Document Zbl 0246.45015

Kammerer, W. J.; Nashed, M. Z.

Iterative methods for best approximate solutions of linear integral equations of the first and second kinds. (English) Zbl 0246.45015

J. Math. Anal. Appl. 40, 547-573 (1972).

Page: −5 −4 −3 −2 −1 ±0 +1 +2 +3 +4 +5 Show Scanned Page
scan of Zbl 0246.45015

Cited in 33 Documents

MSC:

65R20

Numerical methods for integral equations

Cite Review PDF

Full Text: DOI

References:

[1]	Atkinson, K. E., The solution of nonunique linear integral equations, Numer. Math., 10, 117-124 (1967) · Zbl 0183.18305
[2]	Ben-Israel, A.; Charnes, A., Contributions to the theory of generalized inverses, J. Soc. Ind. Appl. Math., 11, 667-699 (1963) · Zbl 0116.32202
[3]	Beutler, F. J., The operator theory of the pseudo-inverse, I: bounded operators, II: unbounded operators with arbitrary range, J. Math. Anal. Appl., 10, 451-493 (1965) · Zbl 0151.19205
[4]	Bialy, H., Iterative Behandlung linearen Funktionalgleichungen, Arch. Rat. Mech. Anal., 4, 166-176 (1959) · Zbl 0154.40204
[5]	G. Cimmino; G. Cimmino
[6]	Courant, R.; Hilbert, D., (Methods of Mathematical Physics, Vol. 1 (1953), Interscience: Interscience New York) · Zbl 0729.00007
[7]	Desoer, C. A.; Whalen, B. H., A note on pseudoinverses, J. Soc. Ind. Appl. Math., 11, 442-447 (1963) · Zbl 0123.09603
[8]	Douglas, J., Mathematical programming and integral equations, (Symposium on the Numerical Treatment of Ordinary Differential Equations, Integral and Integro-Differential Equations (1960), Birkhäuser: Birkhäuser Basel), 269-274 · Zbl 0108.29903
[9]	Elliott, W. W., Generalized Green’s functions for compatible differential systems, Amer. J. Math., 50, 243-258 (1928) · JFM 54.0477.02
[10]	Fredholm, I., Sur une classe d’équations fonctionelles, Acta Math., 27, 365-390 (1903) · JFM 34.0422.02
[11]	Fridman, V. M., A method of successive approximation for Fredholm integral equations of the first kind, Uspehi Mat. Nauk, 11, 233-234 (1956) · Zbl 0070.32802
[12]	K. O. Friedrichs; K. O. Friedrichs
[13]	Garabedian, P. R., Partial Differential Equations (1964), Wiley: Wiley New York · Zbl 0124.30501
[14]	Halany, A.; Moro, A., A boundary value problem and its adjoint, Ann. Mat. Pura Appl., 79, 399-411 (1968) · Zbl 0194.11803
[15]	Hamburger, H., Non-symmetric operators in Hilbert space, (Proceedings of the Symposium on Spectral Theory and Differential Problems (1951), Oklahoma Agricultural and Mechanical College: Oklahoma Agricultural and Mechanical College Stillwater, OH), 67-112 · Zbl 0067.09004
[16]	Hestenes, M. R., Relative self-adjoint operators in Hilbert spaces, Pacific J. Math., 11, 1315-1357 (1961) · Zbl 0171.34601
[17]	Hestenes, M. R.; Stiefel, E., Method of conjugate gradients for solving linear systems, J. Res. Nat. Bur. Stand. Sect. B, 49, 409-436 (1952) · Zbl 0048.09901
[18]	Hilbert, D., Grundzuge einer allgemeinen Theorie der linearen integral gleichungen (1912), Teubner: Teubner Leipniz and Berlin, reprint of six papers which appeared originally in the Gottinger Nachrichten (1904, pp. 49-51; 1904, pp. 213-259; 1905, pp. 307-338; 1906, pp. 157-227; 1906, pp. 439-480; 1910, pp. 355-417) · JFM 43.0423.01
[19]	Householder, A. S., The Theory of Matrices in Numerical Analysis (1963), Blaisdell: Blaisdell Boston · Zbl 0133.37802
[20]	Hurwitz, W. A., On the pseudo-resolvent to the kernel of an integral equation, Trans. Amer. Math. Soc., 13, 405-418 (1912) · JFM 43.0425.04
[21]	Kallina, C., A Green’s function approach to perturbations of periodic solutions, Pacific J. Math., 29, 325-334 (1969) · Zbl 0176.39001
[22]	Kammerer, W. J.; Nashed, M. Z., Steepest descent for singular linear operators with nonclosed range, Appl. Anal., 1, 143-159 (1971) · Zbl 0212.15802
[23]	Kammerer, W. J.; Nashed, M. Z., On the convergence of the conjugate gradient method for singular linear operator equations, SIAM J. Numer. Anal., 9, 165-181 (1971) · Zbl 0243.65026
[24]	Kantorovich, L. V., Functional analysis and applied mathematics, Uspehi Mat. Nauk, 6, 89-185 (1948) · Zbl 0034.21203
[25]	Kantorovich, L. V.; Akilov, G. P., Functional Analysis in Normed Spaces (1964), Pergamon: Pergamon New York · Zbl 0127.06104
[26]	Keller, H. B., The solution of singular and semidefinite linear systems by iteration, SIAM J. Numer. Anal., 2, 281-290 (1965) · Zbl 0135.37503
[27]	Landesman, E. M., Hilbert-space methods in elliptic partial differential equations, Pacific J. Math., 21, 113-131 (1967) · Zbl 0146.34303
[28]	Lonseth, A. T., Approximate solutions of Fredholm-type integral equations, Bull. Amer. Math. Soc., 60, 415-430 (1954) · Zbl 0056.10003
[29]	Loud, W. S., Generalized inverses and generalized Green’s functions, SIAM J. Appl. Math., 14, 342-369 (1966) · Zbl 0142.00303
[30]	Loud, W. S., Some examples of generalized Green’s functions and generalized Green’s matrices, SIAM Rev., 12, 194-210 (1970) · Zbl 0196.16001
[31]	Mikhlin, S. G.; Smolitskiy, K. L., Approximate Methods for Solution of Differential and Integral Equations (1967), American Elsevier: American Elsevier New York · Zbl 0159.20702
[32]	Nashed, M. Z., Steepest descent for singular linear operator equations, SIAM J. Numer. Anal., 7, 358-362 (1970) · Zbl 0221.65097
[33]	M. Z. Nashed; M. Z. Nashed
[34]	Petryshyn, W. V., On a general iterative method for the approximate solution of linear operator equations, Math. Comp., 17, 1-10 (1963) · Zbl 0111.31701
[35]	Petryshyn, W. V., On generalized inverses and uniform convergence of \((I\) − BK)\(^n\) with applications to iterative methods, J. Math. Anal. Appl., 18, 417-439 (1967) · Zbl 0189.47502
[36]	Rall, L. B., Error bounds for iterative solutions of Fredholm integral equations, Pacific J. Math., 5, 977-986 (1955) · Zbl 0067.35803
[37]	Reid, W. T., Generalized Green’s matrices for compatible systems of differential equations, Amer. J. Math., 53, 443-459 (1931) · Zbl 0001.27502
[38]	Reid, W. T., Generalized Green’s matrices for two-point boundary problems, SIAM J. Appl. Math., 15, 856-870 (1967) · Zbl 0157.15304
[39]	Reid, W. T., Generalized inverses of differential and integral operators, (Theory and Application of Generalized Inverses of Matrices: Symposium Proceedings. Theory and Application of Generalized Inverses of Matrices: Symposium Proceedings, Texas Technological College Mathematics Series, No. 4 (1968), Lubbock: Lubbock Texas), 1-25 · Zbl 0188.17701
[40]	Sheffield, R. D., On pseudo-inverses of linear transformations in Banach spaces, Oak Ridge National Laboratory Report 2133 (1956)
[41]	Showalter, D. W.; Ben-Israel, A., Representation and computation of the generalized inverse of a bounded linear operator between two Hilbert spaces, Accad. Naz. Dei Lincei, 48, 184-194 (1970) · Zbl 0202.41703
[42]	Stakgold, I., (Boundary Value Problems of Mathematical Physics, Vol. I (1966), Macmillan: Macmillan New York) · Zbl 0158.04801
[43]	Taylor, A. E., Introduction to Functional Analysis (1958), Wiley: Wiley New York · Zbl 0081.10202
[44]	Tseng, Yu. Ya, Generalized inverses of unbounded operators between two unitary spaces, Dokl. Akad. Nauk. SSSR (N. S.), 67, 431-434 (1949) · Zbl 0040.06201
[45]	Tseng, Tu. Ya, Properties and classification of generalized inverses of closed operators, Dokl. Akad. Nauk SSR (N. S.), 67, 607-610 (1949) · Zbl 0040.06202
[46]	Tseng, Tu. Ya, Virtual solutions and general inversions, Uspehi Mat. Nauk (N. S.), 11, 213-215 (1956) · Zbl 0073.09602
[47]	Votruba, G. F., Generalized inverses and singular equations in functional analysis, (Ph.D. dissertation (1963), University of Michigan: University of Michigan Ann Arbor, MI) · Zbl 0356.47001
[48]	Walther, A.; Dejon, B., General report on the numerical treatment of integral and integro-differential equations, (Symposium on the Numerical Treatment of Ordinary Differential Equations, Integral and Integro-Differential Equations (1960), Birkhauser: Birkhauser Basel), 645-671 · Zbl 0107.33503
[49]	Wyler, O., Green’s operators, Ann. Mat. Pura Appl., 66, 251-264 (1964) · Zbl 0197.39301
[50]	Yosida, K., Functional Analysis (1968), Springer-Verlag: Springer-Verlag New York · Zbl 0217.16001
[51]	Zaanen, A. C., Linear Analysis (1964), North-Holland: North-Holland Amsterdam · Zbl 0053.25601
[52]	Hayes, R. M., Iterative methods for solving linear problems in Hilbert space, (Paige, L.; Taussky, O., Contributions to the Solution of Systems of Linear Equations and the Determination of Eigenvalues. Contributions to the Solution of Systems of Linear Equations and the Determination of Eigenvalues, National Bureau of Standards, Applied Mathematics Series (1954), U. S. Government Printing Office: U. S. Government Printing Office Washington, DC) · Zbl 0058.10703
[53]	Nashed, M. Z., Generalized inverses, normal solvability and iteration for singular operator equations, (Rall, L. B., Nonlinear Functional Analysis and Applications (1971), Academic Press: Academic Press New York), 311-359 · Zbl 0236.41015

This reference list is based on information provided by the publisher or from digital mathematics libraries. Its items are heuristically matched to zbMATH identifiers and may contain data conversion errors. In some cases that data have been complemented/enhanced by data from zbMATH Open. This attempts to reflect the references listed in the original paper as accurately as possible without claiming completeness or a perfect matching.