Optimization of the second order autoregressive model AR(2) for Rayleigh-Jakes flat fading channel estimation with Kalman filter

This paper deals with the estimation of the flat fading Rayleigh channel with Jakes' Doppler spectrum (model due to R.H. Clarke in 1968) and slow fading variations. A common method in literature consists in approximating the variations of the channel using an auto-regressive model of order p (AR(p)), whose parameters are adjusted according to the “correlation matching” (CM) criterion and then estimated by a Kalman filter (KF). Recent studies based on first order AR(1) showed that the performance is far from the Bayesian Cramer-Rao bound for slow to moderate channel variations, which is the case for many applications. The same studies on first order model have shown the importance of replacing the CM criterion with a MAV criterion (Minimization of Asymptotic Variance). Moreover, it has been shown in literature that increasing the order of the model by passing from AR(1) to AR(2) did not improve the performance when the CM criterion is considered. In order to obtain an improvement in performance, it is essential to consider the MAV criterion with second order autoregressive model AR(2), as shown in this article. By imposing a linear relation between one of the parameters and the Doppler frequency, we derive analytic formulas for suboptimal adjustment of the parameters of AR(2) as a function of the noise level and the Doppler frequency of the channel. Theoretical assumptions are validated via simulation.

[1]  R. Winkelstein Closed form evaluation of symmetric two-sided complex integrals , 1981 .

[2]  Bertil Ekstrand,et al.  Analytical Steady State Solution for a Kalman Tracking Filter , 1983, IEEE Transactions on Aerospace and Electronic Systems.

[3]  Soukayna Ghandour-Haidar,et al.  Estimation de canal à évanouissements plats dans les transmissions sans fils à relais multibonds , 2014 .

[4]  Kareem E. Baddour,et al.  Autoregressive models for fading channel simulation , 2001, GLOBECOM'01. IEEE Global Telecommunications Conference (Cat. No.01CH37270).

[5]  Lars Lindbom,et al.  Simplified Kalman estimation of fading mobile radio channels: high performance at LMS computational load , 1993, 1993 IEEE International Conference on Acoustics, Speech, and Signal Processing.

[6]  E. Simon,et al.  Second-order modeling for Rayleigh flat fading channel estimation with Kalman Filter , 2011, 2011 17th International Conference on Digital Signal Processing (DSP).

[7]  Eric Pierre Simon,et al.  Simplified Random-Walk-Model-Based Kalman Filter for Slow to Moderate Fading Channel Estimation in OFDM Systems , 2014, IEEE Transactions on Signal Processing.

[8]  A. Duel-Hallen,et al.  On the performance of coherent and noncoherent multiuser detectors for mobile radio CDMA channels , 1996, Proceedings of ICUPC - 5th International Conference on Universal Personal Communications.

[9]  R. Clarke A statistical theory of mobile-radio reception , 1968 .

[10]  Nastaran Sharifan,et al.  A Classic New Method to Solve Quartic Equations , 2013 .

[11]  Laurent Ros,et al.  On the use of first-order autoregressive modeling for Rayleigh flat fading channel estimation with Kalman filter , 2012, Signal Process..

[12]  Laurent Ros,et al.  Bayesian Cramer-Rao bounds for complex gain parameters estimation of slowly varying Rayleigh channel in OFDM systems , 2009, Signal Process..

[13]  Jonathan D. Cryer,et al.  Time Series Analysis , 1986 .

[14]  Eric Pierre Simon,et al.  Third-Order Kalman Filter: Tuning and Steady-State Performance , 2013, IEEE Signal Processing Letters.

[15]  D. Vaughan A nonrecursive algebraic solution for the discrete Riccati equation , 1970 .