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Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANS)

Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANS). Submission Title: [General Atomics Call For Proposals Presentation] Date Submitted: [3 March 2003; 7 March 2003- rev1]

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Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANS)

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  1. Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANS) Submission Title: [General Atomics Call For Proposals Presentation] Date Submitted: [3 March 2003; 7 March 2003- rev1] Source: Naiel Askar, General Atomics- Photonics Division, Advanced Wireless Group, 10240 Flanders Ct, San Diego, CA 92121-2901, Voice +1 (858) 457-8700], Fax [+1 (858) 457-8740], E-mail [naiel.askar@ga.com} Re: [802.15.3a Call For Proposal, Spectral Keying™ UWB Multi-Band Technology] Abstract: [This presentation outlines General Atomics’ PHY proposal to the IEEE 802.15.3a Task Group] Purpose: [To communicate a proposal for consideration by the standards committee] Notice:This document has been prepared to assist the IEEE P802.15. It is offered as a basis for discussion and is not binding on the contributing individual or organization. The material in this document is subject to change in form and content after further study. The contributor reserves the right to add, amend or withdraw material contained herein. Release: The contributor acknowledges and accepts that this contribution becomes the property of IEEE and may be made publicly available by P802.15.

  2. Overview of General Atomics PHY Proposal to IEEE 802.15.3a Presented by: Naiel Askar www.ga.com/uwb

  3. Outline of Presentation • Description of Spectral KeyingTM (SK) • SK parameters and operating frequencies • Channelization scheme • SK performance • Implementation issues • Interference and co-existence • Preamble definition • Self-evaluation • Conclusions

  4. Summary of Proposal • Scalable data rates from 15-1300 Mbps • Spectral KeyingTM modulation* • Compliant with FCC 02-48, UWB Report & Order • Multi-Band system, scalable from 4-12 bands, occupying 2 - 6 GHz total bandwidth • Supports at least 4 co-located piconets * Spectral KeyingTM is a registered trademark of General Atomics

  5. Key Features • A new modulation scheme which has been optimized for UWB systems • Low symbol rate with guard time between symbols • Enhanced multipath immunity by limiting channel-induced inter symbol interference (ISI) • Low duty cycle allows power saving features • Minimizes collisions between colocated piconets • Set of allowable symbols increases with the factorial of the number of frequencies • Bit rate scalable with power consumption, cost and occupied frequency • Enhanced co-existence with IEEE 802.11a

  6. UWB Multi-Band Technology • UWB spectrum divided into multiple bands • One symbol will be composed of subpulses from multiple bands • Excellent performance in multipath • Scalability • Bit rate • Power consumption • Range • Complexity / Cost • Coexistence • IEEE 802.11a • Regulatory • Compliant with US FCC • Flexibility for world-wide regulatory action

  7. Spectral Keying™ Modulation • Transmit 2 or more subpulses using different bands • Order of bands defines symbol UWB Symbol in Time Voltage Time (ns)

  8. SK Definitions • Data encoded with • Sequence of bands in the pulse • Phase information on the subpulses

  9. Spectral Keying™ General Case • An SK symbol X, where can be defined in terms of the location in a MxT matrix, B and P • where • 0 means no transmission • ±1 allows Binary Phase Shift Keying (BPSK) • ± i allows Quadrature Phase Shift Keying (QPSK) • M is # of frequency bands • T is # of time slots • B is # of non-zero entries • P is # of polarity bits • N is # of available bits where For Optimum BER Performance in SK use M=T=B

  10. SK Rate Scalability Examples 2 bands no polarity 5 bands, with BPSK 8 bands with QPSK Sequence bits/sym. 1~6.5~15 Phase bits /sym. 0516 Total bits/sym. 111.531 For sequence bits, the set of allowable symbols increases with the factorial of the number of bands

  11. Data Rate Examples

  12. SK Parameters For Base Rates

  13. Transmit Sub-pulse Shaping • A rectangular 2 ns pulse is low pass filtered (2nd order) to suppress out of band emissions • 3 dB bandwidth 440 MHz • 10 dB BW 700 MHz

  14. Frequency Plan for 110/200 Mbps • Define 20 bands centered 3.4-7.2 GHz • Bands are spaced 200 MHz apart • Piconets will have different bands • 4 piconets will have 5 unique bands • Bands in each piconet will have 800 MHz separation • Other piconets will share some frequencies, less separation Piconet 1 Piconet 2 Piconet 3 Piconet 4

  15. 4 Piconets at 110/200 Mbps • Systems will be able to cancel or modify the frequency of one band to avoid interference • Reducing receive filter bandwidth can reduce interference from adjacent piconets

  16. Piconet Isolation • Performance improved by 3 factors • Frequency separation isolation • Low symbol rate reduces collision rate between piconets; random or passively synchronized • Coding gain of SK and channel coding

  17. Passive Synchronization for Channels • Time interleaving may be used by channels 3, 4 to minimize interference • Passive scanning of bands will identify best time slots • Improved performance with lower symbol rate • Has reasonable margin for • channel delay spread • timing uncertainty due to near-far problem • Clock synchronization can be avoided by repeated scanning

  18. Performance Bounds for SK • Case when M = T = B, P = 1 • The Euclidian Distance (ED) when a frequency is in error has a value of 2 • Similar to antipodal modulation BPSK • SK will require lower EbNo for the same performance compared to BPSK because of the higher order modulation • Where • M is # of frequencies • T is # of time slots • B is # of non-zero entries • P is # of polarity bits • Ps is the probability of subpulse error • Es is the energy per subpulse • No is the noise spectral density • EbNo is the ratio of bit energy to noise density

  19. SK Error Rate Performance: Predictable Analysis vs. Simulation Results TM

  20. BER Performance of 5 Band SK in AWGN Improvement Over BPSK TM

  21. Channel Capacity in AWGN (Coherent Receiver) • M is # of frequency bands • T is # of time slots • Q is # of non-zero entries • P is # of polarity bits Operating Point

  22. Channel Capacity in AWGN (Non coherent receiver) • M is # of frequency bands • T is # of time slots • Q is # of non-zero entries • P is # of polarity bits Operating Point

  23. Error Correction Coding Approach • Coding algorithm: Turbo Convolutional Code (TCC) • Best performance • Manageable cost and power consumption • Best in flexibility in selection of code rate, on the fly code change • Already selected for 3GPP, DVB, etc. • Cost: • Estimated power consumption = 35 mW. • Estimated chip area = 3 mm2 in 0.13 mm CMOS • Parameters • Overall code rate 4/5 • Memory size (4k bits), larger packets will be concatenated • Number of iterations = 4, 3 bits of quantization • EbNo = 3.6 dB for BER = 1e-5 • Turbo code simulation (DLL) and performance supplied by iCODING Technologies

  24. Turbo Code Scalability • Range of Performance • 1 iteration matches performance of K=7 convolutional code • 1.5 or more iterations exceeds performance of K=7 convolutional code • 3 or more iterations substantial performance gains (2-4 dB) • Code rate is adjustable for longer range mode(s) • Power consumption can be reduced by early stopping • Larger frame size (up to 8K) can further increase performance • Extreme low cost, low power & low latency option • K=4 constituent code can be used as stand alone FEC option. • Uses same encoder components as full Turbo Code • Area less than 0.25 mm^2 in 0.18u process • 1/8th the complexity of a K=7 CC with upwards scalability built in • Very high coding gains in frequency selective fading channel • 2-4 dB gain in AWGN can translate to 4-7 dB gain in frequency selective fading channels over non-iterative techniques.

  25. Bit to Symbol Mapping • Maximum # of frequency bits in SK symbol (M=T=B=5, P=0) = log2 120 = 6.9 (excluding polarity bits) • Simple mapping will produce 6.5 bits,13 bits from 2 symbols • The 3rd frequency of 2 symbols are combined to produce 3 bits • Reserved symbols for preambles are available

  26. SK Simulation in AWGN with Channel Decoder 8% PER 1e-5 BER

  27. Link Budget

  28. Transceiver Block Diagram

  29. Example of a Spectral Keying™ Transmitter

  30. Example of a 5-Band SK Receiver

  31. Unit Manufacturing Complexity* • Preliminary area estimates • ~3 mm2 for RF • ~7.0 mm2 for digital • The target is to have a one chip solution • First implementation may have separate RF and digital chips • The receiver has one signal chain per band (5 total) • Allows implementing Rake receiver without extra hardware • Having multiple receive chains increases area ~0.5 mm, but has little impact on overall complexity • Allows tracking signal peak on each band individually giving improved performance • Low risk * Estimates based on collaboration with Philips Semiconductors

  32. Power Consumption* • Power consumption will be dominated by • Oscillators: trade performance for low current • ADCs: limit number of bits to 3 • Front end receiver: dominated by NF/11a interference requirements • Minimize by designing with adaptive linearity/power tradeoff • Low symbol rate gives low duty cycle allowing power saving techniques to be applied * Estimates based on collaboration with Philips Semiconductors

  33. General Atomics Spectral Keying™ Transceiver Module TRDA / Taiyo Yuden Antenna Size10 x 8 mm Manufacturability & Technical Feasibility • Use of proven technology and processes • No high risk components or technology • Immune from distortion or ringing from antennas or filters owing to relatively long subpulse time • Relaxed antenna characteristics • Modules already tested in the lab

  34. Experimental Results of SK Validate Simulations

  35. Scalability • Power consumption • Scalable from 127 to 425 mW based on rate (55-200Mbps) • Data rate • Scalable from 23 – 1300 Mbps • Range: • Scalable with more rakes, more coding, lower symbol rate • Complexity • Lower complexity, lower performance system possible

  36. Interference from 802.11a • Flexibility in choice of bands is key to performance • Bands centered at 5.0, 5.2, 5.4 GHz will be avoided • Table below based on selection criteria parameters • Bands centered on 4.8, 5.6 will be marginal at 1m • Bands centered on 4.6, 5.8 will be OK at 1m separation between interferer and victim, marginal at 0.3m separation • All other bands are OK

  37. 802.11a Co-existence • Flexibility in removing bands from or moving to adjacent bands improves co-existence • Interference from UWB is much lower than an 802.11a device at same distance • SIR levels are based on 802.11a minimum sensitivity of -82 dBm for 6 Mbps rate

  38. PHY Preamble • Utilize the same preamble as the 15.3 PHY for each band separately • Composed of 16 Constant Zero Autocorrelation (CAZAC) symbols • The pattern is repeated 10 times • Last symbol will have inverted polarity • Total 160 symbols lasting 12.3 µsec. • Detection miss probability and false alarm rate < 10-3 in multipath are achievable • Detection is declared when a threshold is exceeded in 2 out of the 5 bands

  39. General Solution Criteria (1/2)

  40. General Solution Criteria (2/2)

  41. Conclusions • A UWB system based on Spectral KeyingTM will meet or exceed all selection criteria • Spectral KeyingTM is a Multi-Band scheme • Good multipath performance • Flexibility in assigning bands for regulatory and interference avoidance • Unique high order modulation allows low symbol rate with long guard time between symbols • Minimizes ISI - At maximum data rate no equalizer needed • Off period is 75% at 13 MHz symbol rate - Allows power conservation • Efficient spectrum utilization allows frequency based channels • Provides scalability for power consumption, rate, range and complexity • Technology proven with demonstrations • Letter of assurance for essential patents submitted to the IEEE 802.15.3a leadership • The May 2003 presentation will focus on analysis and simulation

  42. 802.15.3a Early Merge Work General Atomics will be cooperating with: • Discrete Time • Focus Enhancements • Intel • Philips • Samsung • Time Domain • Wisair • Objectives: • “Best” Technical Solution • ONE Solution • Excellent Business Terms • Fast Time To Market We encourage participation by any party who can help us reach our goals.

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