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Workshop on the Communication Core Technology Educational Culture Center in Seoul Feb. 14, 2006

Core Technologies of the next generation wireless systems for the high rate mobile data access services. Workshop on the Communication Core Technology Educational Culture Center in Seoul Feb. 14, 2006 By - Bekay (Byung Keun) Lim, Ph.D. ArrayComm LLC. Agenda.

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Workshop on the Communication Core Technology Educational Culture Center in Seoul Feb. 14, 2006

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  1. Core Technologies of the next generation wireless systems for the high rate mobile data access services Workshop on the Communication Core Technology Educational Culture Center in Seoul Feb. 14, 2006 By - Bekay (Byung Keun) Lim, Ph.D. ArrayComm LLC

  2. Agenda 1. Telecommunication Services Status and Trend 2. Mobile Wireless Technology Evolution 3. Experience of the high rate AMC based technologies 4. The constraints of public mobile wireless technology evolution 5. AAS and SDMA for the high rate mobile access 6. Experience of the AAS/SDMA technologies 7. Conclusion

  3. 1. Telecommunication Services Status and Trend • Telecommunication Services Status and Trend • Voice to Data & Multimedia • Wireline to Wireless • Higher Data Speed • Voice Centric network to Data Centric network • NGN, IPv6, Ubiquitous, 3.5G, 4G, • Core Service to Additional Supplementary Services, • Converged services • Converged market - Public Operator driven Market , Enterprise, and SOHO Market. • Saturated and slow growth. • New Revenue Source are required for fast growth • Shared equipment to Personalized

  4. Voice to Data & Multimedia, Wireline to Wireless, Higher Speed Information Rate LAN/ WLAN xDSL, Cable modem Data Broadband Multimedia Services 2Mbps Mobile Wireless Broadband Multimedia Services 1Mbps Multimedia Services 144Kbps 64Kbps Dial up data Voice Services Mobile Wireless Voice PSTN Voice Mobility Fixed Fixed Wireless pedestrian Vehicular

  5. Next Generation Network Legacy Separate Network Wireless PSTN DATA services Services Softswitch Switching Networks QoS Packet Network Network Wireless PSTN 패킷망 Mobile Access Enterprise Access Home Access Access Transport • Voice Centric network to Data Centric network, NGN, IPv6, Ubiquitous, 3.5G, 4G,

  6. Core Service to Additional Supplementary Services, • PSTN – IN services, 080, Ring Sound, CID, etc. • PCS, Cellular – SMS, Multimedia, Data • Converged services, Converged market - Public Operator driven Market , Enterprise, and SOHO Market. • DMB over the Handset • Home Network • Saturated and slow growth. New Revenue Source are required for further growth. Subscribers as of Dec.30, 2005 • PSTN – No growth, (decrease) 22.92Mil • PCS, Cellular – 38.34Milion • High Speed Internet – 12.14Mil

  7. Shared telecommunication equipment to Personalized • PSTN provides a telecommunication services to every home and Office (PSTN Phone)  PCS, Cellular provide a personal services (Handset) • Broadband Internet Access Services, xDSL, Cable, Metro Ethernet provide a High Speed Internet Access services to Home and Office (Desk Top PC)  Wireless Broadband Access provides a personal services ( mobile PC)

  8. 2. Mobile Wireless Technology Evolution • 2. Mobile Wireless Technology Evolution • Voice Centric Network technology • 3GPP2, IS-95A/B, cdma2000 1x/Ev-Do, 1xEV-Do rev A , • 3GPP, WCDMA, CDMA/HSDPA, HSUPA, LTE, TD-SCDMA, TD-CDMA, • GSM, GPRS, EDGE, • Data Centric network technology • IEEE802.x, Hiperxxx • WiFi, WiMAX, WiBro, Mobile WiMAX • HC-SDMA,

  9. From Voice Centric technology to Data Centric technology • Circuit switch Cellular/PCS to All IP Network • Narrow Channel Bandwidth to Broad Channel Bandwidth • 1.25Mhz -> 5Mhz –> 10Mhz -> 20Mhz • To have a broadband access channel widen the channel bandwidth • Uniform Rate service coverage to variable rate service coverage by AMC • Symbol modulation for basic voice channel covers full service areas • Higher order modulation 16QAM, 64QAM, 256QAM provides a portion of coverage areas depend on the SNR • To achieve the high peak data rate as far as possible

  10. SNR 25 20 15 10 5 0 -5 Distance 3. Experience of the high rate AMC based technologies • 3. Experience of the high rate AMC technologies • Easy approach to get a higher peak data rate • Non-uniform service coverage N 25 20 15 10 5 0 dB W E S

  11. Lower Cell Edge data rate deteriorate the service quality • Peak Data rate mislead the understanding for the End user even Operators • Cause a complain by the poor service quality < CDMA 2000 1x, WCDMA, GSM > < 1xEV-DO, EV-DV, HSDPA, WiBro>

  12. 4. The constraints of public mobile wireless technology evolution • 4. The constraints of public mobile wireless technology evolution • Public wireless service system criterion • Guarantee the quality of Services • Public Wireless Services system is different from private wireless system • ISM band WIFI vs. Licensed Spectrum Radio System • Cell Planning and Quality • HSDPA, Mobile WiMAX, WiBro, LTE, 3.5G, 4G, approach is to get a broadband channel bandwidth, higher rate AMC technique • Peak rate driven, OFDMA, MIMO, Higher Radio Frequency Band 2.5GHz, 5GHz, etc. • High RF band is required for Broadband Channel BW • Propagation loss, uniform service quality, Backhaul Cost limit the massive deployment

  13. Lesson of Commercial experience of the MBWA system, Cellular, Netspot, • Expensive, Poor quality (non-uniform), Small coverage • Non-popular services • Low cost , uniform service quality, higher data rate, higher network capacity are required. • For the popular services • Voice Centric Approach could not break the paradigm of cost, quality constraint • User expect similar amount of payment for the data access • Data services requires several tenth times data capacity compare to Voice services capacity • Data centric application network • Can ensure the Capex and Opex for the MBWA services

  14. Data centric telecommunication MBWA network for what? • Providing services by a cheap cost • Providing guaranteed service quality • Providing uniform service quality • Providing commercial new subscriber (Mobile PC?) • Can not build a MBWA network by a legacy cellular concept • New Paradigm is required for MBWA network • Limit some service features (mobility) • Smaller cell (Pico Cell for high capacity/m²) • Zone based service coverage ( reduce the Capex and Opex) • Higher Capacity / footprint ( MBWA requirement) • AAS for the Cell Edge Data Speed and Quality (Uniformity )

  15. Throughput/cell (Mbps) 802.11b (83 MHz) Smart Antenna Benefit 2/2.5G (10 MHz) range (km) Interference Limited Noise Limited Technical Interpretation • Gain vs. noise, fading, ... expands envelope to right • Interference mitigation (+ gain) expands it upwards Economic Interpretation • Coverage improvements reduce CapEx, OpEx (esp. backhaul, sites) • Capacity improvements reduce delivery cost, spectrum requirements 5. AAS and SDMA for the high rate mobile access • 5. AAS and SDMA for the high rate mobile access • Array Antenna based Adaptive Antenna solution provides wider coverage and higher capacity

  16. User 2, s2(t)ejt User 1, s1(t)ejt as1(t)-bs2(t) as1(t)+bs2(t) as1(t) as1(t) +1 -1 +1 +1 2as1(t) 2bs2(t) • Users’ signals arrive at array with different space-time channels • Processing provides gain and interference mitigation • Exploiting Channel State Information

  17. passive mitigation active mitigation coherent gain • Gain, Active & Passive Mitigation co-channel user user omni/sector reference

  18. antenna antenna … Transceiver Transceiver … Channelizer (TDMA, FDMA, CDMA, OFDMA) Channelizer (TDMA, FDMA, CDMA, OFDMA) Spatial and Temporal Processing baseband signals/user data • Protocol Independence • Applicable to any access & modulation methods • Processing in parallel on each channel resource

  19. SISO • Single Input, Single Output MISO • Multiple Input, Single Output SIMO • Single Input, Multiple Output MIMO • Multiple Input, Multiple Output SDMA • SISO, MISO, SIMO, MIMO, …

  20. Antenna Arrays • Wide variety of geometries and element types • arrangements of off-the-shelf single elements • custom arrays • Array size • vertical extent determined by element gain/pattern as usual • horizontal extent, as small as 3-5 lambda • regular structures with 0.5 lambda subarrays desirable for FDD • 2 GHz: array of eight 10 dBi elements is 0.5 x 0.75 m • small! • conformal arrays for aesthetics

  21. Common Radio System Logical Layouts for Advanced Antenna Processing Base Station Calibration Module Resource scheduling and calibration control AntennaCo-Processing ... RF PHY MAC ... Client Device Frame and Control RF AntennaProcessing PHY MAC Antenna processing software modules from ArrayComm Calibration subsystem

  22. PHS HC-SDMA • HC-SDMA system performance 6.7x capacity improvement through 3 software releases in microcellular application, with over 275,000 installations in service in Japan and China Industry’s most sophisticated spatial processing at work in multiple large-scale deployments of true mobile broadband standard GSM 12–30 dB link budget and2–6x capacity improvement in challenging urban FDD application, large US operator trial ongoing

  23. ~30% ~10dB Out of Service • WiBro/Mobile WiMAX performance -Downlink SINR distribution, reuse 3

  24. WiBro/Mobile WiMAX performance - Downlink SINR distribution, reuse 1

  25. Downlink Average Data Rate [kbps] Downlink Uplink UT#1 1,023 328 UT#2 964 329 UT#3 1,027 325 UT#4 892 331 Uplink UT#5 1,026 332 UT#7 982 328 UT#8 1,027 328 UT#6 1,025 328 Total 7,966 2,629 • HC-SDMA , Base Case: 8 Terminals, 8 Carriers

  26. Antenna Configurations — Stub & Patch • Pair 1: co-pol closely spaced • Pair 2: x-pol • Pair 3: co-pol distant

  27. Wavelength at 2GHz is about 15 cm • Typical handset dimension is 10 cm x 5 cm • A 2-antenna solution with 0.3 – 0.5λ antenna separation can be easily accommodated • Due to the large angle spread of the received signals, a 0.3 – 0.5λ antenna separation will yield good performances • ArrayComm has studied handset antenna configurations in detail

  28. Measurement Results – Patch Antennas

  29. Measurement Results – Stub Antennas

  30. Network Simulation – Ec/Ei in the WCDMA Handset • 3GPP TR 29.942 • 3 sectors/site • Max BS power: 20 Watts • Pilot TX power: 1 Watts • Cell radius: 1500 m • Uncorrelated Shadowing sigma=8 dB

  31. Ec/Ei After Cancelling Most Dominant Interferer • 3GPP TR 29.942 • 3 sectors/site • Max BS power: 20 Watts • Pilot TX power: 1 Watts • Cell radius: 1500 m • Uncorrelated Shadowing sigma=8 dB

  32. Ec/Ei After Cancelling Two Dominant Interferers • 3GPP TR 29.942 • 3 sectors/site • Max BS power: 20 Watts • Pilot TX power: 1 Watts • Cell radius: 1500 m • Uncorrelated Shadowing sigma=8 dB

  33. 6. Experience of the AAS/SDMA technologies • 6. Experience of the AAS/SDMA technologies • Mitigate the cell edge interference and provide uniform QoS • Increase the network average throughput • Increase the network total capacity by SDMA • Easy to implement on top of existing technologies • Optimum solution for data centric application system • MIMO Now • BS AAS (Multiple RX/TX) • Handset AAS ( 2 Rx)

  34. 7. Conclusion • 7. Conclusion • Next generation licensed MBWA market • The last domain of telecommunication services • New ocean of Telecommunication services market • When the subscriber come with a new client devices • New Device will consumes a lot of data traffic compare to Cellular packet usage on the handset • Popularity will be assured by low cost and uniform quality • Core technologies for the new public licensed MBWA market • AAS uniquely assures the uniform services quality • SDMA is the last technique to improve the capacity in any technologies even on top of MIMO

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