The Resource Wireless technologies in intelligent transportation systems, Ming-Tuo Zhou, Yan Zhang, and Laurence T. Yang, editors
Wireless technologies in intelligent transportation systems, Ming-Tuo Zhou, Yan Zhang, and Laurence T. Yang, editors
Resource Information
The item Wireless technologies in intelligent transportation systems, Ming-Tuo Zhou, Yan Zhang, and Laurence T. Yang, editors represents a specific, individual, material embodiment of a distinct intellectual or artistic creation found in University of Missouri-St. Louis Libraries.This item is available to borrow from 1 library branch.
Resource Information
The item Wireless technologies in intelligent transportation systems, Ming-Tuo Zhou, Yan Zhang, and Laurence T. Yang, editors represents a specific, individual, material embodiment of a distinct intellectual or artistic creation found in University of Missouri-St. Louis Libraries.
This item is available to borrow from 1 library branch.
- Language
- eng
- Extent
- 1 online resource.
- Contents
-
- WIRELESS TECHNOLOGIES IN INTELLIGENT TRANSPORTATION SYSTEMS ; WIRELESS TECHNOLOGIES IN INTELLIGENT TRANSPORTATION SYSTEMS ; CONTENTS ; PREFACE ; PART 1. HARDWARE, IMPLEMENTATION AND PHYSICALLAYER TECHNOLOGIES; RADAR SENSOR TECHNOLOGY AND TESTREQUIREMENTS IN AUTOMOTIVE APPLICATIONS; Abstract; 1. Introduction; 2. Automotive Radar Technology; Applications Overview; ACC Radar System Requirements; ACC Radar Antenna Types; Radar Types and Modulation Schemes; FM-CW; FSK; Pulse; 3. ACC Radar Test Requirements; Component Level; Sensor Functional Testing; Sensor Alignment on Vehicle
- Optical Mechanical AlignementUsing Internal Angle Measurements; RF Alignment; Built-in Testing and Alignment; 4. Conclusion; References; RADIO CHANNEL MODELINGFOR VEHICLE-TO-VEHICLE/ROADCOMMUNICATIONS; Abstract; Abbreviations; 1. Introduction; 1.1. Defining the V2V and V2R Channels; 1.2. The V2V Channel; 1.3. The V2R Channel; 1.4. V2V/V2R Communication Frequency Bands, and the DSRC Standard; 1.5. V2V/V2R Channels vs. Traditional Mobile Channels; 1.6. Importance of Channel Modeling; 2. Statistical Channel Characteristics; 2.1. Basics; 2.2. Small Scale vs. Large Scale Fading
- 2.3. The Multipath Channel Impulse Response2.4. CIR and CTF Correlation Functions, and Doppler; 2.5. Uncorrelated Scattering; 2.6. Wide-Sense Stationarity; 2.7. Wide-Sense Stationarity, Uncorrelated Scattering; 2.8. Non-stationary Channels and Correlated Scattering; 2.9. Remarks on V2V Channel Statistics; 3. Existing Work on V2V/V2R Channels; 3.1. Deterministic Models; 3.2. Theoretical Statistical Models; 3.3. Empirical Statistical Models; 4. New Non-stationary V2V Channel Models; 4.1. Modeling Multipath Component Persistence
- 4.2. Modeling Propagation Region Transitions and Time-Varying DopplerSpectra4.3. Representative NS V2V Models; Conclusion; Acknowledgments; References; SMART ANTENNAS IN INTELLIGENTTRANSPORTATION SYSTEMS; Abstract; Abbreviations; 1. Introduction; 2. Smart Antennas and Their Benefits for IntelligentTransportation Systems; 2.a. Types of Smart Antennas; 2.b. Benefits of Smart Antennas for ITS; 2.b.1. Spatial Filtering for Interference Reduction; 2.b.2. Space Division Multiple Access (SDMA); 2.b.3. Location Positioning of Mobile Units; 3. Array Data Model and Problem Formulation
- 4. Beamforming Algorithms4.a. Conventional Beamformer; 4.b. Null-steering Beamformer; 4.c. Optimal Beamformer; 4.d. Minimum Mean Square Error (MMSE) Beamformer; 4.e. Adaptive Beamforming Algorithms; 4.e.1. Sample Matrix Inversion (SMI) Algorithm; 4.e.2. Least Mean Square (LMS) Algorithm; 5. Direction of Arrival Estimation; 5.a. MVDR Estimator; 5.b. MUltiple SIgnal Classification (MUSIC) Estimator; 5.c. Estimation of Signal Parameters via Rotational Invariance Technique(ESPRIT); 5.d. Maximum Likelihood (ML) Estimator; 5.d.1. Conditional Maximum Likelihood (CML) Estimator
- Isbn
- 9781611225716
- Label
- Wireless technologies in intelligent transportation systems
- Title
- Wireless technologies in intelligent transportation systems
- Statement of responsibility
- Ming-Tuo Zhou, Yan Zhang, and Laurence T. Yang, editors
- Language
- eng
- Cataloging source
- DLC
- Dewey number
- 629.2/7
- Index
- index present
- Language note
- English
- LC call number
- TE228.3
- Literary form
- non fiction
- Nature of contents
-
- dictionaries
- bibliography
- http://library.link/vocab/relatedWorkOrContributorDate
- 1977-
- http://library.link/vocab/relatedWorkOrContributorName
-
- Zhou, Ming-Tuo
- Zhang, Yan
- Yang, Laurence Tianruo
- Series statement
- Transportation issues, policies and R&D series
- http://library.link/vocab/subjectName
-
- Intelligent transportation systems
- Wireless communication systems
- TRANSPORTATION
- TECHNOLOGY & ENGINEERING
- Intelligent transportation systems
- Wireless communication systems
- Label
- Wireless technologies in intelligent transportation systems, Ming-Tuo Zhou, Yan Zhang, and Laurence T. Yang, editors
- Bibliography note
- Includes bibliographical references and index
- Carrier category
- online resource
- Carrier category code
-
- cr
- Carrier MARC source
- rdacarrier
- Content category
- text
- Content type code
-
- txt
- Content type MARC source
- rdacontent
- Contents
-
- WIRELESS TECHNOLOGIES IN INTELLIGENT TRANSPORTATION SYSTEMS ; WIRELESS TECHNOLOGIES IN INTELLIGENT TRANSPORTATION SYSTEMS ; CONTENTS ; PREFACE ; PART 1. HARDWARE, IMPLEMENTATION AND PHYSICALLAYER TECHNOLOGIES; RADAR SENSOR TECHNOLOGY AND TESTREQUIREMENTS IN AUTOMOTIVE APPLICATIONS; Abstract; 1. Introduction; 2. Automotive Radar Technology; Applications Overview; ACC Radar System Requirements; ACC Radar Antenna Types; Radar Types and Modulation Schemes; FM-CW; FSK; Pulse; 3. ACC Radar Test Requirements; Component Level; Sensor Functional Testing; Sensor Alignment on Vehicle
- Optical Mechanical AlignementUsing Internal Angle Measurements; RF Alignment; Built-in Testing and Alignment; 4. Conclusion; References; RADIO CHANNEL MODELINGFOR VEHICLE-TO-VEHICLE/ROADCOMMUNICATIONS; Abstract; Abbreviations; 1. Introduction; 1.1. Defining the V2V and V2R Channels; 1.2. The V2V Channel; 1.3. The V2R Channel; 1.4. V2V/V2R Communication Frequency Bands, and the DSRC Standard; 1.5. V2V/V2R Channels vs. Traditional Mobile Channels; 1.6. Importance of Channel Modeling; 2. Statistical Channel Characteristics; 2.1. Basics; 2.2. Small Scale vs. Large Scale Fading
- 2.3. The Multipath Channel Impulse Response2.4. CIR and CTF Correlation Functions, and Doppler; 2.5. Uncorrelated Scattering; 2.6. Wide-Sense Stationarity; 2.7. Wide-Sense Stationarity, Uncorrelated Scattering; 2.8. Non-stationary Channels and Correlated Scattering; 2.9. Remarks on V2V Channel Statistics; 3. Existing Work on V2V/V2R Channels; 3.1. Deterministic Models; 3.2. Theoretical Statistical Models; 3.3. Empirical Statistical Models; 4. New Non-stationary V2V Channel Models; 4.1. Modeling Multipath Component Persistence
- 4.2. Modeling Propagation Region Transitions and Time-Varying DopplerSpectra4.3. Representative NS V2V Models; Conclusion; Acknowledgments; References; SMART ANTENNAS IN INTELLIGENTTRANSPORTATION SYSTEMS; Abstract; Abbreviations; 1. Introduction; 2. Smart Antennas and Their Benefits for IntelligentTransportation Systems; 2.a. Types of Smart Antennas; 2.b. Benefits of Smart Antennas for ITS; 2.b.1. Spatial Filtering for Interference Reduction; 2.b.2. Space Division Multiple Access (SDMA); 2.b.3. Location Positioning of Mobile Units; 3. Array Data Model and Problem Formulation
- 4. Beamforming Algorithms4.a. Conventional Beamformer; 4.b. Null-steering Beamformer; 4.c. Optimal Beamformer; 4.d. Minimum Mean Square Error (MMSE) Beamformer; 4.e. Adaptive Beamforming Algorithms; 4.e.1. Sample Matrix Inversion (SMI) Algorithm; 4.e.2. Least Mean Square (LMS) Algorithm; 5. Direction of Arrival Estimation; 5.a. MVDR Estimator; 5.b. MUltiple SIgnal Classification (MUSIC) Estimator; 5.c. Estimation of Signal Parameters via Rotational Invariance Technique(ESPRIT); 5.d. Maximum Likelihood (ML) Estimator; 5.d.1. Conditional Maximum Likelihood (CML) Estimator
- Control code
- 1162524804
- Extent
- 1 online resource.
- Form of item
- online
- Isbn
- 9781611225716
- Lccn
- 2020687779
- Media category
- computer
- Media MARC source
- rdamedia
- Media type code
-
- c
- Specific material designation
- remote
- System control number
- (OCoLC)1162524804
- Label
- Wireless technologies in intelligent transportation systems, Ming-Tuo Zhou, Yan Zhang, and Laurence T. Yang, editors
- Bibliography note
- Includes bibliographical references and index
- Carrier category
- online resource
- Carrier category code
-
- cr
- Carrier MARC source
- rdacarrier
- Content category
- text
- Content type code
-
- txt
- Content type MARC source
- rdacontent
- Contents
-
- WIRELESS TECHNOLOGIES IN INTELLIGENT TRANSPORTATION SYSTEMS ; WIRELESS TECHNOLOGIES IN INTELLIGENT TRANSPORTATION SYSTEMS ; CONTENTS ; PREFACE ; PART 1. HARDWARE, IMPLEMENTATION AND PHYSICALLAYER TECHNOLOGIES; RADAR SENSOR TECHNOLOGY AND TESTREQUIREMENTS IN AUTOMOTIVE APPLICATIONS; Abstract; 1. Introduction; 2. Automotive Radar Technology; Applications Overview; ACC Radar System Requirements; ACC Radar Antenna Types; Radar Types and Modulation Schemes; FM-CW; FSK; Pulse; 3. ACC Radar Test Requirements; Component Level; Sensor Functional Testing; Sensor Alignment on Vehicle
- Optical Mechanical AlignementUsing Internal Angle Measurements; RF Alignment; Built-in Testing and Alignment; 4. Conclusion; References; RADIO CHANNEL MODELINGFOR VEHICLE-TO-VEHICLE/ROADCOMMUNICATIONS; Abstract; Abbreviations; 1. Introduction; 1.1. Defining the V2V and V2R Channels; 1.2. The V2V Channel; 1.3. The V2R Channel; 1.4. V2V/V2R Communication Frequency Bands, and the DSRC Standard; 1.5. V2V/V2R Channels vs. Traditional Mobile Channels; 1.6. Importance of Channel Modeling; 2. Statistical Channel Characteristics; 2.1. Basics; 2.2. Small Scale vs. Large Scale Fading
- 2.3. The Multipath Channel Impulse Response2.4. CIR and CTF Correlation Functions, and Doppler; 2.5. Uncorrelated Scattering; 2.6. Wide-Sense Stationarity; 2.7. Wide-Sense Stationarity, Uncorrelated Scattering; 2.8. Non-stationary Channels and Correlated Scattering; 2.9. Remarks on V2V Channel Statistics; 3. Existing Work on V2V/V2R Channels; 3.1. Deterministic Models; 3.2. Theoretical Statistical Models; 3.3. Empirical Statistical Models; 4. New Non-stationary V2V Channel Models; 4.1. Modeling Multipath Component Persistence
- 4.2. Modeling Propagation Region Transitions and Time-Varying DopplerSpectra4.3. Representative NS V2V Models; Conclusion; Acknowledgments; References; SMART ANTENNAS IN INTELLIGENTTRANSPORTATION SYSTEMS; Abstract; Abbreviations; 1. Introduction; 2. Smart Antennas and Their Benefits for IntelligentTransportation Systems; 2.a. Types of Smart Antennas; 2.b. Benefits of Smart Antennas for ITS; 2.b.1. Spatial Filtering for Interference Reduction; 2.b.2. Space Division Multiple Access (SDMA); 2.b.3. Location Positioning of Mobile Units; 3. Array Data Model and Problem Formulation
- 4. Beamforming Algorithms4.a. Conventional Beamformer; 4.b. Null-steering Beamformer; 4.c. Optimal Beamformer; 4.d. Minimum Mean Square Error (MMSE) Beamformer; 4.e. Adaptive Beamforming Algorithms; 4.e.1. Sample Matrix Inversion (SMI) Algorithm; 4.e.2. Least Mean Square (LMS) Algorithm; 5. Direction of Arrival Estimation; 5.a. MVDR Estimator; 5.b. MUltiple SIgnal Classification (MUSIC) Estimator; 5.c. Estimation of Signal Parameters via Rotational Invariance Technique(ESPRIT); 5.d. Maximum Likelihood (ML) Estimator; 5.d.1. Conditional Maximum Likelihood (CML) Estimator
- Control code
- 1162524804
- Extent
- 1 online resource.
- Form of item
- online
- Isbn
- 9781611225716
- Lccn
- 2020687779
- Media category
- computer
- Media MARC source
- rdamedia
- Media type code
-
- c
- Specific material designation
- remote
- System control number
- (OCoLC)1162524804
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<div class="citation" vocab="http://schema.org/"><i class="fa fa-external-link-square fa-fw"></i> Data from <span resource="http://link.umsl.edu/portal/Wireless-technologies-in-intelligent/uS3H01jnqOM/" typeof="Book http://bibfra.me/vocab/lite/Item"><span property="name http://bibfra.me/vocab/lite/label"><a href="http://link.umsl.edu/portal/Wireless-technologies-in-intelligent/uS3H01jnqOM/">Wireless technologies in intelligent transportation systems, Ming-Tuo Zhou, Yan Zhang, and Laurence T. Yang, editors</a></span> - <span property="potentialAction" typeOf="OrganizeAction"><span property="agent" typeof="LibrarySystem http://library.link/vocab/LibrarySystem" resource="http://link.umsl.edu/"><span property="name http://bibfra.me/vocab/lite/label"><a property="url" href="http://link.umsl.edu/">University of Missouri-St. Louis Libraries</a></span></span></span></span></div>