Title :
Gradient flow approach to discrete-time envelope-constrained filter design via orthonormal filters
Author :
Tseng, C.H. ; Teo, K.L. ; Zang, Z. ; Cantoni, A.
Author_Institution :
Telecomm. Res. Inst., Curtin Univ. of Technol., Perth, WA, Australia
fDate :
2/1/2000 12:00:00 AM
Abstract :
Using digital orthonormal filters and Lagrangian duality theory, the envelope-constrained (EC) filtering problem has been formulated as a dual quadratic programming (QP) problem with simple constraints. Applying the barrier-gradient and barrier-Newton methods based on the space transformation and gradient flow technique, two efficient design algorithms are constructed for solving this QP problem. An adaptive algorithm, based on the barrier-gradient algorithm, is developed to solve the EC filtering problem in a stochastic environment. The convergence properties are established in the mean and mean square error senses. To demonstrate the effectiveness of the proposed algorithms, a practical example using the Laguerre networks is solved for both the deterministic and stochastic cases
Keywords :
Newton method; adaptive filters; convergence of numerical methods; digital filters; discrete time filters; quadratic programming; stochastic processes; Lagrangian duality theory; Laguerre networks; adaptive algorithm; barrier-Newton method; barrier-gradient method; convergence properties; design algorithms; deterministic case; digital orthonormal filters; discrete-time envelope-constrained filter design; dual quadratic programming problem; gradient flow approach; mean error sense; mean square error sense; orthonormal filters; simple constraints; space transformation; stochastic environment;
Journal_Title :
Vision, Image and Signal Processing, IEE Proceedings -
DOI :
10.1049/ip-vis:20000307
