Abstract

Weighted total least squares formulated by standard least squares theoryThis contribution presents a simple, attractive, and flexible formulation for the weighted total least squares (WTLS) problem. It is simple because it is based on the well-known standard least squares theory; it is attractive because it allows one to directly use the existing body of knowledge of the least squares theory; and it is flexible because it can be used to a broad field of applications in the error-invariable (EIV) models. Two empirical examples using real and simulated data are presented. The first example, a linear regression model, takes the covariance matrix of the coefficient matrix asQA=Qn⊗Qm, while the second example, a 2-D affine transformation, takes a general structure of the covariance matrixQA.The estimates for the unknown parameters along with their standard deviations of the estimates are obtained for the two examples. The results are shown to be identical to those obtained based on thenonlinearGauss-Helmert model (GHM). We aim to have an impartial evaluation of WTLS and GHM. We further explore the high potential capability of the presented formulation. One can simply obtain the covariance matrix of the WTLS estimates. In addition, one can generalize the orthogonal projectors of the standard least squares from which estimates for the residuals and observations (along with their covariance matrix), and the variance of the unit weight can directly be derived. Also, the constrained WTLS, variance component estimation for an EIV model, and the theory of reliability and data snooping can easily be established, which are in progress for future publications.

Highlights

  • A signi cant part of literature on the estimation theory distinguishes between the standard least squares (SLS) and the total least squares (TLS)

  • In this contribution we showed that the weighted total least squares (WTLS) problem is an extension of the WLS problem

  • A new WTLS algorithm was formulated which is based on the well-known theory of the standard least squares problem

Read more

Summary

Numerical results and discussions

To verify the efficacy of the presented algorithm, two case studies are provided. Both examples have been widely used in many TLS research papers and are of interest in engineering Surveying and Geomatic applications. The rst example is a linear regression model in which real and simulated data sets are used. The second example is a 2-D affine transformation for which simulated weighted datasets have been used. In both examples, the results are compared to the existing WTLS methods along with the results obtained using the nonlinear Gauss-Helmert model

Linear regression model
Two-dimensional affine transformation
Conclusions and outlook

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.