书籍详情
无线传感器网络同步技术
作者:(美)塞佩丁 等著
出版社:科学出版社
出版时间:2011-06-01
ISBN:9787030315205
定价:¥50.00
购买这本书可以去
内容简介
无线传感器网络在民用与军用设备中有着广泛的应用。微传感器以无线互联的形式完成高度分散系统中的感应、计算、通信以及控制等工作。塞佩丁编著的《无线传感器网络同步技术(影印版)》介绍了无线传感器网络部署中的一项最关键的技术:同步技术。《无线传感器网络同步技术》概述了无线传感器网络中的时钟同步协议,着重讲解了导出高效时钟补偿评估方法以及运行评估指标等技术手段。《无线传感器网络同步技术(影印版)》适合电子信息专业、计算机专业的高年级本科生、研究生以及相关研究人员阅读。
作者简介
暂缺《无线传感器网络同步技术》作者简介
目录
PREFACE page XI
1 INTRODUCTION page
1.1 Wireless Sensor Networks
1.2 Time Synchronization
1.3 Importance of Time Synchronization
1.4 History of Clock Synchronization
1.5 Outline
2 SIGNAL MODELS FOR TIME SYNCHRONIZATION page lO
2.1 Definition of Clock lo
2.2 Design Considerations
2.3 Delay Components in Timing Message Delivery
3 TIME SYNCHRONIZATION PROTOCOLS page
3.1 Pairwise Synchronization -
3.1.1 Timing-Sync Protocol for Sensor Networks(TPSN)
3.1.2 Tiny-Sync and Mini-Sync
3.1.3 Reference Broadcast Synchronization(RBS)
3.1.4 Flooding Time Synchronization Protocol(FTSP)
3.2 Network-Wide Synchronization
3.2.1 Extension of TPSN
3.2.2 Lightweight Time Synchronization(LTS)
3.2.3 Extension of RBS
3.2.4 Extension of FTSP
3.2.5 Pairwise Broadcast Synchronization(PBS)
3.2.6 Time Diffusion Protocol (TDP)
3.2.7 Synchronous and Asynchronous DiffusionAlgorithms
3.2.8 Protocols Based on Pulse Transmissions-
3.3 Adaptive Time Synchronization
3.3.1 Rate-Adaptive Time Synchronization(RATS)
3.3.2 RBS-based Adaptive ClockSynchronization
3.3.3 Adaptive Multi-Hop TimeSynchronization (AMTS)
4 FUNDAMENTAL APPROACHES TO TIME SYNCHRONIZATION page
4.1 Sender-Receiver Synchronization (SRS)
4.2 Receiver-Only Synchronization (ROS)
4.3 Receiver-Receiver Synchronization(RRS)
4.4 COmparisons
5 MINIMUM VARIANCE UNBIASED ESTIMATION (MVUE)OF CLOCK OFFSET page
5.1 The System Architecture -
5.2 Best Linear Unbiased Estimation Using OrderStatistics(BLUE-OS)
5.2.1 Symmetric Link Delays
5.2.2 Asymmetric Link Delays -
5.3 Minimum Variance Unbiased Estimation (MVUE)
5.3.1 Asymmetric Link Delays
5.3.2 Symmetric Link Delays
5.4 Explanatory Remarks
6 CLOCK OFFSET AND SKEW ESTIMATION page
6.1 Gaussian Delay Model
6.1.1 Maximum Likelihood (ML) Clock OffsetEstimation -
6.1.2 Cramer-Rao Lower Bound (CRLB) for ClockOffset
6.1.3 Joint Maximum Likelihood Estimation (JMLE)of Clock Offset and Skew
6.1.4 Cramer-Rao Lower Bound (CRLB) for ClockOffset and Skew
6.2 Exponential Delay Model.
6.2.1 Cramer-Rao Lower Bound (CRLB) for ClockOffset -
6.2.2 Joint Maximum Likelihood Estimation (JMLE)of Clock Offsetand Skew
7 COMPUTATIONALLY SIMPLIFIED ScHEMEs FOR ESTIMATION OF CLOCK OFFSETAND SKEW page
7.1 Using the First and the Last DataSample
7.1.1 Gaussian Delay Model
7.1.2 Exponential Delay Model
7.1.3 Combination of Clock Offset and SkewEstimation
7.1.4 Simulation Results
7.2 Fitting the Line Between Two Points at Minimum DistanceApart
7.2.I Simulation Results lol
7.2.2 Computational Complexity Comparison lo
8 PAIRWISE BROADCAST SYNCHRONIZATION (PBS) - page lo
8.1 Synchronization for Single-Cluster Networks lo
8.2 Comparisons and Analysis lo
8.3 Synchronization for Multi-Cluster Networks - lo
8.3.1 Network-Wide Pair SelectionAlgorithm (NPA) lO
8.3.2 Group-Wise Pair Selection Algorithm(GPA) - 1io
8.4 Comparisons and Analysis
9 ENERGY-EFFICIENT ESTIMATION OF CLOCK OFFSET FOR INACTIVENODES page
9.1 Problem Formulation
9.2 Maximum Likelihood Estimation (MLE)
9.3 Cramer-Rao Lower Bound (CRLB)
9.3.1 CRLB for the Clock Offset of Inactive Nodeq
9.3.2 CRLB for the Clock Offset of Active Nodet'
9.4 Simulation Results
10 SOME IMPROVED AND GENERALIZED ESTIMATION SCHEMES FOR CLOCKSYNCHRONIZATION OF INACTIVE NODES page
10.1 Asymmetric Exponential Link Delays
10.1.1 Best Linear Unbiased EstimationUsing Order Statistics (BLUE-OS)
10.1.2 Minimum Variance Unbiased Estimation(MVUE)
10.1.3 Minimum Mean Square Error (MMSE)Estimation
10.2 Symmetric Exponential Link Delays -
10.2.1 Best Linear Unbiased EstimationUsing Order Statistics(BLUE-OS)
10.2.2 Minimum Variance UnbiasedEstimation (MVUE)
10.2.3 Minimum Mean Square Error (MMSE)Estimation
11 ADAPTIVE MULTI=HOP TIME SYNCHRONIZATION (AMTS) pageI
11.1 Main Ideas -
11.2 Level Discovery Phase
11.3 Synchronization Phase
11.4 Network Evaluation Phase 16o
11.4.1 Synchronization Mode Selection 16o
11.4.2 Determination of SynchronizationPeriod
11.4.3 Determination of the Number ofBeacons
11.4.4 Sequential Multi-HopSynchronization Algorithm (SMA)
11.5 Simulation Results -
12 CLOCK DRIFT ESTIMATION FOR ACHIEVING LONG-TERM SYNCHRONIZATION -page
12.1 Problem Formulation 17o
12.2 The Estimation Procedure
13 JOINT SYNCHRONIZATION OF CLOCK OFFSET AND SKEW IN aRECEIVER-REcEIVER PROTOCOL page
13.1 Modeling Assumptions
13.2 Joint Maximum Likelihood Estimation (JMLE)of the Offsetand Skew
13.3 Application of the Gibbs Sampler
13.4 Performance Bounds and Simulations
14 ROBUST ESTIMATION OF CLOCK OFFSET page
14.1 Problem Modeling and Objectives -
14.2 Gaussian Mixture Kalman Particle Filter(GMKPF)
14.3 Testing the Performance of GMKPF -
14.4 Composite Particle Filtering (CPF) with BootstrapSampling (BS)
14.5 Testing the Performance of CPF and CPF withBS
15 CONCLUSIONS AND FUTURE DIRECTIONS page
ACRONYMS page
REFERENCES page
INDEX page
1 INTRODUCTION page
1.1 Wireless Sensor Networks
1.2 Time Synchronization
1.3 Importance of Time Synchronization
1.4 History of Clock Synchronization
1.5 Outline
2 SIGNAL MODELS FOR TIME SYNCHRONIZATION page lO
2.1 Definition of Clock lo
2.2 Design Considerations
2.3 Delay Components in Timing Message Delivery
3 TIME SYNCHRONIZATION PROTOCOLS page
3.1 Pairwise Synchronization -
3.1.1 Timing-Sync Protocol for Sensor Networks(TPSN)
3.1.2 Tiny-Sync and Mini-Sync
3.1.3 Reference Broadcast Synchronization(RBS)
3.1.4 Flooding Time Synchronization Protocol(FTSP)
3.2 Network-Wide Synchronization
3.2.1 Extension of TPSN
3.2.2 Lightweight Time Synchronization(LTS)
3.2.3 Extension of RBS
3.2.4 Extension of FTSP
3.2.5 Pairwise Broadcast Synchronization(PBS)
3.2.6 Time Diffusion Protocol (TDP)
3.2.7 Synchronous and Asynchronous DiffusionAlgorithms
3.2.8 Protocols Based on Pulse Transmissions-
3.3 Adaptive Time Synchronization
3.3.1 Rate-Adaptive Time Synchronization(RATS)
3.3.2 RBS-based Adaptive ClockSynchronization
3.3.3 Adaptive Multi-Hop TimeSynchronization (AMTS)
4 FUNDAMENTAL APPROACHES TO TIME SYNCHRONIZATION page
4.1 Sender-Receiver Synchronization (SRS)
4.2 Receiver-Only Synchronization (ROS)
4.3 Receiver-Receiver Synchronization(RRS)
4.4 COmparisons
5 MINIMUM VARIANCE UNBIASED ESTIMATION (MVUE)OF CLOCK OFFSET page
5.1 The System Architecture -
5.2 Best Linear Unbiased Estimation Using OrderStatistics(BLUE-OS)
5.2.1 Symmetric Link Delays
5.2.2 Asymmetric Link Delays -
5.3 Minimum Variance Unbiased Estimation (MVUE)
5.3.1 Asymmetric Link Delays
5.3.2 Symmetric Link Delays
5.4 Explanatory Remarks
6 CLOCK OFFSET AND SKEW ESTIMATION page
6.1 Gaussian Delay Model
6.1.1 Maximum Likelihood (ML) Clock OffsetEstimation -
6.1.2 Cramer-Rao Lower Bound (CRLB) for ClockOffset
6.1.3 Joint Maximum Likelihood Estimation (JMLE)of Clock Offset and Skew
6.1.4 Cramer-Rao Lower Bound (CRLB) for ClockOffset and Skew
6.2 Exponential Delay Model.
6.2.1 Cramer-Rao Lower Bound (CRLB) for ClockOffset -
6.2.2 Joint Maximum Likelihood Estimation (JMLE)of Clock Offsetand Skew
7 COMPUTATIONALLY SIMPLIFIED ScHEMEs FOR ESTIMATION OF CLOCK OFFSETAND SKEW page
7.1 Using the First and the Last DataSample
7.1.1 Gaussian Delay Model
7.1.2 Exponential Delay Model
7.1.3 Combination of Clock Offset and SkewEstimation
7.1.4 Simulation Results
7.2 Fitting the Line Between Two Points at Minimum DistanceApart
7.2.I Simulation Results lol
7.2.2 Computational Complexity Comparison lo
8 PAIRWISE BROADCAST SYNCHRONIZATION (PBS) - page lo
8.1 Synchronization for Single-Cluster Networks lo
8.2 Comparisons and Analysis lo
8.3 Synchronization for Multi-Cluster Networks - lo
8.3.1 Network-Wide Pair SelectionAlgorithm (NPA) lO
8.3.2 Group-Wise Pair Selection Algorithm(GPA) - 1io
8.4 Comparisons and Analysis
9 ENERGY-EFFICIENT ESTIMATION OF CLOCK OFFSET FOR INACTIVENODES page
9.1 Problem Formulation
9.2 Maximum Likelihood Estimation (MLE)
9.3 Cramer-Rao Lower Bound (CRLB)
9.3.1 CRLB for the Clock Offset of Inactive Nodeq
9.3.2 CRLB for the Clock Offset of Active Nodet'
9.4 Simulation Results
10 SOME IMPROVED AND GENERALIZED ESTIMATION SCHEMES FOR CLOCKSYNCHRONIZATION OF INACTIVE NODES page
10.1 Asymmetric Exponential Link Delays
10.1.1 Best Linear Unbiased EstimationUsing Order Statistics (BLUE-OS)
10.1.2 Minimum Variance Unbiased Estimation(MVUE)
10.1.3 Minimum Mean Square Error (MMSE)Estimation
10.2 Symmetric Exponential Link Delays -
10.2.1 Best Linear Unbiased EstimationUsing Order Statistics(BLUE-OS)
10.2.2 Minimum Variance UnbiasedEstimation (MVUE)
10.2.3 Minimum Mean Square Error (MMSE)Estimation
11 ADAPTIVE MULTI=HOP TIME SYNCHRONIZATION (AMTS) pageI
11.1 Main Ideas -
11.2 Level Discovery Phase
11.3 Synchronization Phase
11.4 Network Evaluation Phase 16o
11.4.1 Synchronization Mode Selection 16o
11.4.2 Determination of SynchronizationPeriod
11.4.3 Determination of the Number ofBeacons
11.4.4 Sequential Multi-HopSynchronization Algorithm (SMA)
11.5 Simulation Results -
12 CLOCK DRIFT ESTIMATION FOR ACHIEVING LONG-TERM SYNCHRONIZATION -page
12.1 Problem Formulation 17o
12.2 The Estimation Procedure
13 JOINT SYNCHRONIZATION OF CLOCK OFFSET AND SKEW IN aRECEIVER-REcEIVER PROTOCOL page
13.1 Modeling Assumptions
13.2 Joint Maximum Likelihood Estimation (JMLE)of the Offsetand Skew
13.3 Application of the Gibbs Sampler
13.4 Performance Bounds and Simulations
14 ROBUST ESTIMATION OF CLOCK OFFSET page
14.1 Problem Modeling and Objectives -
14.2 Gaussian Mixture Kalman Particle Filter(GMKPF)
14.3 Testing the Performance of GMKPF -
14.4 Composite Particle Filtering (CPF) with BootstrapSampling (BS)
14.5 Testing the Performance of CPF and CPF withBS
15 CONCLUSIONS AND FUTURE DIRECTIONS page
ACRONYMS page
REFERENCES page
INDEX page
猜您喜欢