Three methods for the study of semilinear equations at resonance

Bogdan Przeradzki

Colloquium Mathematicae (1993)

  • Volume: 66, Issue: 1, page 109-12
  • ISSN: 0010-1354

Abstract

top
Three methods for the study of the solvability of semilinear equations with noninvertible linear parts are compared: the alternative method, the continuation method of Mawhin and a new perturbation method [22]-[27]. Some extension of the last method and applications to differential equations in Banach spaces are presented.

How to cite

top

Przeradzki, Bogdan. "Three methods for the study of semilinear equations at resonance." Colloquium Mathematicae 66.1 (1993): 109-12. <http://eudml.org/doc/210225>.

@article{Przeradzki1993,
abstract = {Three methods for the study of the solvability of semilinear equations with noninvertible linear parts are compared: the alternative method, the continuation method of Mawhin and a new perturbation method [22]-[27]. Some extension of the last method and applications to differential equations in Banach spaces are presented.},
author = {Przeradzki, Bogdan},
journal = {Colloquium Mathematicae},
keywords = {solvability of semilinear equations with noninvertible linear parts; alternative method; continuation method of Mawhin; new perturbation method; differential equations in Banach spaces},
language = {eng},
number = {1},
pages = {109-12},
title = {Three methods for the study of semilinear equations at resonance},
url = {http://eudml.org/doc/210225},
volume = {66},
year = {1993},
}

TY - JOUR
AU - Przeradzki, Bogdan
TI - Three methods for the study of semilinear equations at resonance
JO - Colloquium Mathematicae
PY - 1993
VL - 66
IS - 1
SP - 109
EP - 12
AB - Three methods for the study of the solvability of semilinear equations with noninvertible linear parts are compared: the alternative method, the continuation method of Mawhin and a new perturbation method [22]-[27]. Some extension of the last method and applications to differential equations in Banach spaces are presented.
LA - eng
KW - solvability of semilinear equations with noninvertible linear parts; alternative method; continuation method of Mawhin; new perturbation method; differential equations in Banach spaces
UR - http://eudml.org/doc/210225
ER -

References

top
  1. [1] A. R. Abdullaev and A. B. Burmistrova, On the solvability of boundary value problems at resonance, Differentsial'nye Uravneniya 25 (1989), 2044-2048. Zbl0695.34019
  2. [2] A. Ambrosetti and G. Prodi, On the inversion of some differentiable mappings with singularities between Banach spaces, Ann. Math. Pura Appl. 93 (1973), 231-247. Zbl0288.35020
  3. [3] H. Brézis and L. Nirenberg, Characterizations of the ranges of some nonlinear operators and applications to boundary value problems, Ann. Scuola Norm. Sup. Pisa 5 (1978), 225-326. 
  4. [4] L. Cesari, Functional analysis, nonlinear differential equations, and the alternative method, in: Nonlinear Functional Analysis and Differential Equations, L. Cesari, R. Kannan and J. D. Schuur (eds.), Dekker, New York, 1976, 1-197. 
  5. [5] D. G. de Figueiredo, On the range of nonlinear operators with linear asymptotes which are not invertible, Comment. Math. Univ. Carolinae 15 (1974), 415-428. Zbl0296.35038
  6. [6] K. Deimling, Nonlinear Functional Analysis, Springer, 1985. 
  7. [7] P. Drábek, Landesman-Lazer type condition and nonlinearities with linear growth, Czechoslovak Math. J. 40 (1990), 70-87. Zbl0705.34009
  8. [8] P. Drábek, Landesman-Lazer condition for nonlinear problems with jumping nonlinearities, J. Differential Equations, to appear. 
  9. [9] S. Fučik, Nonlinear equations with noninvertible linear part, Czechoslovak Math. J. 24 (1974), 259-271. 
  10. [10] S. Fučik, Solvability of Nonlinear Equations and Boundary Value Problems, Reidel, Dordrecht, 1980. Zbl0453.47035
  11. [11] R. E. Gaines and J. L. Mawhin, Coincidence Degree and Nonlinear Differential Equations, Lecture Notes in Math. 568, Springer, 1977. Zbl0339.47031
  12. [12] P. Hess, On a theorem by Landesman and Lazer, Indiana Univ. Math. J. 23 (1974), 827-829. Zbl0259.35036
  13. [13] R. Iannacci and M. N. Nkashama, Nonlinear two point boundary value problem at resonance without Landesman-Lazer condition, Proc. Amer. Math. Soc. 106 (1989), 943-952. Zbl0684.34025
  14. [14] R. Iannacci and M. N. Nkashama, Unbounded perturbations of forced second order ordinary differential equations at resonance, J. Differential Equations 69 (1987), 289-309. Zbl0627.34008
  15. [15] R. Iannacci, M. N. Nkashama and J. R. Ward, Nonlinear second order elliptic partial differential equations at resonance, Trans. Amer. Math. Soc. 311 (1989), 710-727. Zbl0686.35045
  16. [16] R. Kannan, Perturbation methods for nonlinear problems at resonance, in: Nonlinear Functional Analysis and Differential Equations, L. Cesari, R. Kannan and J. D. Schuur (eds.), Dekker, New York, 1976, 209-225. 
  17. [17] E. M. Landesman and A. C. Lazer, Nonlinear perturbations of linear elliptic boundary value problems at resonance, J. Math. Mech. 19 (1970), 609-623. Zbl0193.39203
  18. [18] N. G. Lloyd, Degree Theory, Cambridge Univ. Press, Cambridge, 1978. Zbl0367.47001
  19. [19] J. Mawhin, Topological degree methods in nonlinear boundary value problems, Regional Conf. Series in Math. 40, Amer. Math. Soc., Providence, R.I., 1979. 
  20. [20] J. Mawhin, Boundary value problems for vector second order nonlinear ordinary differential equations, in: Lecture Notes in Math. 703, Springer, 1979, 241-249. 
  21. [21] L. C. Piccinini, G. Stampacchia and G. Vidossich, Ordinary Differential Equations in n , Appl. Math. Sci. 39, Springer, 1984. Zbl0535.34001
  22. [22] B. Przeradzki, An abstract version of the resonance theorem, Ann. Polon. Math. 53 (1991), 35-43. Zbl0746.47043
  23. [23] B. Przeradzki, Operator equations at resonance with unbounded nonlinearities, preprint. 
  24. [24] B. Przeradzki, A new continuation method for the study of nonlinear equations at resonance, J. Math. Anal. Appl., to appear. 
  25. [25] B. Przeradzki, A note on solutions of semilinear equations at resonance in a cone, Ann. Polon. Math. 58 (1993), 95-103. 
  26. [26] B. Przeradzki, The solvability of nonlinear equations with noninvertible linear part, Acta Univ. Lodzensis, habilitation thesis. 
  27. [27] B. Przeradzki, Nonlinear boundary value problems at resonance for differential equations in Banach spaces, preprint. 
  28. [28] B. Ruf, Multiplicity results for nonlinear elliptic equations, in: Nonlinear Analysis, Function Spaces and Applications, Vol. 3 (Litomyšl 1986), Teubner-Texte zur Math. 93, Teubner, Leipzig, 1986, 109-138. 
  29. [29] J. Santanilla, Existence of nonnegative solutions of a semilinear equations at resonance with linear growth, Proc. Amer. Math. Soc. 105 (1989), 963-971. Zbl0687.47045
  30. [30] M. Schechter, J. Shapiro and M. Snow, Solution of the nonlinear problem Au=Nu in a Banach space, Trans. Amer. Math. Soc. 241 (1978), 69-78. Zbl0403.47030
  31. [31] S. A. Williams, A sharp sufficient condition for solution of a nonlinear elliptic boundary value problem, J. Differential Equations 8 (1970), 580-586. Zbl0209.13003
  32. [32] S. A. Williams, A connection between the Cesari and Leray-Schauder methods, Michigan Math. J. 15 (1968), 441-448. Zbl0174.45601

NotesEmbed ?

top

You must be logged in to post comments.

To embed these notes on your page include the following JavaScript code on your page where you want the notes to appear.

Only the controls for the widget will be shown in your chosen language. Notes will be shown in their authored language.

Tells the widget how many notes to show per page. You can cycle through additional notes using the next and previous controls.

    
                

                
Note: Best practice suggests putting the JavaScript code just before the closing </body> tag.