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Performance of Time Delay Estimation and Range-Based Localization in Wireless Channels

Performance of Time Delay Estimation and Range-Based Localization in Wireless Channels. Ning Liu. Wireless Information Technology Lab Department of Electrical Engineering University of California, Riverside September 3, 2010. Outline. Motivation Challenges in m ultipath c hannels

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Performance of Time Delay Estimation and Range-Based Localization in Wireless Channels

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  1. Performance of Time Delay Estimation and Range-Based Localizationin Wireless Channels Ning Liu Wireless Information Technology Lab Department of Electrical Engineering University of California, Riverside September 3, 2010

  2. Outline • Motivation • Challenges in multipath channels • Part I: Ziv-Zakai bounds for TDE in unknown random multipath channels • Pulsed signal • Frequency hopping waveforms • Part II: ToA localization performance in multipath channels • Deterministic and random bias • WLS and ML estimators • Conclusions

  3. Transceiver Localization in Wireless Systems • GPS/GNSS: • Sky infrastructure-based • At least 4 accurate references always available • Cellular/WLAN: • Terrestrial infrastructure-based • Reference available in coverage • Ad-Hoc/Sensor networks: Infrastructure-less • Reference nodes are sparse • Possibly no direct radio link to references • Cooperative localization applicable

  4. Two-Stage Localization Schemes

  5. Time Delay Estimation • Challenge on TDE in multipath channels • t0: generally random; Channel known/unknown to receivers. • LOS path detection(Patwari, 2005; Peterson, 1998; Lee, 2002) • NLOS identification and mitigation (Chen 1999; Tuchler, 2006) LOS NLOS

  6. Motivation on Developing Realistic TDE Bounds Need better ranging algorithms in practice Practical Algorithms Still a big gap between practical algorithms and fundamental bounds Fundamental Bounds and MLE Need tighter bounds in practical scenarios Time delay estimation with UWB signal over deterministic multipath channels. (Guvenc et al, 2008)

  7. Motivation: Two fundamental topics • Performance bounds for TDE • Tight bounds to predict performance limits • ZZB is tighter than CRB in low-to-mid SNR region • Bounds for practical scenario: unknown multipath channel • CRB for deterministic channels (Yau 1992, Saarnisaari 1996) • ZZB for AWGN and flat-fading channel (Sadler 2007, Kozick 2006) • Average ZZB for known multipath channel (Xu 2007) • Efficient evaluation method for ZZB • Performance of ToA localization with biased ranging • Error analysis for typical estimators • ML for Deterministic bias (Weiss 2008) • CRB of ToA localization • Uniformly distributed random bias (Jourdan 2008)

  8. Part I Ziv-Zakai Performance Bounds for TDE in Unknown Random Multipath Channels • Signal and channel models • ZZB development for pulsed signal • Evaluation of ZZB by MGF approach • Efficiently compute MGF with a compact form • Asymptotic analysis at low and high SNR regimes • ECRB, MAP/GML estimators. • ZZB for frequency hopping: frequency diversity • Numerical examples

  9. Review of ZZB: A Hypothesis Testing Approach • Two possible time delays for • Time delay estimate by an arbitrary estimator • Minimum error probability by an optimum detector • ZZB (Ziv, Zakai, ’69, ’75) • Question: How to find in case of interest? : estimation error by an arbitrary estimator

  10. Pulsed Signal and Channel Models • Transmitted pulse • Multipath channel • Received signal

  11. Distributions of Received Signal • Replace by for ZZB development: • pdf conditioned on one channel realization: • Unconditional pdf by averaging over channel: : Gaussian vector, correlation at the receiver W, h: depend on signal autocorrelation and channel statistics

  12. Log-likelihood Ratio Test • LLR to decide on H0 and H1 • Find pdf of LLR: the MGF approach pdf of r (Gaussian) MGF of (Quadratic Gaussian) pdf of • and ZZB conditioned on actual delay FT

  13. Efficiently Computing MGF • MGF of LLR: Direct Form conditioned on actual delay depend on LLR’s statistics, channel statistics, signal correlation. • MGF of LLR: Compact Form • : linear transform of • Each term is MGF of Chi-square variable • No matrix inverse and determinant. Only decomposition and scalar multiplication needed.

  14. Asymptotic Analysis • Low SNR regime • High SNR regime

  15. Numerical Result: Typical ZZB Behavior Typical ZZB behavior for TDE. A prior distribution T=[0,30]. SRRC pulse with roll-off factor =0, pulse width Tp=2; channel taps L=5 with spacing Tt=1, Ricianfading with exponential PDP.

  16. ECRB and MAP • ECRB: Expected conditional CRB • MAP and GML estimators (Win & Scholtz 2002)

  17. Numerical Result: Compare ZZB, CRB, Estimators ZZB compared to ECRB, MAP and GMLE. A prior distribution T=[0,30]. SRRC pulse with roll-off factor =0, pulse width Tp=2; channel taps L=5 with spacing Tt=1, Ricianfading with exponential PDP.

  18. Case of Frequency Hopping Transmission • Transmitted waveform • Multipath channel • Received signal

  19. Closed-Forms under Independent Flat-Fading • Rician fading depend on channel statistics and signal correlation. • Rayleigh fading is a function of SNR, channel statistics and signal correlation. • Applicable for pulsed signal with N=1

  20. Numerical Results - Frequency Diversity N=1, U=1 N=2, U=2 N>2, U=3 ZZB for FH shows frequency diversity gain. N = 1, 2, 4, 8 and 16. Number of symbols per hop M=80/N. Independent flat-fading Rayleigh channels. A prior distribution T=[0,30]. FH waveforms formed by SRRC pulses.

  21. Performance Summary on the ZZBs • ZZB: Bayesian MSE bound for random parameter, for unbiased or biased estimator, and tighter than CRB at low to mid SNRs. • ZZB for unknown random multipath channels: • Both LOS and NLOS channels • Rayleigh / Ricean • Different power delay profiles (PDPs) • Different tap correlation profiles (TCPs) • Known arbitrary finite duration pulse or frequency hopping waveforms.

  22. Part II ToA Localization Performance Analysis With Biased Range/Time-Delay Measurements in Multipath Channels • Modeling for biased time-delay measurement • Unknown deterministic • Random bias: convolved distributions • CRB of ToA localization with random biased ranging • WLS estimator error analysis • MLE error analysis and discussions on an extreme case • Numerical examples

  23. Assumptions on the Bias in Time Delay Estimation • Bias is known • Directly subtracted from time delay measurement • Bias is unknown deterministic, embedded in measurement error • WLS estimator • Bias is unknown deterministic, jointly estimated with unknown location • Identical for all measurements: Weiss & Picard, 2008 • Bias is random, following certain distributions • CRB for uniform distribution: Jourdan, Dardari & Win, 2008

  24. Model • Biased range measurement Non-negative bias White Gaussian noise • Random bias following exponential distribution • pdf • Convolved distribution

  25. CRB • Joint distribution • Fisher information matrix (FIM) • CRB

  26. Weighted Least-Square (WLS) • Estimator Constraints: • Error Analysis

  27. Maximum-Likelihood (MLE) • General Constraints: • Case of exponential distribution

  28. Error Analysis for MLE • Estimation MSE and bias • Extreme case: for exponential bias pdf -> Gaussian: MLE ->WLS:

  29. Numerical Results: Typical Localization by biased range measurement with non-uniform circular array of 10 references. Two groups of 5 sensors placed at 0 and 90 degrees, respectively. The exponential distributed bias and Gaussian noise at each sensor are assumed i.i.d.

  30. Numerical Results: Non-i.i.d Bias WLS Group 3 MLE Non-uniform circular array of 10 references. The case of non-iid measurement bias. The standard deviation of the exponential bias at five sensor groups (2 sensors per group) keep the constant ratio of 1:2:4:2:0.5, starting from the sensor at 0 degree.

  31. Numerical Results: Scatter Plots WLS MLE Scatter plots with uniform and three non-uniform circular arrays. The exponential distributed bias and Gaussian noise at each sensor are assumed i.i.d.

  32. Conclusions and Contributions • Developed Bayesian MSE bounds by Ziv-Zakaiapproach for random time delay estimation in unknown random multipath channels. • Valid for both pulsed signal and frequency hopping waveforms. • valid for both wideband and narrow band channels, both LOS and NLOS channels, different power delay profiles (PDP), and different channel tap correlation profiles (TCP). • The ZZBs represent more realistic and tighter performance limits, and provide good performance prediction for the MAP estimation. • The ZZB for FH waveforms reveals achievable performance with frequency diversity in wideband frequency-selective fading channels. • A MGF approach is proposed to compute the pdf of the LLR. • The compact form of MGF is developed, which greatly lowers the computation complexity, and is very efficient for evaluating ZZBs. • Closed-form expressions of the ZZB are developed for special cases of multipath channels: independent Rician/Rayleigh flat-fading channels.

  33. Conclusions and Contributions of Thesis • Asymptotic analysis on the ZZBs at low and high SNR regimes are performed.The results are useful for studying ZZB SNR thresholds behavior. At low SNR a closed-form expression is obtained. • ECRB, MAP, and GML estimatorsfor TDE in multipath channels are developed for comparative study with the ZZBs. • The 3dB gap between ZZB and MAP at low SNR is accounted for by studying the inequality approximations during ZZB development. • Developed random bias models and the convolved distributions are developed for ToA localization performance analysis. • Derived the CRBfor ToA localization with random biased range measurements for several distribution cases. • Error analysis for WLS and ML location estimators: • Analytical estimation bias and MSE depend on bias and noise statistics, reference array geometry and estimator type. • The ML estimation has an obvious suppression effect on the estimation bias in typical cases, and is closer to the CRB.

  34. Thank you!

  35. Questions

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