Title :
Low-Complexity Equalizers---Rank Versus Order Reduction
Author :
Dietl, Guido ; Utschick, Wolfgang
Author_Institution :
Inst. for Circuit Theor. & Signal Process., Munich Technol. Univ.
Abstract :
Reduced-rank approximations of finite impulse response equalizers in Krylov subspaces, e.g., the conjugate gradient algorithm, can be used to decrease computational complexity involved in calculating the filter coefficients. However, an alternative approach would be to reduce the order of the corresponding full-rank filter or to even combine rank and order reduction. In this paper, we compare both reduction methods based on (G, D)-charts where we analyze the mean square error of the reduced-rank equalizers on complexity isosets, i.e., for tuples of the filter length G and its rank D resulting in a certain number of floating point operations. The application of (G, D)-charts to a coded system with an iterative receiver (turbo equalization) reveals the superiority of rank reduction, especially, if one is interested in low-complexity implementations
Keywords :
Wiener filters; computational complexity; conjugate gradient methods; equalisers; filtering theory; floating point arithmetic; matrix algebra; mean square error methods; Krylov subspaces; computational complexity; conjugate gradient algorithm; filter coefficients; finite impulse response equalizers; floating point operations; full-rank filter; iterative receiver; low-complexity equalizers; mean square error; reduced-rank approximations; turbo equalization; Character generation; Circuit theory; Computational complexity; Equalizers; Equations; Finite impulse response filter; Mean square error methods; Nonlinear filters; Signal processing algorithms; Wiener filter;
Conference_Titel :
Signal Processing Advances in Wireless Communications, 2006. SPAWC '06. IEEE 7th Workshop on
Conference_Location :
Cannes
Print_ISBN :
0-7803-9710-X
Electronic_ISBN :
0-7803-9711-8
DOI :
10.1109/SPAWC.2006.346460
