[[1] Grzegorz Bancerek. König’s theorem. Formalized Mathematics, 1(3):589–593, 1990.]Search in Google Scholar
[[2] Grzegorz Bancerek. On powers of cardinals. Formalized Mathematics, 3(1):89–93, 1992.]Search in Google Scholar
[[3] Grzegorz Bancerek. The fundamental properties of natural numbers. Formalized Mathematics, 1(1):41–46, 1990.]Search in Google Scholar
[[4] Grzegorz Bancerek and Krzysztof Hryniewiecki. Segments of natural numbers and finite sequences. Formalized Mathematics, 1(1):107–114, 1990.]Search in Google Scholar
[[5] Czesław Byliński. The complex numbers. Formalized Mathematics, 1(3):507–513, 1990.]Search in Google Scholar
[[6] Czesław Byliński. Finite sequences and tuples of elements of a non-empty sets. Formalized Mathematics, 1(3):529–536, 1990.]Search in Google Scholar
[[7] Czesław Byliński. Functions and their basic properties. Formalized Mathematics, 1(1): 55–65, 1990.]Search in Google Scholar
[[8] Czesław Byliński. The sum and product of finite sequences of real numbers. Formalized Mathematics, 1(4):661–668, 1990.]Search in Google Scholar
[[9] Czesław Byliński. Some basic properties of sets. Formalized Mathematics, 1(1):47–53, 1990.]Search in Google Scholar
[[10] Agata Darmochwał. The Euclidean space. Formalized Mathematics, 2(4):599–603, 1991.]Search in Google Scholar
[[11] Michel Marie Deza and Elena Deza. Encyclopedia of distances. Springer, 2009.]Search in Google Scholar
[[12] Noboru Endou, Katsumi Wasaki, and Yasunari Shidama. Definitions and basic properties of measurable functions. Formalized Mathematics, 9(3):495–500, 2001.]Search in Google Scholar
[[13] Adam Grabowski. On the subcontinua of a real line. Formalized Mathematics, 11(3): 313–322, 2003.]Search in Google Scholar
[[14] Adam Grabowski. On the Borel families of subsets of topological spaces. Formalized Mathematics, 13(4):453–461, 2005.]Search in Google Scholar
[[15] Artur Korniłowicz. The correspondence between n-dimensional Euclidean space and the product of n real lines. Formalized Mathematics, 18(1):81–85, 2010. doi:10.2478/v10037-010-0011-0.10.2478/v10037-010-0011-0]Search in Google Scholar
[[16] Jean Mawhin. Analyse: fondements, techniques, évolution. De Boeck, 1992.]Search in Google Scholar
[[17] Beata Padlewska. Families of sets. Formalized Mathematics, 1(1):147–152, 1990.]Search in Google Scholar
[[18] Karol Pak. Tietze extension theorem for n-dimensional spaces. Formalized Mathematics, 22(1):11–19, 2014. doi:10.2478/forma-2014-0002.10.2478/forma-2014-0002]Search in Google Scholar
[[19] Jan Popiołek. Some properties of functions modul and signum. Formalized Mathematics, 1(2):263–264, 1990.]Search in Google Scholar
[[20] Marco Riccardi. The definition of topological manifolds. Formalized Mathematics, 19(1): 41–44, 2011. doi:10.2478/v10037-011-0007-4.10.2478/v10037-011-0007-4]Search in Google Scholar
[[21] Marco Riccardi. Planes and spheres as topological manifolds. Stereographic projection. Formalized Mathematics, 20(1):41–45, 2012. doi:10.2478/v10037-012-0006-0.10.2478/v10037-012-0006-0]Search in Google Scholar
[[22] Jean Schmets. Analyse mathematique. Notes de cours, Université de Liège, 337 pages, 2004.]Search in Google Scholar
[[23] Alexander Yu. Shibakov and Andrzej Trybulec. The Cantor set. Formalized Mathematics, 5(2):233–236, 1996.]Search in Google Scholar
[[24] Andrzej Trybulec. Binary operations applied to functions. Formalized Mathematics, 1 (2):329–334, 1990.]Search in Google Scholar
[[25] Wojciech A. Trybulec. Pigeon hole principle. Formalized Mathematics, 1(3):575–579, 1990.]Search in Google Scholar
[[26] Wojciech A. Trybulec. Basis of real linear space. Formalized Mathematics, 1(5):847–850, 1990.]Search in Google Scholar
[[27] Edmund Woronowicz. Relations defined on sets. Formalized Mathematics, 1(1):181–186, 1990.]Search in Google Scholar
