Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Fourth Generation Wireless Systems Jack H. Winters May 6, 2003

Published byJoella Jacobs Modified over 8 years ago

Similar presentations

Presentation on theme: "1 Fourth Generation Wireless Systems Jack H. Winters May 6, 2003"— Presentation transcript:

1 1 Fourth Generation Wireless Systems Jack H. Winters May 6, 2003 jack@jackwinters.com jwinters@motia.com

2 2 Goal Wireless communications, anywhere, in any form In any form: –high-speed data (Internet) –voice –audio (music) –video Anywhere: –home –buildings (office) –pedestrian –vehicles

3 3 OUTLINE Current Systems Current Trends Technical Issues –Smart Antennas –Radio Resource Management Conclusions

4 4 Current Systems 10 feet100 feet1 mile10 miles 100 kbps 1 Mbps 10 Mbps 100 Mbps 3G Wireless ~ 2GHz BlueTooth 2.4GHz 802.11a 5.5GHz Unlicensed 802.11b 2.4GHz Unlicensed Peak Data Rate Range 2 mph10 mph30 mph 60 mph $ 500,000 $ 1000 $ 100 $ 500 $ 100 $ 10 $/Cell $/Sub High performance/price High ubiquity and mobility Mobile Speed UWB 3.1-10.6 GHz

5 5 Cellular Data CDPD (US) < 10 kbps GPRS = 30-40 kbps EDGE/1xRTT = 80 kbps WCDMA = 100 kbps (starting in Japan, but not for several years in US)

6 6 Data rate: 1, 2, 5.5, 11 Mbps Modulation/Spreading: Direct Sequence Spread Spectrum (DSSS) DBPSK, DQPSK with 11-chip Barker code (1, 2 Mbps) (this mode stems from the original 802.11 standard) 8-chip complementary code keying (CCK) (5.5, 11 Mbps) optional: packet binary convolutional coding (PBCC), 64 state, rate 1/2 CC (BPSK 5.5 Mbps, QPSK 11 Mbps) Barker Key 802.11b Physical Layer Parameters: Chip rate:11 MHz Frequency band:Industrial, Scientific and Medical (ISM, unlicensed) 2.4 - 2.4835 GHz Bandwidth:22 MHz - TDD Channel spacing:5 MHz Total of 14 (but only the first 11 are used in the US), with only 3 nonoverlapping channels Number of channels: Transmission modes: (dynamic rate shifting) CCK 1  s 11 chips Barker 727 ns 8 chips CCK WLANs: 802.11b

7 7 Unlicensed national infrastructure (U-NII), 5.5 GHz Total of 12 in three blocks between 5 and 6 GHz Data rate:6, 9, 12, 18, 24, 36, 48, 54 Mbps Modulation:BPSK, QPSK, 16QAM, 64QAM Coding rate:1/2, 2/3, 3/4 Subcarriers:52 Pilot subcarriers:4 G 3.2  s 4  s FFT 52=48+4 tones 64 point FFT Key 802.11a Physical Layer Parameters: Symbol duration: 4  s Guard interval:800 ns Subcarrier spacing:312.5 kHz Bandwidth:16.56 MHz - TDD Channel spacing:20 MHz FFT size:64 : BPSKQPSKQAM16QAM64 61224 R=1/2 48 R=2/3 9183654 R=3/4 User data rates (Mbps): Frequency band: Number of channels: WLANs: 802.11a (g in 2.4 GHz band)

8 8 Current Trends Business WLANs dominate, but home usage growing faster (14 million WLANs sold last year) Spontaneous appearance of neighborhood/residential access sites via consumer broadband wire-line connections Public WLAN offerings for enterprise and home users when they are away from the office or home –Players: Wayport: Covers over 450 hotels & 9 airports US, Canada, UK Cometa (AT&T,Intel,IBM) Aggregators: –Deep Blue Wireless (hotels and coffee houses) –Joltage –Sputnik –Boingo Wireless//

9 9 Community 802.11b LANs North America –Bay Area Wireless User Group –Equip2rip (Oahu, HI) –Guerrilla.net (Boston) –Pdx Personal Telco –pdxwireless.org (Portland, Oregon) –SBAY.ORG Wireless Network (San Francisco Bay Area) –Seattle Wireless (Seattle) –Seattle Wireless Internet Project –SFLAN (San Francisco) –Xlan (Seattle) Europe –Consume (London, UK) –Elektrosmog (Stockholm and Gothenburg) –Wlan.org.uk (UK) –Wireless France (France) –Wireless MediaPoli (Helsinki) Australia Bay Area 802.11b Access Point Map

10 10 Possible Strategies Broadband Residential Access –Provide 802.11b’s to selected cable modem customers or pole locations for universal wireless high-speed data coverage (1 mile radius) with access to other homes in neighborhood –Since cable modem is at 1.5 Mbps and 802.11b is at 11 Mbps, provide fiber to these selected homes or poles (economical for selected homes) Broadband Business Access –Fiber to building access points (e.g., floors) –Extend to residences for virtual offices

11 11 WLAN Overlay for Broadband Cable Infrastructure HYBRID FIBER WIRELESS Logical fit with cable infrastructure Responds to ad-hoc and organized competition Potential for higher data rate alternative to DOCSIS Synergy with streaming digital media

12 12 Hybrid Fiber Wireless Run fiber down streets (or to selected homes/businesses) to access points (1 mile apart) for universal coverage with one infrastructure) –Start with wireless data access (802.11b) –Extend range and migrate to: Voice (802.11e) Audio (music) Video Mobility Higher data rates (54 Mbps - 802.11a => 216 Mbps) –Virtual personal/office (remote workforce) environment

13 13 WLAN Evolution Start with wireless data access (802.11b) (hotspots) –Extend range and migrate to: Voice Audio (music) Video Mobility Higher data rates (54 Mbps - 802.11a and higher)

14 14 Technical Issues Voice/Music streaming/Video streaming (802.11e) Universal coverage (Internet roaming) Range Higher data rates Capacity/Interference Key constraint: Stay within existing standards/standard evolution (enhance performance within standards and drive standards evolution)

15 15 Internet Roaming Seamless handoffs between WLAN and WAN –high-performance when possible –ubiquity with reduced throughput Management/brokering of consolidated WLAN and WAN access Adaptive or performance-aware applications Nokia GPRS/802.11b PCMCIA card NTT DoCoMo WLAN/WCDMA trial Cellular Wireless Enterprise Home Public Internet Wireless LAN’s

16 16 Technical Issues Voice/Music streaming/Video streaming (802.11e) Universal coverage (Internet roaming) Range Higher data rates Capacity/Interference Key constraint: Stay within existing standards/standard evolution (enhance performance within standards and drive standards evolution)

17 17 Wireless System Enhancements 10 feet100 feet1 mile10 miles 100 kbps 1 Mbps 10 Mbps 100 Mbps 3G Wireless ~ 2GHz BlueTooth 2.4GHz 802.11a 5.5GHz Unlicensed 802.11b 2.4GHz Unlicensed Peak Data Rate Range 2 mph10 mph30 mph 60 mph $ 500,000 $ 1000 $ 100 $ 500 $ 100 $ 10 $/Cell $/Sub High performance/price High ubiquity and mobility Mobile Speed Enhanced UWB 3.1-10.6 GHz

18 18 Enhancements Smart Antennas (keeping within standards): –Range increase –Interference suppression –Capacity increase –Data rate increase using multiple transmit/receive antennas (MIMO) Radio resource management techniques (using cellular techniques in WLANs): –Dynamic packet assignment –Power control –Adaptive coding/modulation/smart antennas

19 19 Smart Antennas Smart Antennas significantly improve performance: Higher antenna gain with multipath mitigation (gain of M with M-fold diversity)  Range extension Interference suppression (suppress M-1 interferers)  Quality and capacity improvement With smart antennas at Tx/Rx  MIMO capacity increase(M-fold) SIGNAL INTERFERENCE BEAMFORMER WEIGHTS SIGNAL OUTPUT

20 In 1999, combining at base stations changed from MRC to MMSE for capacity increase Downlink Switched Beam Antenna INTERFERENCE SIGNAL OUTPUT BEAMFORMER WEIGHTS Uplink Adaptive Antenna SIGNAL OUTPUT SIGNAL INTERFERENCE BEAMFORMER BEAM SELECT Smart Antennas for Cellular Key enhancement technique to increase system capacity, extend coverage, and improve user experience in cellular (IS-136)

21 21 Multiple-Input Multiple-Output (MIMO) Radio With M transmit and M receive antennas, can provide M independent channels, to increase data rate M-fold with no increase in total transmit power (with sufficient multipath) – only an increase in DSP –Indoors – up to 150-fold increase in theory –Outdoors – 8-12-fold increase typical AT&T measurements show 4x data rate & capacity increase in all mobile & indoor/outdoor environments (4 Tx and 4 Rx antennas) –216 Mbps 802.11a (4X 54 Mbps) –1.5 Mbps EDGE –19 Mbps WCDMA

22 22 Rx MIMO Channel Testing W1W1 W2W2 W3W3 W4W4 LO Synchronous test sequences Rx Perform timing recovery and symbol synchronization Record 4x4 complex channel matrix Evaluate capacity and channel correlation LO Mobile Transmitters Test Bed Receivers with Rooftop Antennas Terminal Antennas on a Laptop Tx Rooftop Base Station Antennas 11.3 ft Prototype Dual Antenna Handset Mobile Transmitters

23 23 DIVERSITY TYPES Spatial: Separation – only ¼ wavelength needed at terminal Polarization: Dual polarization (doubles number of antennas in one location Pattern: Allows even closer than ¼ wavelength  4 or more antennas on a PCMCIA card  16 on a handset  Even more on a laptop

24 24 MIMO Antennas Base Station Antennas Laptop Prototype Antennas mounted on 60 foot tower on 5 story office building Dual-polarized slant 45  1900 MHz sector antennas and fixed multibeam antenna with 4 - 30  beams 4 patch antennas at 1900 MHz separated by 3 inches ( /2 wavelengths) Laptop prototype made of brass with adjustable PCB lid

25 25 Measured capacity distribution is close to the ideal for 4 transmit and 4 receive antennas MIMO Field Test Results

26 26 Smart Antennas for WLANs TDD operation (only need smart antenna at access point or terminal for performance improvement in both directions) Interference suppression  Improve system capacity and throughput –Supports aggressive frequency re-use for higher spectrum efficiency, robustness in the ISM band (microwave ovens, outdoor lights) Higher antenna gain  Extend range (outdoor coverage) Multipath diversity gain  Improve reliability MIMO (multiple antennas at AP and laptop)  Increase data rates AP Smart Antenna Interference Smart Antennas can significantly improve the performance of WLANs AP Smart Antenna

27 27 Smart Antennas Adaptive MIMO –Adapt among: antenna gain for range extension interference suppression for capacity (with frequency reuse) MIMO for data rate increase With 4 antennas at access point and terminal, in 802.11a have the potential to provide up to 216 Mbps in 20 MHz bandwidth within the standard In EDGE/GPRS, 4 antennas provide 4-fold data rate increase (to 1.5 Mbps in EDGE) In WCDMA, BLAST techniques proposed by Lucent, with 19 Mbps demonstrated In UWB, smart antennas at receiver provide range increase at data rates of 100’s Mbps

28 28 Radio Resource Management Use cellular radio resource management techniques in WLANs: Adaptive coding/modulation, dynamic packet assignment, power control Use software on controller PC for multiple access points to analyze data and control system Power control to permit cell ‘breathing’ (for traffic spikes) Dynamic AP channel assignment –Combination of radio resource management and smart antennas yields greater gains than sum of gains

29 29 Cell Breathing in WLAN Systems Measure traffic load for each access point Shrink overloaded cell by reducing RF power Expand others to cover abandoned areas AP

30 30 Adaptive Channel Assignment 31 2 2 3 23 1 1 31 2 2 2 33 3 2 Initial Assignment After one iteration Assign channels to maximize capacity as traffic load changes Cochannel interference High traffic load

31 31 Conclusions We are evolving toward our goal of universal high-speed wireless access, but technical challenges remain These challenges can be overcome by the use of: –Smart antennas to reduce interference, extend range, increase data rate, and improve quality, without standards changes –Radio resource management techniques, in combination with smart antennas, and multiband/multimode devices

Download ppt "1 Fourth Generation Wireless Systems Jack H. Winters May 6, 2003"

Similar presentations

Slide 1Thursday, June 30, 2005 1 12/05/03 EMERGING TECHNOLOGIES IN WIRELESS Jack H. Winters Chief Scientist, Motia

Slide 1Thursday, June 30, /05/03 EMERGING TECHNOLOGIES IN WIRELESS Jack H. Winters Chief Scientist, Motia
A Wireless Local Area Network (WLAN) is a network that interconnects devices using radio waves. Wireless networking technologies allow devices to communicate.

A Wireless Local Area Network (WLAN) is a network that interconnects devices using radio waves. Wireless networking technologies allow devices to communicate.
How to Set Up, Secure and Manage A Network

How to Set Up, Secure and Manage A Network
Performance Analysis Lab,

Performance Analysis Lab,
The Mobile MIMO Channel and Its Measurements

The Mobile MIMO Channel and Its Measurements
1 Smart Antennas for Mobile Wireless Systems Jack H. Winters May 6, 2003

1 Smart Antennas for Mobile Wireless Systems Jack H. Winters May 6, 2003
CS 350 Chapter-12 Wireless Technologies. Wireless Agencies & Standards AgencyPurposeWeb Site Institute of Electrical and Electronics Engineers (IEEE)

CS 350 Chapter-12 Wireless Technologies. Wireless Agencies & Standards AgencyPurposeWeb Site Institute of Electrical and Electronics Engineers (IEEE)
Fourth Generation Cellular Systems and Smart Antennas Jack H. Winters April 9, 2002

Fourth Generation Cellular Systems and Smart Antennas Jack H. Winters April 9, 2002
Wireless Networks and Spread Spectrum Technologies.

Wireless Networks and Spread Spectrum Technologies.
Wireless Fundamentals Chapter 6 Introducing Wireless Regulation Bodies, Standards, and Certifications.

Wireless Fundamentals Chapter 6 Introducing Wireless Regulation Bodies, Standards, and Certifications.
Wednessday, October 8, 2003Slide 1 VTC2003 Fall Integration of Cellular Systems with WLAN and Internet Jack Winters Chief Scientist, Motia, Inc. Email:

Wednessday, October 8, 2003Slide 1 VTC2003 Fall Integration of Cellular Systems with WLAN and Internet Jack Winters Chief Scientist, Motia, Inc.
UMTS / 3G Wireless ENGR 475 – Telecommunications November 7, 2006 Harding University Jonathan White.

UMTS / 3G Wireless ENGR 475 – Telecommunications November 7, 2006 Harding University Jonathan White.
IMT 2000, CDMA 2000 1 x And Future Trends.  IMT 2000 objective.  CDMA 2000 1x.  IMT 2000 Technological Options Brief Outline  Migration Paths.

IMT 2000, CDMA x And Future Trends.  IMT 2000 objective.  CDMA x.  IMT 2000 Technological Options Brief Outline  Migration Paths.
Wireless networking technology By Abbas Izadpanah January 2007.

Wireless networking technology By Abbas Izadpanah January 2007.
© 2009 Pearson Education Inc., Upper Saddle River, NJ. All rights reserved.1 Computer Networks and Internets, 5e Chapter 14 Wireless Networking Technologies.

© 2009 Pearson Education Inc., Upper Saddle River, NJ. All rights reserved.1 Computer Networks and Internets, 5e Chapter 14 Wireless Networking Technologies.
Wireless Network Taxonomy Wireless communication includes a wide range of network types and sizes. Government regulations that make specific ranges of.

Wireless Network Taxonomy Wireless communication includes a wide range of network types and sizes. Government regulations that make specific ranges of.
1 SMART ANTENNAS FOR THIRD GENERATION TDMA (EDGE) Jack H. Winters AT&T Labs - Research Red Bank, NJ 07701-7033 October 3, 2000.

1 SMART ANTENNAS FOR THIRD GENERATION TDMA (EDGE) Jack H. Winters AT&T Labs - Research Red Bank, NJ October 3, 2000.
Overview.  UMTS (Universal Mobile Telecommunication System) the third generation mobile communication systems.

Overview.  UMTS (Universal Mobile Telecommunication System) the third generation mobile communication systems.
By Abdullah Al-Dossary Ahmad Al-Suhaibani

By Abdullah Al-Dossary Ahmad Al-Suhaibani
1 SMART ANTENNA TECHNIQUES AND THEIR APPLICATION TO WIRELESS AD HOC NETWORKS JACK H. WINTERS 2006 2007/11/13 碩一 謝旻欣.

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

Similar presentations

Ads by Google