Cauchy-like functional equation based on a class of uninorms

Feng Qin

Kybernetika (2015)

  • Volume: 51, Issue: 4, page 678-698
  • ISSN: 0023-5954

Abstract

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Commuting is an important property in any two-step information merging procedure where the results should not depend on the order in which the single steps are performed. In the case of bisymmetric aggregation operators with the neutral elements, Saminger, Mesiar and Dubois, already reduced characterization of commuting n -ary operators to resolving the unary distributive functional equations. And then the full characterizations of these equations are obtained under the assumption that the unary function is non-decreasing and distributive over special aggregation operators, for examples, continuous t-norms, continuous t-conorms and two classes of uninorms. Along this way of thinking, in this paper, we will investigate and fully characterize the following unary distributive functional equation f ( U ( x , y ) ) = U ( f ( x ) , f ( y ) ) , where f : [ 0 , 1 ] [ 0 , 1 ] is an unknown function but unnecessarily non-decreasing, a uninorm U 𝒰 min has a continuously underlying t-norm T U and a continuously underlying t-conorm S U . Our investigation shows that the key point is a transformation from this functional equation to the several known ones. Moreover, this equation has also non-monotone solutions completely different with already obtained ones. Finally, our results extend the previous ones about the Cauchy-like equation f ( A ( x , y ) ) = B ( f ( x ) , f ( y ) ) , where A and B are some continuous t-norm or t-conorm.

How to cite

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Qin, Feng. "Cauchy-like functional equation based on a class of uninorms." Kybernetika 51.4 (2015): 678-698. <http://eudml.org/doc/271814>.

@article{Qin2015,
abstract = {Commuting is an important property in any two-step information merging procedure where the results should not depend on the order in which the single steps are performed. In the case of bisymmetric aggregation operators with the neutral elements, Saminger, Mesiar and Dubois, already reduced characterization of commuting $n$-ary operators to resolving the unary distributive functional equations. And then the full characterizations of these equations are obtained under the assumption that the unary function is non-decreasing and distributive over special aggregation operators, for examples, continuous t-norms, continuous t-conorms and two classes of uninorms. Along this way of thinking, in this paper, we will investigate and fully characterize the following unary distributive functional equation $f(U(x,y))=U(f(x),f(y))$, where $f\colon [0,1]\rightarrow [0,1]$ is an unknown function but unnecessarily non-decreasing, a uninorm $U\in \{\mathcal \{U\}\}_\{\min \}$ has a continuously underlying t-norm $T_U$ and a continuously underlying t-conorm $S_U$. Our investigation shows that the key point is a transformation from this functional equation to the several known ones. Moreover, this equation has also non-monotone solutions completely different with already obtained ones. Finally, our results extend the previous ones about the Cauchy-like equation $f(A(x,y))=B(f(x),f(y))$, where $A$ and $B$ are some continuous t-norm or t-conorm.},
author = {Qin, Feng},
journal = {Kybernetika},
keywords = {fuzzy connectives; distributivity functional equations; T-norms; T-conorms; uninorms; fuzzy connectives; distributivity functional equations; T-norms; T-conorms; uninorms},
language = {eng},
number = {4},
pages = {678-698},
publisher = {Institute of Information Theory and Automation AS CR},
title = {Cauchy-like functional equation based on a class of uninorms},
url = {http://eudml.org/doc/271814},
volume = {51},
year = {2015},
}

TY - JOUR
AU - Qin, Feng
TI - Cauchy-like functional equation based on a class of uninorms
JO - Kybernetika
PY - 2015
PB - Institute of Information Theory and Automation AS CR
VL - 51
IS - 4
SP - 678
EP - 698
AB - Commuting is an important property in any two-step information merging procedure where the results should not depend on the order in which the single steps are performed. In the case of bisymmetric aggregation operators with the neutral elements, Saminger, Mesiar and Dubois, already reduced characterization of commuting $n$-ary operators to resolving the unary distributive functional equations. And then the full characterizations of these equations are obtained under the assumption that the unary function is non-decreasing and distributive over special aggregation operators, for examples, continuous t-norms, continuous t-conorms and two classes of uninorms. Along this way of thinking, in this paper, we will investigate and fully characterize the following unary distributive functional equation $f(U(x,y))=U(f(x),f(y))$, where $f\colon [0,1]\rightarrow [0,1]$ is an unknown function but unnecessarily non-decreasing, a uninorm $U\in {\mathcal {U}}_{\min }$ has a continuously underlying t-norm $T_U$ and a continuously underlying t-conorm $S_U$. Our investigation shows that the key point is a transformation from this functional equation to the several known ones. Moreover, this equation has also non-monotone solutions completely different with already obtained ones. Finally, our results extend the previous ones about the Cauchy-like equation $f(A(x,y))=B(f(x),f(y))$, where $A$ and $B$ are some continuous t-norm or t-conorm.
LA - eng
KW - fuzzy connectives; distributivity functional equations; T-norms; T-conorms; uninorms; fuzzy connectives; distributivity functional equations; T-norms; T-conorms; uninorms
UR - http://eudml.org/doc/271814
ER -

References

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  1. Aczél, J., 10.1002/zamm.19670470321, Acad. Press, New York 1966. Zbl0139.09301MR0208210DOI10.1002/zamm.19670470321
  2. Aczél, J., Maksa, G., Taylor, M., 10.1006/jmaa.1997.5580, J. Math. Anal. Appl. 214 (1997), 1, 22-35. Zbl0936.39009MR1645499DOI10.1006/jmaa.1997.5580
  3. Baczyński, M., Jayaram, B., 10.1109/TFUZZ.2008.924201, IEEE Trans. Fuzzy Systems 17 (2009), 3, 590-603. DOI10.1109/TFUZZ.2008.924201
  4. Beliakov, G., Calvo, T., Pradera, A., Aggregation Functions: A Guide for Practitioners., Springer-Verlag, Berlin - Heidelberg 2007. 
  5. Benvenuti, P., Vivona, D., General theory of the fuzzy integral., Mathware Soft Comput. 3 (1996), 199-209. Zbl0857.28014MR1414267
  6. Combs, W. E., Andrews, J. E., 10.1109/91.660804, IEEE Trans. Fuzzy Systems 6 (1) (1998), 1, 1-11. DOI10.1109/91.660804
  7. Baets, B. De, Meyer, H. De, Mesiar, R., 10.1016/j.fss.2011.09.013, Fuzzy Sets and Systems 191 (2012), 82-102. Zbl1237.62063MR2874825DOI10.1016/j.fss.2011.09.013
  8. Díaz, S., Montes, S., Baets, B. De, 10.1109/tfuzz.2006.880004, IEEE Trans. Fuzzy Systems 15 (2007), 2, 275-286. DOI10.1109/tfuzz.2006.880004
  9. Dubois, D., Fodor, J., Prade, H., Roubens, M., 10.1007/bf00134116, Theory Decision 41 (1996), 59-95. Zbl0863.90020MR1401341DOI10.1007/bf00134116
  10. Fodor, J., Roubens, M., 10.1007/978-94-017-1648-2, Kluwer, Dordrecht 1994. Zbl0827.90002DOI10.1007/978-94-017-1648-2
  11. Fodor, J., Yager, R. R., Rybalov, A., 10.1142/s0218488597000312, Int. J. Uncertainly and Knowledge-Based Systems 5 (1997), 411-427. Zbl1232.03015MR1471619DOI10.1142/s0218488597000312
  12. Gottwald, S., A Treatise on Many-Valued Logics., Research Studies Press, Hertfordshire 2001. Zbl1048.03002MR1856623
  13. Grabisch, M., Marichal, J. L., Mesiar, R., Pap, E., 10.1017/cbo9781139644150, Cambridge University Press, 2009. Zbl1206.68299MR2538324DOI10.1017/cbo9781139644150
  14. Klement, E. P., Mesiar, R., Pap, E., 10.1007/978-94-015-9540-7, Kluwer, Dordrecht 2000. Zbl1087.20041MR1790096DOI10.1007/978-94-015-9540-7
  15. McConway, K. J., 10.1080/01621459.1981.10477661, J. Amer. Stat. Assoc. 76 (1981), 410-414. Zbl0455.90004MR0624342DOI10.1080/01621459.1981.10477661
  16. Qin, F., 10.1109/fuzz-ieee.2014.6891537, IEEE Trans. Fuzzy Systems 20 (2013), 126-132. DOI10.1109/fuzz-ieee.2014.6891537
  17. Qin, F., Baczyński, M., 10.1109/TFUZZ.2011.2171188, IEEE Trans. Fuzzy Syst. 21 (2012), 1, 153-167. DOI10.1109/TFUZZ.2011.2171188
  18. Qin, F., Baczyński, M., 10.1016/j.fss.2013.07.020, Fuzzy Sets and Systems 240 (2014), 86-102. Zbl1315.03040MR3167514DOI10.1016/j.fss.2013.07.020
  19. Qin, F., Yang, P. C., On the distributive equation of implication based on a continuous t-norm and a continuous Archimedean t-conorm., In: BMEI, 4th International Conference 4, 2011, pp. 2290-2294. 
  20. Qin, F., Yang, L., 10.1016/j.ijar.2010.07.005, Int. J. Approx. Reason. 51 (2010), 984-992. MR2719614DOI10.1016/j.ijar.2010.07.005
  21. Rudas, I. J., Pap, E., Fodor, J., 10.1016/j.knosys.2012.07.025, Knowledge-Based Systems 38 (2013), 3-13. DOI10.1016/j.knosys.2012.07.025
  22. Ruiz, D., Torrens, J., Residual implications and co-implications from idempotent uninorms., Kybernetika 40 (2004), 21-38. Zbl1249.94095MR2068596
  23. Saminger, S., Mesiar, R., Bodenhofer, U., 10.1142/S0218488502001806, Int. J. Uncertainty Fuzziness Knowledge-Based Systems 10/s (2002), 11-35. Zbl1053.03514MR1962666DOI10.1142/S0218488502001806
  24. Saminger-Platz, S., Mesiar, R., Dubois, D., 10.1109/TFUZZ.2006.890687, IEEE Trans. Fuzzy Syst. 15 (2007), 6, 1032-1045. DOI10.1109/TFUZZ.2006.890687
  25. Su, Y., Wang, Z., Tang, K., Left and right semi-uninorms on a complete lattice., Kybernetika 49 (2013), 6, 948-961. Zbl1286.03098MR3182650
  26. Yager, R. R., Rybalov, A., 10.1016/0165-0114(95)00133-6, Fuzzy Sets and Systems 80 (1996), 111-120. Zbl0871.04007MR1389951DOI10.1016/0165-0114(95)00133-6

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