Abstract:
This thesis focuses on the development of new variants of adaptive filters. Built
around state-space framework, the proposed filters are especially suitable for applications
like tracking, output feedback control and recursive spectrum estimation. They operate
without prior knowledge of process and observation noise statistics and exhibit good
stability properties. The development in this thesis can broadly be classified into state-
space least mean square (SSLMS) and finite memory least-squares filters.
SSLMS is a generalization of the well-known least mean square (LMS) filter.
Incorporating linear time-varying state-space model of the underlying environment,
SSLMS exhibits marked improvement in its tracking performance over the standard
LMS. An extension of SSLMS is SSLMS with adaptive memory (SSLMSWAM).
SSLMSWAM iteratively tunes the step-size parameter by stochastic gradient method in
an attempt to yield its most appropriate value. This filter is useful for situations where a
suitable value of step-size parameter is difficult to obtain beforehand.
Recursive nature of an adaptive filter brings with it stability issues. The concept
of finite memory (or receding horizon) for an adaptive filter is appealing because it
ensures stability. This motivates the development of finite memory filters, both for
iiiunforced and forced systems. Finite impulse response (FIR) adaptive filter, built around
structure of an unforced system, uses weighted observations on a finite interval. Uniform
weighting of the observations results in rectangular RLS (RRLS). Additional flexibility is
achieved by developing an adaptive memory variant of FIR adaptive filter. Similar to
SSLMSWAM, the data window size is iteratively tuned so as to minimize the prediction
error. For the forced system case, a useful solution in the form of receding horizon state
observer is obtained. It finds utility in output feedback control of linear time-varying
systems. An insight into convergence properties of finite memory based filters is
provided by the convergence analyses.
Spectrum update with the arrival of new data is a desirable feature in real-time
spectrum estimation applications. The mathematical equivalence of RRLS resonator bank
and recursive discrete Fourier transform (DFT) gives the rationale for using the newly
developed filters for recursive spectrum estimation. A symmetric windowed variant of
RRLS called ‘truncated exponential RLS (TERLS)’ is useful for reducing spectral
leakage. Same is true for an SSLMS resonator, which has an attractive feature that
spectral side levels and main lobe width may be reduced simultaneously by reducing the
step-size parameter. The higher order resonator (HOR), constructed from several SSLMS
resonators, exhibits close resemblance to an ideal (rectangular) frequency bin, thus
minimizing spectral leakage and increasing resolution.