Title :
Frame analysis for biorthogonal cosine-modulated filterbanks
Author_Institution :
Sch. of Electr., Comput., & Telecommun. Eng., Wollongong Univ., NSW, Australia
Abstract :
This paper addresses the efficient computation of frame bounds for cosine-modulated filterbanks. We derive explicit expressions for the eigenvalues of the frame operator that can be easily computed from the prototype´s polyphase components. The number of channels and the downsampling factor may be even or odd, and the oversampling factor is supposed to be an integer. The analysis of low-delay, biorthogonal filterbanks; shows that prototypes solely designed to minimize the stopband energy may lead to wide open frames and, thus, to an undesirable numerical behavior. Because the computational cost of determining the frame bounds with the proposed method is very low, we can directly use the bounds during prototype optimization and obtain prototypes with minimum stopband energy under the condition of fixed frame bounds. Various design examples are presented.
Keywords :
channel bank filters; circuit optimisation; digital filters; eigenvalues and eigenfunctions; fast Fourier transforms; filtering theory; modulation; signal sampling; FFT method; Fournier transforms; autocorrelation sequences; biorthogonal cosine-modulated filterbanks; computational cost; critically sampled filterbanks; discretization error; downsampling factor; eigenvalues; fixed frame bounds; frame analysis; frame bounds; frame operator; low-delay filterbanks; minimum stopband energy; oversampling factor; polyphase components; prototype optimization; signal processing; stopband energy; Computational efficiency; Costs; Delay systems; Design methodology; Eigenvalues and eigenfunctions; Finite impulse response filter; IIR filters; Optimization methods; Prototypes; Sampling methods;
Journal_Title :
Signal Processing, IEEE Transactions on
DOI :
10.1109/TSP.2002.806572
