Title :
A divide and conquer approach to least-squares estimation
Author :
Abel, Jonathan S.
Author_Institution :
Tetra Syst. Inc., Palo Alto, CA
fDate :
3/1/1990 12:00:00 AM
Abstract :
The problem of estimating parameters θ which determine the mean μ(θ) of a Gaussian-distributed observation X is considered. It is noted that the maximum-likelihood (ML) estimate, in this case the least-squares estimate, has desirable statistical properties but can be difficult to compute when μ(θ) is a nonlinear function of θ. An estimate formed by combining ML estimates based on subsections of the data vector X is proposed as a computationally inexpensive alternative. The main result is that this alternative estimate, termed here the divide-and-conquer (DAC) estimate, has ML performance in the small-error region when X is appropriately subdivided. As an example application, an inexpensive range-difference-based position estimator is derived and shown by means of Monte-Carlo simulation to have small-error-region mean-square error equal to the Cramer-Rao lower bound
Keywords :
Monte Carlo methods; least squares approximations; parameter estimation; Cramer-Rao lower bound; Gaussian-distributed observation; Monte-Carlo simulation; data vector; divide and conquer estimate; least-squares estimation; maximum likelihood estimate; mean; mean-square error; nonlinear function; parameter estimation; position estimator; statistical properties; subsections; Acoustic signal processing; Additive noise; Gaussian noise; Gaussian processes; Least squares approximation; Maximum likelihood estimation; Mean square error methods; Parameter estimation; Signal processing; Statistics;
Journal_Title :
Aerospace and Electronic Systems, IEEE Transactions on
