Algorithm 676: ODRPACK: software for weighted orthogonal distance regression

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Algorithm 676: ODRPACK: software for weighted orthogonal distance regression

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ACM Transactions on Mathematical Software (TOMS) archive
Volume 15 , Issue 4 (December 1989) table of contents

Pages: 348 - 364

Year of Publication: 1989

ISSN:0098-3500

Authors

Paul T. Boggs	National Institute of Standards and Technology, Gaithersburg, MD
Janet R. Donaldson	National Institute of Standards and Technology, Boulder, CO
Richaard h. Byrd	Univ. of Colorado, Boulder
Robert B. Schnabel	Univ. of Colorado, Boulder

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ACM New York, NY, USA

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Downloads (6 Weeks): 16, Downloads (12 Months): 133, Citation Count: 0

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appendices and supplements abstract references cited by index terms collaborative colleagues

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APPENDICES and SUPPLEMENTS

ODRPACK (676.gz) (201 KB)

weighted orthogonal distance regression
Gams: K1b1a2,L8a4,L8e5

ABSTRACT

In this paper, we describe ODRPACK, a software package for the weighted orthogonal distance regression problem. This software is an implementation of the algorithm described in [2] for finding the parameters that minimize the sum of the squared weighted orthogonal distances from a set of observations to a curve or surface determined by the parameters. It can also be used to solve the ordinary nonlinear least squares problem. The weighted orthogonal distance regression procedure application to curve and surface fitting and to measurement error models in statistics. The algorithm implemented is an efficient and stable trust region (Levenberg-Marquardt) procedure that exploits the structure of the problem so that the computational cost per iteration is equal to that for the same type of algorithm applied to the ordinary nonlinear least squares problem. The package allows a general weighting scheme, provides for finite difference derivatives, and contains extensive error checking and report generating facilities.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	BOGGS, P. T., BYRD, R. H., DONALDSON, J. R., AND SCHNABEL, R.B. User's reference guide for ODRPACK--Software for weighted orthogonal distance regression. National Institute of Standards and Technology Internal Rep. 89-4103.
	2	Paul T. Boggs , Richard H. Byrd , Robert B. Schnabel, A stable and efficient algorithm for nonlinear orthogonal distance regression, SIAM Journal on Scientific and Statistical Computing, v.8 n.6, p.1052-1078, November 1, 1987 [doi>10.1137/0908085]
	3	BOGGS, P. T., AND DONALDSON, J.R. The computation and use of the asymptotic covariance matrix for measurement error models. National Institute of Standards and Technology Internal Rep. 89-4102.
	4	BOGGS, P. T., DONALDSON, J. R., SCHNABEL, R. B., AND SPIEGELMAN, C.H. A computational examination of orthogonal distance regression. J. Econometrics 38, 1/2 (1988), 169-201.
	5	COWELL, W. R., HAGUE, S. J., AND ILES, R. M.J. Toolpack/1 Introductory Guide. Issued jointly as Publication NP1277, Numerical Algorithms Group, Oxford, England, and Tech. Rep. ANL- 86-43, Argonne National Laboratory, Argonne, Ill., 1986.
	6	J. E. Dennis, Jr. , Robert B. Schnabel, Numerical Methods for Unconstrained Optimization and Nonlinear Equations (Classics in Applied Mathematics, 16), Soc for Industrial & Applied Math, 1996
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	10	EFRON, B. The Jackknife, the Bootstrap and Other Resampling Plans. SIAM, Philadelphia, Pa., 1982.
	11	FONG, K. W., JEFFERSON, T. H., AND SUYEH1RO, T. SLATEC common mathematical library source file format. Lawrence Livermore Laboratory UCRL-53313, Livermore, Calif., 1982.
	12	Wayne A Fuller, Measurement error models, John Wiley & Sons, Inc., New York, NY, 1986
	13	HIMMELBLAU, D.M. Process Analysis by Statistical Methods. Wiley, New York, 1970.
	14	C. L. Lawson , R. J. Hanson , D. R. Kincaid , F. T. Krogh, Basic Linear Algebra Subprograms for Fortran Usage, ACM Transactions on Mathematical Software (TOMS), v.5 n.3, p.308-323, Sept. 1979 [doi>10.1145/355841.355847]
	15	MoR~, J.J. The Levenberg-Marquardt algorithm: Implementation and theory. In Numerical Ana/ys/s, G. A. Watson, Ed. Lecture Notes in Mathematics 630, Springer Verlag, Berlin 1977, 105-116.
	16	Jorge J. Moré , Burton S. Garbow , Kenneth E. Hillstrom, Testing Unconstrained Optimization Software, ACM Transactions on Mathematical Software (TOMS), v.7 n.1, p.17-41, March 1981 [doi>10.1145/355934.355936]

CITED BY 2

	Nicholas A. Allen , Clifford A. Shaffer , Marc T. Vass , Naren Ramakrishnan , Layne T. Watson, Next generation modeling II - applications: improving the development process for eukaryotic cell cycle models with a modeling support environment, Proceedings of the 35th conference on Winter simulation: driving innovation, December 07-10, 2003, New Orleans, Louisiana
	Jason W. Zwolak , Paul T. Boggs , Layne T. Watson, Algorithm 869: ODRPACK95: A weighted orthogonal distance regression code with bound constraints, ACM Transactions on Mathematical Software (TOMS), v.33 n.4, p.27-es, August 2007