Title :
H∞ optimality of the LMS algorithm
Author :
Hassibi, Babak ; Sayed, Ali H. ; Kailath, Thomas
Author_Institution :
Inf. Syst. Lab., Stanford Univ., CA, USA
fDate :
2/1/1996 12:00:00 AM
Abstract :
We show that the celebrated least-mean squares (LMS) adaptive algorithm is H∞ optimal. The LMS algorithm has been long regarded as an approximate solution to either a stochastic or a deterministic least-squares problem, and it essentially amounts to updating the weight vector estimates along the direction of the instantaneous gradient of a quadratic cost function. We show that the LMS can be regarded as the exact solution to a minimization problem in its own right. Namely, we establish that it is a minimax filter: it minimizes the maximum energy gain from the disturbances to the predicted errors, whereas the closely related so-called normalized LMS algorithm minimizes the maximum energy gain from the disturbances to the filtered errors. Moreover, since these algorithms are central H∞ filters, they minimize a certain exponential cost function and are thus also risk-sensitive optimal. We discuss the various implications of these results and show how they provide theoretical justification for the widely observed excellent robustness properties of the LMS filter
Keywords :
H∞ optimisation; adaptive filters; adaptive signal processing; filtering theory; least mean squares methods; minimax techniques; minimisation; prediction theory; H∞ optimality; LMS algorithm; LMS filter; adaptive filtering; central H∞ filters; deterministic least-squares; exact solution; exponential cost function; instantaneous gradient; least-mean squares adaptive algorithm; maximum energy gain; minimax filter; minimization problem; predicted errors; quadratic cost function; risk-sensitive optimal filters; robustness properties; stochastic least-squares; weight vector estimates; Adaptive filters; Computer errors; Cost function; H infinity control; Least squares approximation; Minimax techniques; Recursive estimation; Robustness; Signal processing algorithms; Uncertainty;
Journal_Title :
Signal Processing, IEEE Transactions on
