Muutke küpsiste eelistusi

Introduction to Ultra Wideband for Wireless Communications 2009 ed. [Kõva köide]

,
  • Formaat: Hardback, 188 pages, kõrgus x laius: 235x155 mm, kaal: 1040 g, XVIII, 188 p., 1 Hardback
  • Sari: Signals and Communication Technology
  • Ilmumisaeg: 14-Oct-2008
  • Kirjastus: Springer-Verlag New York Inc.
  • ISBN-10: 1402066325
  • ISBN-13: 9781402066320
Teised raamatud teemal:
  • Kõva köide
  • Hind: 141,35 €*
  • * hind on lõplik, st. muud allahindlused enam ei rakendu
  • Tavahind: 166,29 €
  • Säästad 15%
  • Raamatu kohalejõudmiseks kirjastusest kulub orienteeruvalt 2-4 nädalat
  • Kogus:
  • Lisa ostukorvi
  • Tasuta tarne
  • Tellimisaeg 2-4 nädalat
  • Lisa soovinimekirja
Introduction to Ultra Wideband for Wireless Communications 2009 ed.Suurem pilt
  • Formaat: Hardback, 188 pages, kõrgus x laius: 235x155 mm, kaal: 1040 g, XVIII, 188 p., 1 Hardback
  • Sari: Signals and Communication Technology
  • Ilmumisaeg: 14-Oct-2008
  • Kirjastus: Springer-Verlag New York Inc.
  • ISBN-10: 1402066325
  • ISBN-13: 9781402066320
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781402066320.html
Märksõnad:
asakta-buddhih sarvatra . jitatma vigata-sprhah . . . . naiskarmya-siddhim paramam . sannyasenadhigacchati Detached by spiritual intelligence from everything controlling the mind, without material desires, one attains the paramount perfection in cessation of re- tions by renunciation. The Bhagvad Gita (18.49) Compared to traditional carrier-based, Ultra-Wide Band (UWB), or carrier-less, systems implement new paradigms in terms of signal generation and reception. Thus, designing an UWB communication system requires the understanding of how excess bandwidth and very low transmitted powers can be used jointly to provide a reliable radio link. UWB offers systems transceiver potential for very simple implementations. Comparison between UWB and traditional narrow-band systems highlights the following features: Large bandwidth enables very fine time-space resolution for accurate lo- tion of the UWB nodes and for distributing network time stamps. Very short pulses are effectively counter-fighting the channel effect in very dense multipath environments. Data rate (number of pulses transmitted per bit) can be traded with power emission control and distance coverage. Very low power density leads to low probability of signal detection and adds security for all the layers of the communication stack. Very low power density is obtained through radio regulation emission masks; UWB systems are suitable for coexistence with already deployed narrow-band systems.

Arvustused

From the reviews:

One of several books on ultra wideband (UWB) technologies, the Introduction to Ultra Wideband for Wireless Communications has coverage overlap with other titles. It includes history, basic theory considerations on UWD-specific issues (bandwidth, circuits, signal processing, and interference), applications and regulatory issues. Intended as a tutorial for graduate students and professionals, the book includes an index, black and white photos and figures, and end-of-chapter summaries and problems. (Bogdan Hoanca, Optics & Photonics News, December, 2009)

1 Introduction
1
1.1 History of UWB
1
1.2 Preview of the Book
7
References
10
2 UWB For Wireless Communications
11
2.1 UWB Definition
12
2.2 FCC Mask
13
2.2.1 Hermite Pulses
19
2.2.2 Legandre Pulses
20
2.2.3 Prolate Spheroidal Functions
22
2.3 UWB Features
25
2.4 Summary
25
Problems
26
References
27
3 UWB Antennas
29
3.1 Antenna Requirements
31
3.2 Radiation Mechanism of the UWB Antennas
31
3.3 Link Budget for UWB System Taking into Account the UWB Antennas
32
3.4 Short Range Analysis of UWB Antennas
37
3.4.1 Phase Error
37
3.4.2 Antenna Mismatch
39
3.4.3 Re-radiation Between Antennas
39
3.5 Summary
40
Problems
40
References
41
4 Ultra Wide Band Wireless Channels
43
4.1 Impulse Response Modeling of UWB Wireless Channels
45
4.1.1 Distribution of Amplitude Fading
46
4.1.2 Distribution of Time of Arrival
50
4.1.3 Path Loss
53
4.1.4 Power-Delay Profiles
55
4.1.5 RMS Delay Spread
56
4.2 Modified Impulse Response Method
57
4.3 The IEEE UWB Channel Model
58
4.4 Frequency Modeling of UWB Channels
60
4.5 Comparison of Time and Frequency Models
62
4.6 Summary
62
Problems
62
References
64
5 UWB Interference
67
5.1 An Example: IEEE802-11.a Interference
68
5.2 General Method of Signal to Interference Ratio Calculation
70
5.3 Interference of UWB to Existing OFDM System
73
5.4 Interference of UWB to Narrowband Systems
80
5.5 Interference to WiMax
82
5.6 Interference Reduction
83
5.7 Interference Mitigation of Wideband System on UWB Using Multicarrier Templates
84
5.8 Summary
89
Problems
89
References
92
6 UWB Signal Processing
93
6.1 Modulation
93
6.1.1 Data Modulation
93
6.1.2 Comparison of Data Modulation Schemes
95
6.1.3 UWB Multiple Access Modulation
98
6.1.4 Uniform Pulse Train Spacing
98
6.1.5 Pseudorandom Time Hopping
100
6.1.6 Direct Sequence UWB (DS-UWB)
100
6.2 BER of Modulation Schemes
100
6.3 Rake Receiver
104
6.4 Transmit-Reference (T-R) Technique
106
6.5 UWB Range- Data Rate Performance
108
6.6 UWB Channel Capacity
6.7 Summary
112
Problems
112
References
115
7 UWB Technologies
117
7.1 Impulse Radio
117
7.1.1 Complexity
119
7.1.2 Power Consumption
119
7.1.3 Security
119
7.1.4 IR Industry Standard Groups
120
7.1.5 Other Features of IR Technology
120
7.2 Pulsed Multiband
120
7.3 Multiband OFDM
121
7.3.1 Complexity
124
7.3.2 Power Consumption
124
7.3.3 Security
124
7.3.4 Costs
124
7.3.5 MB-OFDM Industry Standard Groups
125
7.3.6 Other Features of MB-OFDM Technology
125
7.4 Comparison of UWB Technologies
125
7.4.1 Interference
126
7.4.2 Robustness to Multipath
127
7.4.3 Performance
127
7.4.4 Complexity
128
7.4.5 Achievable Range-Data Rate Performance
129
Problems
131
References
132
8 UWB Wireless Locationing
135
8.1 Position Locationing Methods
136
8.1.1 Received Signal Strength (RSS)
136
8.1.2 Angle of Arrival (AOA)
137
8.1.3 Time of Arrival (TOA)
138
8.2 Time of Arrival Estimation
141
8.2.1 Inverse Filtering Technique
141
8.2.2 ESPRIT Technique
142
8.2.3 CLEAN Technique
143
8.2.4 Super-Resolution Technique
144
8.2.5 Non-Coherent Technique
146
8.3 NLOS Location Error
147
8.4 Locationing with OFDM
148
8.5 Summary
150
Problems
150
References
151
9 UWB Applications
153
9.1 Wireless Ad hoc Networking
153
9.2 UWB Wireless Sensor Networks
155
9.3 RFID
156
9.4 Consumer Electronics and Personal Computers (PC)
157
9.5 Asset Location
157
9.6 Medical Applications
158
9.7 Summary
159
Problems
159
References
160
10 UWB Regulation 163
10.1 UWB Regulation in US
164
10.2 UWB Regulation in Europe
165
10.3 UWB Regulation in Japan
167
10.4 UWB Regulation in Korea
168
10.5 UWB Regulation in Singapore
168
10.6 UWB Regulation in ITU
169
10.7 IEEE Standardization
169
10.8 Summary
170
Problems
171
References
171
11 The Vision of Europe on UWB Applications 173
11.1 Magnet (My Personal Adaptive Global NET)
174
11.1.1 MC-UWB
177
11.1.2 FM-UWB
177
11.1.3 IR-UWB
179
11.1.4 Conclusion on Interfaces
180
11.2 Magnet Beyond
180
11.3 Pulsers (Pervasive Ultra-Wideband Low Spectral Energy Radio Systems)
181
11.4 Summary
183
References
183
Index 185
Prof. Ramjee Prasad is the Director of the Wireless Centre at Aalborg University in Denmark. He recently won a distinguished "Nordic" award for research achievements in the field of wireless communications. Ramjee Prasad is editor-in-chief for our Wireless Personal Communication journal and has also published over 15 books, mostly with Artech House though he is now eager to start publishing more of his books also with Springer.