Abstract
In this contribution it is shown that the so-called “total least-squares estimate” (TLS) within an errors-in-variables (EIV) model can be identified as a special case of the method of least-squares within the nonlinear Gauss–Helmert model. In contrast to the EIV-model, the nonlinear GH-model does not impose any restrictions on the form of functional relationship between the quantities involved in the model. Even more complex EIV-models, which require specific approaches like “generalized total least-squares” (GTLS) or “structured total least-squares” (STLS), can be treated as nonlinear GH-models without any serious problems. The example of a similarity transformation of planar coordinates shows that the “total least-squares solution” can be obtained easily from a rigorous evaluation of the Gauss–Helmert model. In contrast to weighted TLS, weights can then be introduced without further limitations. Using two numerical examples taken from the literature, these solutions are compared with those obtained from certain specialized TLS approaches.
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References
Aitken AC (1935) On least squares and linear combinations of observations. Proc R Soc Edinburgh 55: 42–48
Akyilmaz O (2007) Total least squares solution of coordinate transformation. Surv Rev 39(303): 68–80
Benning W (2007) Statistics in geodesy, geoinformation and civil engineering (in German), 2nd edn. Herbert Wichmann Verlag, Heidelberg
Böck R (1961) Most general formulation of least-squares adjustment computations (in German). Z für Vermessungswesen 86:43–45 (see also pp 98–106)
Felus Y, Schaffrin B (2005) Performing similarity transformations using the errors-in-variables-model. In: Proceedings of the ASPRS Meeting, Washington, DC, May 2005, on CD
Gauss CF (1809) Theoria motus corporum coelestium in sectionibus conicis solem ambientium. F. Perthes und I.H. Besser, Hamburg
Golub GH, van Loan C (1980) An analysis of the total least-squares problem. SIAM J Numer Anal 17(6): 883–893
Helmert FR (1924) Adjustment computation with the least-squares method (in German), 3rd edn. Teubner-Verlag, Leipzig
Lawson CL, Hanson RJ (1974) Solving least-squares problems. Prentice-Hall, Englewood Cliffs
Lenzmann L, Lenzmann E (2004) Rigorous adjustment of the nonlinear Gauss–Helmert model (in German). Allgem Verm Nachr 111: 68–73
Mikhail EM, Gracie G (1981) Analysis and adjustment of survey measurements. Van Nostrand Reinhold Company, New York
Neitzel F, Petrovic S (2008) Total least-squares (TLS) in the context of least-squares adjustment on the example of straight-line fitting (in German). Z für Vermessungswesen 133: 141–148
Niemeier W (2008) Adjustment computations (in German), 2nd edn. Walter de Gruyter, New York
Petrovic S (2003) Parameter estimation for incomplete functional models in geodesy (in German). German Geodetic Comm, Publ. No. C-563, Munich
Pope AJ (1972) Some pitfalls to be avoided in the iterative adjustment of nonlinear problems. In: Proceedings of the 38th Annual Meeting of the American Society of Photogrammetry, Washington, DC, pp 449–477
Schaffrin B, Lee I, Felus Y, Choi Y (2006) Total least-squares (TLS) for geodetic straight-line and plane adjustment. Boll Geod Sci Affini 65(3): 141–168
Schaffrin B (2008) Correspondence, coordinate transformation. Surv Rev 40(307): 102
Schaffrin B, Felus Y (2008) On the multivariate total least-squares approach to empirical coordinate transformations. Three Algorithms J Geod 82(6): 373–383
Schaffrin B, Wieser A (2008) On weighted total least-squares adjustment for linear regression. J Geod 82(7): 415–421
Schaffrin B, Neitzel F (2011) Modifying Cadzow’s algorithm to generate the TLS solution for Structured EIV-Models (submitted)
Schaffrin B, Snow K (2010) Total least-squares regularization of Tykhonov type and an ancient racetrack in Corinth. Linear Algebra Appl 432(8): 2061–2076
Schaffrin B, Wieser A (2009) Empirical affine reference frame transformations by weighted multivariate TLS adjustment. In: Drewes H (ed) International Association of Geodesy Symposia Volume 134, Geodetic Reference Frames IAG Symposium Munich, Germany, 9–14 October 2006, pp 213–218
Schwarz HR, Rutishauser H, Stiefel E (1968) Numerics of symmetric matrices (in German). B. G. Teubner, Stuttgart
van Huffel S, Vandewalle J (1991) The total least-squares problem, computational aspects and analysis. SIAM, Philadelphia
Wolf PR, Ghilani CD (1997) Adjustment computations: statistics and least squares in surveying and GIS. Wiley, New York
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Neitzel, F. Generalization of total least-squares on example of unweighted and weighted 2D similarity transformation. J Geod 84, 751–762 (2010). https://doi.org/10.1007/s00190-010-0408-0
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DOI: https://doi.org/10.1007/s00190-010-0408-0