- 3.5.1 Coverage Area and Traffic
- 3.5.1.1 Traffic
- 3.5.1.2 Traffic channel allocation
- 3.5.1.3 Computation of traffic capacity
- 3.5.1.4 Traffic unit
- 3.5.1.5 Cell coverage
- 3.5.1.6 Traffic capacity
- 3.5.2 Spectral Efficiency.
- 3.5.3 Processing Capacity
- 3.5.3.1 Cellular system partitioning
- 3.6 Model to Estimate Costs
- 3.6.1 Problem Characterization
- 3.6.2 Design and Network Planning
- 3.6.3 Green Field Dimensioning
- 3.6.4 Optimum Allocation and Cell Dimensioning
- 3.6.4.1 Mathematical modeling of the economic optimization
- 3.6.4.2 SA to solve the EOM model
- 3.6.5 Planning the Cellular Architecture
- 3.6.6 Detailed Planning for the Final Cost Estimation
- Chapter 4
- Base Station Deploymentbased on Artificial Immune Systems
- 4.1 Introduction
- 4.2 Multi-Objective Optimization
- 4.2.1 The Multi-Objective Optimization Algorithms based on Artificial Immune Systems
- 4.3 Proposed Formulation
- 4.4 Simulation Results
- Chapter 5
- Cost-Effective Base Station Deployment Approach based on Artificial Immune Systems
- 5.1 Simulation Results
- Chapter 6
- Cell Planning Using Voronoi Diagrams
- 6.1 Introduction
- 6.2 The Voronoi Diagram
- 6.2.1 Types of Voronoi Diagrams
- 6.3 The Order-k Voronoi Diagram
- 6.3.1 The Ordered Order-k Voronoi Diagram
- 6.3.2 Order-k Voronoi Diagrams Properties
- 6.4 The Ordered Order-k MWVDs
- 6.5 The Path-Loss Prediction
- 6.6 The Mobile Cellular Network as a Voronoi Diagram
- 6.6.1 Cell Radius
- 6.6.2 The Two-Cell Model
- 6.6.3 Sectored Cells
- 6.6.4 Microcells
- 6.7 Coverage
- An Example
- 6.7.1 Distance Ratio
- 6.8 Spatial Analysis of the Coverage
- 6.9 Outage Contours
- 6.9.1 Interference Model
- 6.9.2 The Distance Ratio
- 6.9.3 An Example
- Bibliography
- Index
- About the Authors
- Back Cover.