1 SMART ANTENNAS FOR WIRELESS COMMUNICATIONS JACK H. WINTERS AT&T Labs - Research Red Bank, NJ 07701-7033 September 9, 1999.

Slides:

Advertisements

Similar presentations

International Technology Alliance In Network & Information Sciences International Technology Alliance In Network & Information Sciences 1 Interference.

Advertisements

GSC: Standardization Advancing Global Communications Evolution of TD-SCDMA China Communications Standards Association (CCSA) Chicago, May 29th to 2nd June,

Slide 1Thursday, June 30, /05/03 EMERGING TECHNOLOGIES IN WIRELESS Jack H. Winters Chief Scientist, Motia

CELLULAR COMMUNICATIONS. LTE Data Rate Requirements And Targets to LTE  reduced delays, in terms of both connection establishment and transmission.

The Mobile MIMO Channel and Its Measurements

1 Smart Antennas for Mobile Wireless Systems Jack H. Winters May 6, 2003

Multiple Access Techniques for wireless communication

Comparison of different MIMO-OFDM signal detectors for LTE

Wednessday, October 8, 2003Slide 1 VTC2003 Fall Integration of Cellular Systems with WLAN and Internet Jack Winters Chief Scientist, Motia, Inc.

1 SMART ANTENNAS FOR THIRD GENERATION TDMA (EDGE) Jack H. Winters AT&T Labs - Research Red Bank, NJ October 3, 2000.

1/44 1. ZAHRA NAGHSH JULY 2009 BEAM-FORMING 2/44 2.

EE360: Lecture 12 Outline Cellular Systems Overview Design Considerations Access Techniques Cellular System Capacity Performance Enhancements Interference.

RAKE Receiver Marcel Bautista February 12, Propagation of Tx Signal.

SMART ANTENNAS. Smart Antennas The presentation is divided into the following: Why? What? How?

Overview.  UMTS (Universal Mobile Telecommunication System) the third generation mobile communication systems.

APPLICATION OF SPACE-TIME CODING TECHNIQUES IN THIRD GENERATION SYSTEMS - A. G. BURR ADAPTIVE SPACE-TIME SIGNAL PROCESSING AND CODING – A. G. BURR.

#7 1 Victor S. Frost Dan F. Servey Distinguished Professor Electrical Engineering and Computer Science University of Kansas 2335 Irving Hill Dr. Lawrence,

1 SMART ANTENNA TECHNIQUES AND THEIR APPLICATION TO WIRELESS AD HOC NETWORKS JACK H. WINTERS /11/13 碩一謝旻欣.

SMART ANTENNA SYSTEMS. Increasing use in Mobile Wireless Communications due to demand for  Higher Capacity  Higher Coverage  Higher bit rate  Improved.

6: Wireless and Mobile Networks Wireless LANs.

EE 525 Antenna Engineering

Frequencies (or time slots or codes) are reused at spatially-separated locations  exploit power falloff with distance. Best efficiency obtained with minimum.

February 26, 2004Slide 1 Little Wireless and Smart Antennas Little Wireless and Smart Antennas Jack H. Winters 2/26/04.

Smart Antennas for Wireless System

1 Wireless and Mobile Networks EECS 489 Computer Networks Z. Morley Mao Monday March 12, 2007 Acknowledgement:

MIMO WIRELESS COMMUNICATION SYSTEMS Bhaskar D. Rao University of California, San Diego La Jolla, CA

Project Title: Data Access Points in Tiered Wireless Networks PI: Shalinee Kishore, Ph.D. Graduate Assistant: Zhenlei Shen Introduction & Objective In.

MULTIPLE INPUT MULTIPLE OUTPUT SYSTEMS (MIMO)

Slide 1Sunday, March 21, /05/03 Smart Antennas for Wireless Systems Jack H. Winters May 31, 2004

For 3-G Systems Tara Larzelere EE 497A Semester Project.

John Thornton, Yuriy Zakharov, David Grace

Telecommunications Networking II Lecture 39 Next Generation Wireless.

Wireless Communications. Outline Introduction History System Overview Signals and Propagation Noise and Fading Modulation Multiple Access Design of Cellular.

SMART ANTENNA SYSTEMS IN BWA Submitted by M. Venkateswararao.

by P. Sriploy, M. Uthansakul and R. Wongsan

1 PROPAGATION ASPECTS FOR SMART ANTENNAS IN WIRELESS SYSTEMS JACK H. WINTERS AT&T Labs - Research Red Bank, NJ July 17,

SMART ANTENNA under the guidance of Mr. G.V.Kiran Kumar EC

6: Wireless and Mobile Networks6-1 Chapter 6 Wireless and Mobile Networks Computer Networking: A Top Down Approach Featuring the Internet, 3 rd edition.

Multiuser Detection (MUD) Combined with array signal processing in current wireless communication environments Wed. 박사 3학기 구 정 회.

Propagation Measurements and Models for Wireless Communication Channels 指導教授：黃文傑老師學　　生：曾凱霖學　　號：M 無線通訊實驗室.

Ch 11. Multiple Antenna Techniques for WMNs Myungchul Kim

1 SMART ANTENNAS FOR TDMA Jack H. Winters AT&T Labs - Research Red Bank, NJ September 7, 2000.

Designing for High Density Wireless LANs Last Update Copyright Kenneth M. Chipps Ph.D.

S MART A NTENNA B.GANGADHAR 08QF1A1209. ABSTRACT One of the most rapidly developing areas of communications is “Smart Antenna” systems. This paper deals.

Introduction to Smart Antenna Advisor ： Dr. Wen-Jye Huang Student ： Chi-Ting Wu Wireless Communication LAB.

Network and Systems Laboratory nslab.ee.ntu.edu.tw Branislav Kusy, Christian Richter, Wen Hu, Mikhail Afanasyev, Raja Jurdak, Michael Brunig, David Abbott,

Vidya Bharathi Institute of Technology

Space Time Codes. 2 Attenuation in Wireless Channels Path loss: Signals attenuate due to distance Shadowing loss : absorption of radio waves by scattering.

1 SMART ANTENNAS FOR THIRD GENERATION TDMA (EDGE) Jack H. Winters AT&T Labs - Research Red Bank, NJ July 17, 2000.

1 SMART ANTENNAS FOR THIRD GENERATION TDMA (EDGE) Jack H. Winters AT&T Labs - Research Red Bank, NJ March 22, 2000.

Click to edit Master title style Click to edit Master text styles Second level Third level Fourth level Fifth level Wednesday, December 3, 2003Slide 1.

HISTORY OF COMMUNICATION - CONTENT - communication systems overview - Introduction to Cellular Fundamentals - Network Architecture - GSM Air Interface.

Data and Computer Communications Tenth Edition by William Stallings Data and Computer Communications, Tenth Edition by William Stallings, (c) Pearson Education.

Antenna Arrays and Automotive Applications

SMART ANTENNAS SMART ANTENNAS apoorva k. Shetti 2bu09ec006

[1] TECHNICAL SEMINAR PRESENTATION SMART ANTENNA Edited by: Priyabrata Nayak, Lecturer, Dept. of CSE SMART ANTENNA.

Transmission Techniques Traffic channels: different users are assigned unique code and transmitted over the same frequency band, for example, WCDMA and.

EE 525 Antenna Engineering

SMART ANTENAS Presentation by Mr. Sahil Tarfe Mr. Siddhesh Sonawdekar.

Advanced Wireless Communication Systems

Digital transmission over a fading channel

Wednesday, November 07, 2018 Little Wireless and Smart Antennas Jack H. Winters 2/26/04.

Wednesday, November 21, 2018 Little Wireless and Smart Antennas Jack H. Winters 2/26/04.

Active Beam MobiRake TDMA/OFDM Radio

Hanks H. Zeng Ye Li Jack H. Winters AT&T Labs - Research Red Bank, NJ

Subject Name: Adhoc Networks Subject Code: 10CS841

EE 525 Antenna Engineering

Presentation transcript:

1 SMART ANTENNAS FOR WIRELESS COMMUNICATIONS JACK H. WINTERS AT&T Labs - Research Red Bank, NJ September 9, 1999

2 AGENDA Background Use of adaptive antennas Key research issues Conclusions

3 Smart Antennas Smart Antenna Definition: Phased array or adaptive array antenna which adjusts to the environment. From site visits: “Smart antenna technology is the most (or one of the most) important technology for 4G cellular systems” (speakers at NTT, Filtronics, etc.). SIGNAL OUTPUT SIGNAL INTERFERENCE BEAMFORMER WEIGHTS SIGNAL OUTPUT BEAM SELECT SIGNAL BEAMFORMER Adaptive Antenna ArrayPhased Array

4 Power: –Higher data rates need higher power for the adequate reliability and perhaps higher frequencies (which have higher propagation and circuit losses) Interference suppression: –For higher capacity with frequency reuse Multipath mitigation: –For more reliable and robust communications Future Systems Will Need Greater:

5 Power: –Phased arrays provide narrow pencil beams with higher gain, particularly at higher frequencies, as do adaptive arrays Interference suppression: –Phased arrays reduce probability of interference, and adaptive arrays suppress interference Multipath mitigation: –Diversity (spatial, polarization, and angle) Smart Antennas Provide:

6 From site visits, phased arrays and adaptive arrays are considered and researched about equally Phased arrays: –Point-to-point –Some macrocellular base stations (e.g., GSM) –On satellites and on satellite terminals Adaptive arrays: –Indoor systems –Microcells –Some cellular base stations (e.g., ANSI-136) –Terminals Smart Antennas Use:

7 Cost: –Power 50% of power is in RF electronics, adding more antennas increases power usage (decreases terminal battery life) –RF electronics and A/D are expensive –Low cost phased array –Cost limits the number of antenna elements that can be used –Solutions being studied: Optical beamforming for large phased arrays Integrated antennas Limited introduction Size: –Antenna on a chip –“Antenna-less” terminals Key Research Issues:

8 Diversity: –Multiple antennas for diversity –Spatial (separation) Difficult on handset Difficult for point-to-point or base stations with small angular spread –Polarization (dual diversity only) –Angle (direction/pattern) Multibeam antennas (depends on angular spread) Antennas on handset where hand placement is critical Minimize headloss Key Research Issues:

9 Tracking –Angle-of-arrival with phased arrays –Weights with adaptive arrays –Signal processing horsepower is not considered a significant research issue for tracking in most future systems –Better algorithms required: AOA with MUSIC/ESPRIT today, but need to be robust with angular spread, obtain higher resolution Adaptive array needs better subspace tracking methods: –higher data rates => longer equalizers => longer training sequences => greater overhead Key Research Issues:

10 Spatial-Temporal Processing: –Equalization of intersymbol interference (delay spread at high data rates) with cochannel interference suppression Better architectures needed –Space-Time coding interference suppression tracking –BLAST/MIMO technology M-fold increase in capacity with M antennas without increase in power or bandwidth Extension to outdoors with tracking and multipath richness issues Cochannel interference suppression Key Research Issues:

11 Hooks in standards (interdisciplinary research - protocols): –Incorporate features so that smart antennas are possible –2G system problems: ANSI-136: continuous downlink IS-95: common downlink pilot –3G hooks: WCDMA: Downlink pilots dedicated to each user EDGE: Signals from base stations that need to be broadcast to all users restrict smart antenna usage –4G: Any packet/multimedia access to all users is a critical issue for smart antennas Key Research Issues:

12 Vertical Integration/Interdisciplinary Approach –Protocols for smart antennas - pilots and broadcast signals –Interaction with frequency hopping, power control, discontinuous transmission, adaptive channel assignment –RF matching (multiband antennas) –Adaptation to hand position –Limited introduction with nonuniform traffic –Ad hoc networks –Channel characterization –Base versus terminal antenna (complexity) tradeoffs –Transmit diversity with space-time coding Key Research Issues:

13 Future system needs: higher data rates/better coverage/ubiquitous users and systems Smart antennas are seen as a critical component to satisfy these needs - significant research in nearly all wireless companies visited Substantial research to reduce cost, develop technologies, and integrate into future systems is required to achieve these goals Conclusions