Perfect periodic sequences for nonlinear Wiener filters

Abstract: A periodic sequence is defined as a perfect periodic sequence for a certain nonlinear filter if the cross-correlation between any two of the filter basis functions, estimated over a period, is zero. Using a perfect periodic sequence as input signal, an unknown nonlinear system can be efficiently identified with the cross-correlation method. Moreover, the basis functions that guarantee the most compact representation according to some information criterion can also be easily estimated. Perfect periodic sequence… Show more

“…In [32,[35][36][37], it has been proved that perfect periodic sequences (PPSs) can be developed for the identification of EMFN and LN filters. A periodic sequence is called perfect for a modeling filter if all cross-correlations between two of its basis functions, estimated over a period, are zero.…”

A study about Chebyshev nonlinear filters

“…In [32,[35][36][37], it has been proved that perfect periodic sequences (PPSs) can be developed for the identification of EMFN and LN filters. A periodic sequence is called perfect for a modeling filter if all cross-correlations between two of its basis functions, estimated over a period, are zero.…”

A study about Chebyshev nonlinear filters

“…PPS are periodic sequences that guarantee the perfect orthogonality of the basis functions over a period and thus can accurately estimate the coefficients of the filter with the cross-correlation approach replacing the expectations in (4) with time averages over a period. A PPS x p (n) of period L suitable for the identification of the Wiener filters up to an order P and memory N and with Gaussian variance σ 2 x can be developed following the approach of [8]. The PPS x p (n) can be derived by imposing that all joint moments of the input signal, estimated over a period, involved in the identification of the WN filter, are equal to those of a white Gaussian signal x(n) ∈ N (0, σ 2 x ).…”

“…Therefore, an unknown system can be efficiently identified with the cross-correlation method using a PPS as input signal. PPSs suitable for the identification of WN filters have been recently proposed in [8] to reduce the accuracy problems in estimating the kernels diagonal points thanks to the perfect orthogonality of the Wiener basis functions for PPSs.…”

“…The Wiener basis functions [8] are a set of polynomial basis functions, which are orthogonal for white Gaussian noise inputs. They can arbitrarily well approximate any discrete time, time-invariant, finite memory, continuous, nonlinear system.…”

“…Perfect periodic sequences (PPSs) [9], [10] have been proposed for linear [11], [12] and nonlinear [8], [13]- [17] system identification as an alternative to stochastic inputs. A PPS ensures that the cross-correlation between any two different basis functions of the system, estimated over a period, is zero.…”

Multivariance nonlinear system identification using Wiener basis functions and perfect sequences

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