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Prediction of Fading Broadband Wireless Channels. JOINT BEATS/Wireless IP seminar, Loen. Torbjörn Ekman UniK-University Graduate Center Oslo, Norway. Contents. Motivation Noise Reduction Linear Prediction of Channels Delay Spacing, Sub-sampling Results Power Prediction Results
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Prediction of Fading Broadband Wireless Channels JOINT BEATS/Wireless IP seminar, Loen Torbjörn Ekman UniK-University Graduate Center Oslo, Norway
Contents • Motivation • Noise Reduction • Linear Prediction of Channels • Delay Spacing, Sub-sampling • Results • Power Prediction • Results • Recommendations
Why? With channels known in advance the problem with fast fading can be turned into an advantage • Adaptive resource allocation • Fast link adaptation The multi-user diversity can be exploited
Noise Reduction of Estimated Channels The estimated Doppler spectrum is low pass and has a noise floor. The same noise floor is seen in the power delay profile.
FIR or IIR Wiener-smoother? • IIR smoothers • based on a low pass ARMA-model • can be numerically sensitive • need few parameters • FIR smoothers • based on a model for the covariance • need many parameters • Both have similar performance. • Both use estimates of the variance of the estimation error and the Doppler frequency.
Linear Prediction of Mobile Radio Channels • A step towards power prediction • Can produce prediction of the frequency response • Model for the tap • The FIR-predictor • The MSE-optimal coefficients
The MSE optimal delay spacing for the Jakes model depends on the variance of the estimation error. The NMSE has many local minima.
Sub-sampling and aliasing • OSR 50 • Sub-sampling rate 13 • Jakes model • SNR 10dB • 16 predictor coefficients • FIR Wiener smoother (128)
Prediction performance on a Jakes model • OSR 50 (100 samples per l) • FIR predictor, 8 coefficients • FIR Wiener smoother (128) • Dashed lines: no smoother
The Measurements • Channel sounder measurements in urban and suburban Stockholm • Carrier frequency 1880MHz • Baseband sampling rate 6.4MHz • Channel update rate 9.1kHz • Vehicle speeds 30-90km/h • 1430 consecutive impulse responses at each location • Data from 41 measurement locations
Power Prediction • The power of a tap • A biased quadratic predictor • An unbiased quadratic predictor • Rayleigh fading taps: the optimal q for the complex tap prediction is optimal also for the power prediction.
Observed power or complex regressors? • AR2-process • Approx. Jakes • FIR predictor (2) • Dash-dotted line for observed power in the regressors.
Predictor Design • Estimate the channel with uttermost care. • Noise reduction using Wiener smoothers. • Estimate sub-sampled AR-models or use a direct FIR-predictor. • Estimate as few parameters as possible. • Design Kalman predictor using a noise model that compensates for estimation errors • Power prediction: Squared magnitude of tap prediction with added bias compensation.