Tudor Zamfirescu

[List of publications] List with citations

1. On homothetic triangles (rom.), Gaz. Mat. Fiz. B 10 (1959) 20-21.
2. Properties of arbitrary triangles and their circumscribed circles (rom.), Gaz. Mat. Fiz. B 10 (1959) 346-350.
3. Applications of the three-perpendiculars-theorem (rom.), Gaz. Mat. Fiz. B 12 (1961) 146-150.
4. Isogonal lines and rotated angles in a triangle (rom., hung.), Gaz. Mat. Fiz. B 14 (1963) 207-214.
5. Geometric constructions with ruler, compass, and trisector (rom.), Stud. Cerc. Mat. 15 (1964) 405-411.
6. [1] Note sur les hyperplans isogonaux d'un simplexe, Bull. Math. Soc. Sci. Math. Phys. R.P.R. 8 (1964) 317-320.
cited by:
1. H. Martini, M. Spirova, Revue Roum. Math. Pures Appl. 51 (2006) pp. 57, 64.
7. About the trisectors of a triangle (rom., hung.), Gaz. Mat. B 14 (1964) 483-485.
8. [2] Sur quelques théorèmes de G. Szekeres et S. Marcus concernant les fonctions monotones et convexes, Rev. Roum. Math. Pures Appl. 10 (1965) 81-90.
cited by:
1. B. Bereanu, Revue Roum. Math. Pures Appl. 14 (1969) p. 1077.
2. A. Roberts, D. Varberg, Convex Functions, Acad. Press (1973).
9. Simplicial convexity in vector spaces, Bull. Math. Soc. Sci. Math. Phys. R.P.R. 9 (1965) 137-149.
10. On teaching the similarity of triangles (rom.) (with D. Papadopol), Gaz. Mat. A 70 (1965) 146-149.
11. On the fundamental lemmas of the Calculus of Variations, Rev. Roum. Math. Pures Appl. 10 (1965) 505-510.
12. Constructibility with ruler, compass, and trisector (rom.), Gaz. Mat. A 70 (1965) 204-213.
13. Un problème variationnel dans l'espace de Riemann (with T. Albu), Rev. Roum. Math. Pures Appl. 10 (1965) 1323-1330.
14. On the geodesics of a particular nondifferentiable manifold (rom.), Gaz. Mat. A 70 (1965) 96-99.
15. On teaching the ellipse (rom.), Gaz. Mat. A 70 (1965) 356-358.
16. [1] Sur les fonctions du type K, Rev. Roum. Math. Pures Appl. 10 (1965) 1575-1582.
cited by:
1. B. Bereanu, Revue Roum. Math. Pures Appl. 14 (1969) p. 1077.
17. Caractérisations des hypersurfaces convexes, Bull. Math. Soc. Sci. Math. R.S.R. 9 (1965) 247-252.
18. [2] Réductibilité et séries linéaires de corps convexes, L'Enseign. Math. 12 (1966) 57-67.
cited by:
1. D. Voiculescu, Stud. Cerc. Mat. 18 (1966) pp. 742, 745.
2. R. Schneider, Convex Bodies: the Brunn-Minkowski Theory, Cambridge Univ. Press (1993).
19. Constructions with ruler, compass, and trisector (rom.), Gaz. Mat. A 71 (1966) 9-18.
20. Familles de corps associés à un corps convexe, Bull. Math. Soc. Sci. Math. R.S.R. 10 (1966) 397-412.
21. [3] On pencils of diameters in convex bodies (with A. S. Besicovitch), Rev. Roum. Math. Pures Appl. 11 (1966) 637-639.
cited by:
1. K. Hann, The average number of normals through a point in a convex body and a related Euler-type identity, Geom. Dedicata 48 (1993) p. 54.
2. K. Hann, What's the bound on the average number of normals?, Am. Math. Mon. 103 (1996) pp. 898, 900.
3. V. Soltan, Affine diameters of convex bodies--a survey Expo. Math. 23 (2005) pp. 53, 61.
22. [2] Sur les corps associés à un corps convexe, Rev. Roum. Math. Pures Appl. 12 (1966) 727-735.
cited by:
1. D. Voiculescu, Stud. Cerc. Mat. 18 (1966) pp. 743, 745.
2. R. Schneider, Convex Bodies: the Brunn-Minkowski Theory, Cambridge Univ. Press (1993).
23. [1] Sur les séries linéaires de corps convexes à frontières non différentiables et applications à la réductibilité, Rev. Roum. Math. Pures Appl. 11 (1966) 1015-1022.
cited by:
1. R. Schneider, Convex Bodies: the Brunn-Minkowski Theory, Cambridge Univ. Press (1993).
24. Establishing Frenet's formulae (rom.) (with Ch. Zamfirescu), Gaz. Mat. A 71 (1966) 371-374.
25. [3] Two characterizations of simplices (rom.), Gaz. Mat. A 71 (1966) 422-424.
cited by:
1. E. Heil, H. Martini, Handbook of Convex Geometry, Elsevier Sci. Publ. (1993) p. 347.
2. V. Soltan, Affine diameters of convex bodies--a survey Expo. Math. 23 (2005) pp. 53, 63.
3. H. Martini, M. Spirova, Revue Roum. Math. Pures Appl. 51 (2006) pp. 57, 64.
26. Another kind of problems (rom.), Gaz. Mat. A 71 (1966) 462-468.
27. [1] Sur la réductibilité des corps convexes, Math. Z. 95 (1967) 20-33.
cited by:
1. R. Schneider, Convex Bodies: the Brunn-Minkowski Theory, Cambridge Univ. Press (1993).
28. [1] Sur une fibration de l'espace des corps convexes (with P. Vincensini), C. R. Acad. Sci. Paris A-B 264 (1967) 510-511.
cited by:
1. R. Schneider, Convex Bodies: the Brunn-Minkowski Theory, Cambridge Univ. Press (1993).
29. [1] On l-simplicial convexity in vector spaces, Pacific J. Math. 22 (1967) 565-573.
cited by:
1. J. Bair, R. Fourneau, Etude géométrique des espaces vectoriels, LNM 489 Springer-Verlag (1975).
30. [5] Sur les familles continues de courbes I, Atti Accad. Naz. Lincei Rend. 42 (1967) 771-774.
cited by:
1. B. Grünbaum, Arrangements and Spreads, Reg. Conf. Series in Math. 10 (1972), AMS.
2. C. Ivan, On spreads of curves, Rend. Accad. Naz. Lincei 55 (1973) pp. 46, 49.
3. A. G. Zucco, Sur une conjecture de B. Gruenbaum concernant les familles continues de courbes, Rend. Accad. Naz. Lincei 66 (1979) pp. 372, 376.
4. A. G. Zucco, Sur la multiplicité par rapport à une famille continue de courbes, Rend. Accad. Naz. Lincei 67 (1979) p. 103.
5. A. G. Zucco, Sur une des conjectures de B. Gruenbaum concernant les familles continues de courbes, Rend. Accad. Naz. Lincei 68 (1980) p. 419.
31. [1] Sur quelques questions de continuité liées à la réductibilité des corps convexes, Rev. Roum. Math. Pures Appl. 12 (1967) 989-998.
cited by:
1. R. Schneider, Convex Bodies: the Brunn-Minkowski Theory, Cambridge Univ. Press (1993).
32. [5] Sur les familles continues de courbes II, Atti Accad. Naz. Lincei Rend. 43 (1967) 13-17.
cited by:
1. Grünbaum B., Arrangements and Spreads, Reg. Conf. Series in Math., 10 (1972), AMS.
2. C. Ivan, On spreads of curves, Rend. Accad. Naz. Lincei 55 (1973) pp. 46, 47, 49.
3. A. G. Zucco, Sur une conjecture de B. Gruenbaum concernant les familles continues de courbes, Rend. Accad. Naz. Lincei 66 (1979) pp. 372, 373, 376.
4. A. G. Zucco, Sur la multiplicité par rapport à une famille continue de courbes, Rend. Accad. Naz. Lincei 67 (1979) pp. 99, 100, 103.
5. A. G. Zucco, Sur une des conjectures de B. Gruenbaum concernant les familles continues de courbes, Rend. Accad. Naz. Lincei 68 (1980) pp. 417, 419.
33. [2] Reducibility of convex bodies, Proc. Lond. Math. Soc. 17 (1967) 653-668.
cited by:
1. D. Voiculescu, Stud. Cerc. Mat. 18 (1966) pp. 742, 743, 745.
2. R. Schneider, Convex Bodies: the Brunn-Minkowski Theory, Cambridge Univ. Press (1993).
34. [1] Conditions nécessaires et suffisantes pur la réductibilité des voisinages des corps convexes, Rev. Roum. Math. Pures Appl. 12 (1967) 1523-1527.
cited by:
1. R. Schneider, Convex Bodies: the Brunn-Minkowski Theory, Cambridge Univ. Press (1993).
35. [1] Théorème dual concernant les familles continues des courbes, Bull. Cl. Sci. Acad. Roy. Belg. 53 (1967) 1385-1391.
cited by:
1. B. Grünbaum, Arrangements and Spreads, Reg. Conf. Series in Math. 10 (1972), AMS.
36. [1] Sur les familles continues de courbes III, Atti Accad. Naz. Lincei Rend. 44 (1968) 639-642.
cited by:
1. B. Grünbaum, Arrangements and Spreads, Reg. Conf. Series in Math. 10 (1972), AMS.
37. [1] Sur les familles continues de courbes IV, Atti Accad. Naz. Lincei Rend. 44 (1968) 753-758.
cited by:
1. B. Grünbaum, Arrangements and Spreads, Reg. Conf. Series in Math. 10 (1972), AMS.
38. [1] Sur les points multiples d'une famille continue de courbes, Rend. Circ. Mat. Palermo 18 (1969) 103-112.
cited by:
1. A. G. Zucco, Rend. Accad. Naz. Sci. XL 10 (1986) pp. 172, 176.
39. [1] On a theorem of Chartrand, Kapoor and Kronk, Rend. Circ. Mat. Palermo 18 (1969) 319-322.
cited by:
1. A. Hellwig, L. Volkmann, Maximally edge-connected and vertex-connected graphs and digraphs: A survey, Discrete Math. 308 (2008) pp. 3284, 3296.
40. [2] Les courbes fermées doubles sans points triples associées à une famille continue, Israel J. Math. 7 (1969) 69-89.
cited by:
1. B. Grünbaum, Arrangements and Spreads, Reg. Conf. Series in Math., 10 (1972), AMS.
2. K. S. Watson, Sylvester's problem for spreads of curves, Can. J. Math. 32 (1980) p. 219.
41. [7] On planar continuous families of curves, Canad. J. Math. 21 (1969) 513-530.
cited by:
1. Grünbaum B., Arrangements and Spreads, Reg. Conf. Series in Math., 10 (1972), AMS.
2. Douglas V., J. Reine Ang. Math. 283 (1976) p. 370.
3. A. G. Zucco, Sur une conjecture de B. Gruenbaum concernant les familles continues de courbes, Rend. Accad. Naz. Lincei 66 (1979) p. 376.
4. A. G. Zucco, Sur la multiplicité par rapport à une famille continue de courbes, Rend. Accad. Naz. Lincei 67 (1979) pp. 100, 103.
5. A. G. Zucco, Sur une des conjectures de B. Gruenbaum concernant les familles continues de courbes, Rend. Accad. Naz. Lincei 68 (1980) p. 419.
6. K. S. Watson, Sylvester's problem for spreads of curves, Can. J. Math. 32 (1980) p. 219.
7. R. Guàrdia, F. Hurtado, On the equipartition of plane convex bodies and convex polygons, J. Geom. 83 (2005).
42. [1] The simplicial convexity of convex surfaces, Rev. Roum. Math. Pures Appl. 14 (1969) 889-897.
cited by:
1. J. Bair, R. Fourneau, Etude géométrique des espaces vectoriels, LNM 489 Springer-Verlag (1975).
43. [3] Sur quelques généralisations par F. Browder du principe de contraction de Picard-Banach, Atti Accad. Naz. Lincei Rend. 49 (1970) 11-16.
cited by:
1. I. A. Rus, A. Petrusel, G. Petrusel, Fixed point theory 1950-2000 Romanian contributions, House of the Book of Science, Cluj-Napoca (2002), pp. 13, 16, 216.
2. C. Avramescu, C. Vladimirescu, On the existence of zeros of continuity functions defined in $\Bbb R^n$, Revue Roumaine Math. Pures Appl. 50 (2005) pp. 431, 435, 436.
3. I. A. Rus, A. Petrusel, G. Petrusel, Fixed Point Theory (2008), Cluj Univ. Press.
44. [17] On the line-connectivity of line-graphs, Math. Ann. 187 (1970) 305-309.
cited by:
1. T. Hamada, N. Toshio, I. Yoshimura, On the connectivity of total graphs, Math. Ann. 196 (1972) p. 30.
2. T. Hamada, T. Kitamura, I. Yoshimura, Bull. Fac. Sci., Ibaraki Univ., Math. 7 (1975) pp. 49, 54.
3. T. Hamada, I. Yoshimura I., Traversability and connectivity of the middle graph of a graph, Discrete Math. 14 (1976) p. 247.
4. M. Capobianco, J. C. Molluzzo, Examples and Counterexamples in Graph Theory, Elsevier Science Ltd (1978) pp. 65, 249.
5. Bauer D., Tindell R., J. Graph Th. 3 (1979) p. 393.
6. Bauer D., Tindell R., J. Graph Th. 6 (1982) p. 197.
7. Sun H., Chinese Ann. Math. Ser. A 7 (1986) p. 605.
8. Buckley F., Harary F., Distance in Graphs, Addison-Wesley Publ. Comp. (1990) pp. 64, 326.
9. Prisner E., Graph dynamics, CRC Press (1995).
10. Zamfirescu Ch., Discrete Math. 170 (1997) pp. 293, 297.
11. Zörnig P., Discrete Math. 171 (1997) pp. 277, 281.
12. Xu J., Topological structure and analysis of interconnection networks, Springer (2001) pp. 49, 328.
13. Balbuena C., Ferrero D., Discrete Math. 269 (2003) p. 20.
14. Balbuena C., García-Vázquez P., Discrete Math. 286 (2004) pp. 213, 218.
15. Balbuena C., García-Vázquez P., Discrete Appl. Math. 155 (2007).
16. Li X., Y. Liu, Chinese J. Engineering Math. 24 Iss. 5(2007) pp. 29, 35.
17. A. Hellwig, L. Volkmann, Maximally edge-connected and vertex-connected graphs and digraphs: A survey, Discrete Math. 308 (2008) pp. 3292, 3296.
45. [1] Convexité par rapport à une famille continue de courbes I, Atti Accad. Naz. Lincei Rend. 50 (1971) 625-629.
cited by:
1. Bair J., Fourneau R., Etude géométrique des espaces vectoriels, LNM 489 Springer-Verlag (1975).
46. [3] Area contractions in the plane, Rend. Sem. Mat. Univ. Padova 46 (1971) 49-52.
cited by:
1. Rus I. A., Principii si aplicatii ale teoriei punctului fix, Ed. Dacia, Cluj (1979).
2. Dezsö G., Muresan V., Studia Univ. Babes-Bolyai, Mathematica 26, 3 (1981) pp. 52, 55.
3. Rus I. A., Petrusel A., Petrusel G., Fixed point theory 1950-2000 Romanian contributions, House of the Book of Science, Cluj-Napoca (2002), pp. 29, 30, 216.
4. Rus I. A., Petrusel A., Petrusel G., Fixed Point Theory (2008), Cluj Univ. Press.
47. [2] Convexité par rapport à une famille continue de courbes II, Atti Accad. Naz. Lincei Rend. 51 (1971) 127-132.
cited by:
1. Bair J., Fourneau R., Etude géométrique des espaces vectoriels, LNM 489 Springer-Verlag (1975).
2. Mani P., Handbook of Convex Geometry, Elsevier Sci. Publ. (1993) pp. 31, 41.
48. [1] On k-path hamiltonian graphs and line-graphs, Rend. Sem. Mat. Univ. Padova 46 (1971) 385-389.
cited by:
1. Lesniak-Forster L., J. Graph Th. 1 (1977) p. 27.
49. [1] Trois caractérisations des ensembles convexes, Ist. Veneto Sci. Lett. Atti Cl. Sci. Mat. Natur. 130 (1971/72) 377-384.
cited by:
1. Mani P., Handbook of Convex Geometry, Elsevier Sci. Publ. (1993) pp. 28, 41.
50. [14] A two-connected planar graph without concurrent longest paths, J. Combin. Theory B 13 (1972) 116-121.
cited by:
1. Grünbaum B., Notices Am. Math. Soc. 20 (1973) p. A458.
2. Grünbaum B., J. Comb. Theory, A 17 (1974) p. 31.
3. Walther H., Voss H.-J., Über Kreise in Graphen, VEB Berlin, 1974, pp. 71, 98.
4. Thomassen C. Theor. Appl. Graphs, Proc. Kalamazoo 1976, Lect. Notes Math. 642 (1978).
5. Schmitz W., Rend. Sem. Mat. Univ. Padova 53 (1975) p. 97.
6. Thomassen C., Lecture Notes Math. 642 (1978) p. 557.
7. Hatzel W., Math. Ann. 243 (1979) p. 213.
8. Plummer M. D., Ann. Discrete Math. 20 (1984) pp. 258, 262.
9. Klavzar, Petkovsek, Ars Combin. 29 (1990) p. 43.
10. Voss H.-J., Cycles and Bridges in Graphs, Kluwer Acad. Publ. - Deutscher Verlag Wiss. (1991).
11. Menke B., Studia Sci. Math. Hung. 36 (2000) pp. 229, 230.
12. Cameron P. J., BCC Problem List (2001) pp. 24, 72.
13. Schauerte B., Zamfirescu C. T., Ann. Univ. Craiova, Math. Comp. Sci. Ser. 33 (2006) pp. 154, 161.
14. M. Araya and G. Wiener. On cubic planar hypohamiltonian and hypotraceable graphs, Electron. J. Comb. 18, No. 1, #P85 (2011).
51. [76] Fix point theorems in metric spaces, Arch. Math. 23 (1972) 292-298.
cited by:
1. Rhoades B., Trans. Am. Math. Soc. 196 (1974) p. 161.
2. Popa V., Puiu G., Stud. Cerc. Mat 26 (1974) pp. 439, 444.
3. Pittnauer F., Arch. Math. 26 (1975) p. 421.
4. Iséki K., Application of Zamfirescu's fixed point theorem, Math. Sem. Notes Kobe Univ. 4 (1976) pp. 215, 216.
5. Khazanchi L., Dass B. K., Indian J. Pure Appl. Math. 7 (1976) pp. 602, 609.
6. Rhoades B., J. Math. Anal. 56 (1976) p. 741.
7. Rhoades B., Trans. Am. Math. Soc. 226 (1977) p. 257.
8. Czerwik S., Aeq. Math. 16 (1977) pp. 297, 302.
9. Achari J., Some results on fixed point theorem of Zamfirescu, Mathematica, 20 (1978) pp. 105, 112.
10. Rus I., Metrical Fixed Point Theorems, Cluj (1979) pp. 9, 52.
11. Sharma A. K., Indian J. pure appl. Math. 10 (1979) pp. 752, 757, 760.
12. Reilly I. L., Subrahmanyam P. V., Ind. J. Pure Appl. Math. 11 (1980) pp. 569, 571.
13. Zhang S. S., Chin. Ann. Math. 3 (1982) p. 179.
14. Achari J., Math. Educ., Sect. B 16 (1982) p. 48.
15. Papageorgiou N. S., Nonlinear Anal. 7 (1983) p. 763.
16. Ding X. P., Chin. Ann. Math. 4 (1983) p. 153.
17. Ding X. P., Chin. Ann. Math. 5 (1984) p. 145.
18. Rhoades B., J. Math. Anal. 146 (1990) p. 482.
19. Czerwik S., Acta Mathematica Univ. Ostraviensis 1 (1993) p. 10.
20. Jotik N., Indian J. Pure Appl. Math. 26 (1995) p. 947.
21. Guillerme J., Rev. Mat. Apl. 15 (1995) pp. 56, 61.
22. Paula Collaco, Jaime Carvalho e Silva, Nonlinear Analysis 30 (1997).
23. Berinde V., Bul. Stiint. Univ. Baia Mare, Ser. B 18 (2002) pp. 11, 12, 14.
24. Rus I. A., Petrusel A., Petrusel G., Fixed point theory 1950-2000 Romanian contributions, House of the Book of Science, Cluj-Napoca (2002), pp. 16, 216.
25. Berinde V., Carpathian J. Math. 19 (2003) pp. 9, 12, 20, 22.
26. Berinde V., Iterative approximation of fixed points, Efemeride, Baia Mare (2004) pp. 28, 38, 39, 40, 41, 42, 47, 52, 53, 92, 93, 94, 95, 115, 116, 136, 137, 269.
27. Berinde V., Fixed Point Th. 4 (2003) pp. 133, 135, 142.
28. Berinde V., Nonlinear Analysis Forum 9 (2004) pp. 43, 44, 46, 47, 48, 50, 51, 53.
29. Berinde V., Fixed Point Th. Appl. 2 (2004) pp. 97, 98, 99, 100, 101, 102, 103, 104, 105.
30. Berinde V., Acta Math. Univ. Comenianae 73 (2004) pp. 120, 121, 122, 124, 125, 126.
31. C. Avramescu, C. Vladimirescu, On the existence of zeros of continuity functions defined in $\Bbb R^n$, Revue Roumaine Math. Pures Appl. 50 (2005) pp. 431, 435, 436.
32. Berinde M., Berinde V., Revue Roumaine Math. Pures Appl. 50 (2005) pp. 443, 444, 445, 446, 448, 450, 451, 452, 453.
33. Berinde V., General Math. 13 (2005) pp. 25, 26, 27, 30, 34.
34. Babu G. V., Vara Prasad K. N., Mann iteration converges faster than Ishikawa iteration for the class of Zamfirescu operators, Fixed Point Th. Appl. 2006 (2006) pp. 1, 2, 6.
35. Rafiq A., Intern. J. Math. Math. Sci. 2006 (2006) pp. 1, 2, 6.
36. Olaleru J. O., Carpathian J. Math. 22 (2006) pp. 115, 120.
37. Rafiq A., Math. Communications 11 (2006) pp. 116, 120.
38. Rafiq A., Acta Math. Acad. Paed. Nyireg. 22 (2006) p. 309.
39. Rafiq A., Appl. Math. E-Notes, 6 (2006) pp. 290, 293.
40. Berinde M., Studia Univ. Babes–Bolyai, Math., 51 (2006) pp. 17, 18, 22, 25.
41. Rafiq A., General Math. 14 (2006) pp. 82, 83, 89, 90.
42. Gu F., Math. Communications 12 (2007) pp. 75, 76, 78, 81, 82.
43. Popescu O., Math. Communications 12 (2007) pp. 195, 198, 199, 201, 202.
44. Berinde M., Berinde V., J. Math. Analysis Appl. 326 (2007).
45. Berinde V., Analele Univ. de Vest, Timisoara, Ser. Mat.-Inf. 45 (2007) pp. 35, 36, 39, 41.
46. Olaleru J. O., Proc. World Congress Engin. 2007, Vol II (2007) pp. 1, 4.
47. Berinde V., Pacurar M., Fixed Point Th. 9 (2008).
48. Imoru C. O., Olatinwo M. O., Akinbo G., Bosede A. O., General Math. 16 (2008) pp. 27, 32.
49. Xue Z., Fixed Point Th. Appl. 2008 (2008) pp. 1, 2, 3, 4, 5.
50. Olatinwo M. O., Revista Colombiana Mat. 42 (2008) pp. 146, 147, 150, 151.
51. Olatinwo M. O., Imoru C. O., Some convergence results for the Jungck-Mann and the Jungck-Ishikawa iteration processes in the class of generalized Zamfirescu operators, Acta Math. Univ. Comenianae 77 (2008) pp. 299, 300, 301, 304.
52. Rafiq A., Acu A. M., General Math. 16 (2008) pp. 148, 149, 155, 157.
53. Olatinwo M. O., Fasc. Math. 40 (2008) pp. 38, 43.
54. Rus I. A., Petrusel A., Petrusel G., Fixed Point Theory (2008), Cluj Univ. Press.
55. Soltuz S. M., Grosan T., Fixed Point Th. Appl. 2008 (2008) pp. 2, 6, 7.
56. I. Yildirim, M. Özdemir, H. Kiziltunc, On the convergence of a new two-step iteration in the class of quasi-contractive operators, Int. J. Math. Analysis 3 (2009) pp. 1881, 1882, 1883, 1885, 1886, 1887, 1888, 1889, 1890, 1892.
57. B. Prasad, B. Singh, R. Sahni, Some approximate fixed point theorems, Int. J. Math. Analysis 3 (2009) pp. 204, 205, 207, 208, 209.
58. O. Popescu, Two fixed point theorems for generalized contractions with constants in complete metric space, Central Europ. J. Math. 7 (2009).
59. S. H. Khan, Common fixed points of two quasi-contractive operators in normed spaces by iteration, Int. J. Math. Analysis 3 (2009) pp. 147, 148, 149, 150, 151.
60. M. O. Olatinwo, Acta Math. Acad. Paed. Nyireg. 25 (2009) pp. 106, 107, 118.
61. A. A. Mogbademu and J. O. Olaleru, On the stability of some fixed point iteration procedures with errors, Bol. Asoc. Mat. Venezolana 16 (2009) pp. 31, 32.
62. K. Neammanee, A. Kaewkhao, Fixed Point Theorems of Multi-Valued Zamfirescu Mapping, J. Math. Research 2 (2010) pp. 1, 7.
63. S. L. Singh, S. N. Mishra, Coincidence Theorems for Certain Classes of Hybrid Contractions, Fixed Point Th. Appl. 2010, doi:10.1155/2010/898109 (2010) pp. 1, 2, 3, 10.
64. M. O. Olatinwo, Some stability results for Picard and Mann iteration processes using contractive condition of integral type, Creative Math. & Inf. 19 (2010) pp. 58, 64.
65. M. Abbas, P. Vetro, and S. H. Khan, On fixed points of Berinde's contractive mappings in cone metric spaces, Carpathian J. Math. 26 (2010) pp. 122, 133.
66. Z. Q. Xue, G. W. Lv, B. E. Rhoades, On Equivalence of Some Iterations Convergence for Quasi-Contraction Maps in Convex Metric Spaces, Fixed Point Theory Appl., Article Number: 252871 (2010).
67. V. Berinde, Approximating Common Fixed Points of Noncommuting Almost Contractions in Metric Spaces, Fixed Point Theory 11 (2010).
68. V. Berinde, Common Fixed Points of Noncommuting Discontinuous Weakly Contractive Mappings in Cone Metric Spaces, Taiwan. J. Math. 14 (2010).
69. M. Abbas, D. Ilic, Common Fixed Points of Generalized Almost Nonexpansive Mappings, Filomat 24 (2010).
70. M. Abbas, G. V. R. Babu, G. N. Alemayehu, On common fixed points of weakly compatible mappings satisfying 'generalized condition (B)', Filomat 25 (2011).
71. L. Ciric, M. Abbas, R. Saadati, N. Hussain, Common fixed points of almost generalized contractive mappings in ordered metric spaces, Appl. Math. Comput. 217 (2011).
72. W. Sintunavarat, P. Kumam, Weak condition for generalized multi-valued (f, alpha, beta)-weak contraction mappings, Appl. Math. Lett. 24 (2011).
73. D. Ariza-Ruiz, A. Jimenez-Melado, G. Lopez-Acedo, A fixed point theorem for weakly Zamfirescu mappings, Nonlinear Analysis-Theory Methods & Appl. 74 (2011).
74. Sintunavarat W., Kumam P., Weak condition for generalized multi-valued (f, alpha, beta)-weak contraction mappings, Appl. Math. Lett. 22 (2011).
75. W. Sintunavarat, P. Kumam, Common fixed point theorem for hybrid generalized multi-valued contraction mappings, Appl. Math. Lett. 25 (2012).
76. D. Ilic, V. Pavlovic, V. Rakocevic, Extensions of the Zamfirescu theorem to partial metric spaces, Mathematical and Computer Modelling 55 (2012).
52. [1] On k-path hamiltonian line-graphs, Rend. Ist. Mat. Univ. Trieste 4 (1972) 123-129.
cited by:
1. Lesniak-Forster L., J. Graph Th. 1 (1977) p. 27.
53. [8] A theorem on fixed points, Atti Accad. Naz. Lincei Rend. 52 (1972) 832-834.
cited by:
1. Iséki K., Math. Sem. Notes Kobe Univ. 2 (1974).
2. Rhoades B., Trans. Am. Math. Soc. 226 (1977) p. 257.
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56. On $k$-path hamiltonian graphs, Boll. Unione Mat. Ital. 6 (1972) 61-66.
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68. Quelques questions sur les familles continues de courbes, in "Convex Geometry", Vrije Universiteit Brussel (1977) 31-35.
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2. C. Avramescu, C. Vladimirescu, On the existence of zeros of continuity functions defined in $\Bbb R^n$, Revue Roumaine Math. Pures Appl. 50 (2005) pp. 431, 435, 436.
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70. Sulle famiglie continue di curve VII, Rend. Sem. Mat. Univ. Politecn. Torino 36 (1978) 183-190.
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8. J. F. Le Gall, Geodesics in large planar maps and in the Brownian map, Acta Math. 205 pp. 46, 64 (2010).
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83. Shortness exponents for polytopes which are $k$-gonal modulo $n$ (with M. Schmidt), J. Combin. Theory B 33 (1982) 101-120.
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4. Gruber P., Handbook of Convex Geometry, Elsevier Sci. Publ. (1993) pp. 1335, 1345.
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2. Berinde V., Iterative approximation of fixed points, Efemeride, Baia Mare (2004), p. 269.
3. C. Avramescu, C. Vladimirescu, On the existence of zeros of continuity functions defined in $\Bbb R^n$, Revue Roumaine Math. Pures Appl. 50 (2005) pp. 431, 435, 436.
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1. Gruber P., Handbook of Convex Geometry, Elsevier Sci. Publ. (1993) p. 1327.
2. Jaffard S., J. Math. Pures Appl. 79 (2000), p. 552.
3. Renfro D. L., Essay on non-differentiability points of monotone functions -- http://mathforum.org/discuss/sci.math/t/301615 (2000) pp. 4, 6.
4. Z. Buczolich, J. Nagy, Real Analysis Exchange 26 (2000/2001) pp. 133, 140, 156.
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5. P. Gruber, Handbook of Convex Geometry, Elsevier Sci. Publ. (1993) pp. 1334, 1345.
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91. Interiors of uniform size in Steinitz's theorem (with J. Reay), in "Drittes Kolloquium über Diskrete Geometrie", Universität Salzburg (1985) 319-328.
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14. P. Gruber, Handbook of Convex Geometry, Elsevier Sci. Publ. (1993) p. 1345.
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20. Gruber P., Convex and Discrete Geometry, Springer (2007), pp. 71, 231, 232, 554.
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14. J. Pach, G. Tóth, Algorithms, Architectures and Information Systems Security, World Scientific (2009).
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139. The dimension print of most convex surfaces (with G. Craciun), Monatsh. Math. 123 (1997) 203-207.
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6. J. Itoh, C. Vîlcu, Criteria for farthest points on convex surfaces, Math. Nachr. 282 (2009).
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3. J. Rouyer, J. Geom. 77 (2003) pp. 152, 170.
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6. J. Itoh, C. Vîlcu, J. Geom. 80 (2004) pp. 106, 120.
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8. C. Vîlcu, Math. Ann. 340 (2008).
9. Y. G. Nikonorov, Y. V. Nikonorova, Discrete Comput. Geom. 40 (2008).
10. J. Itoh, C. Vîlcu, Criteria for farthest points on convex surfaces, Math. Nachr. 282 (2009).
11. J. Rouyer, On antipodes on a convex polyhedron II, Adv. Geom. 10 (2010).
12. J. Rouyer, A characterization of the real projective plane, Int. J. Math. 21 (2010).
13. K. Ieiri, J. Itoh, C. Vîlcu, Quasigeodesics and farthest points on convex surfaces, Adv. Geom. 11 (2011).
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4. C. Avramescu, C. Vladimirescu, On the existence of zeros of continuity functions defined in $\Bbb R^n$, Revue Roumaine Math. Pures Appl. 50 (2005) pp. 431, 435, 436.
5. F. S. De Blasi, N. V. Zhivkov, Revue Roumaine Math. Pures Appl. 50 (2005) pp. 555, 564.
6. F. De Blasi, N. Zhivkov, Abstr. Appl. Analysis 2005 (2005) pp. 424, 436.
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149. Dense ambiguous loci and residual cut loci, Rend. Circ. Mat. Palermo Suppl. 65 (2000) 203-208.
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4. L. Yuan, Discrete Comput. Geom. 34 (2005).
5. J. Erickson, D. Guoy, J. Sullivan, A. Üngör, Engineering Comp. 20 (2005) pp. 344, 353.
6. L. Yuan, C. T. Zamfirescu, Bollettino U.M.I. (8) 10-B (2007).
7. J. Itoh, H. Maehara, Ryukyu Math. J. 21 (2008) pp. 16, 22.
8. J. Itoh and L. Yuan. Acute triangulations of flat tori, Eur. J. Comb. 30 (2009) pp. 1, 4.
9. L. Yuan, Acute triangulations of trapezoids, Discrete Appl. Math. 158 (2010).
10. V. Pambuccian, Acute Triangulation of a Triangle in a General Setting, Canad. Math. Bull. 53, No. 3 (2010) pp. 539, 540.
11. L. Yuan. Acute Triangulations of Pentagons, Bull. Math. Soc. Sci. Math. Roum. 53 (101), No. 4 (2010).
12. H. Maehara, On a proper acute triangulation of a polyhedral surface, Discrete Math. 311 (2011) pp. 1903, 1909.
13. X. Feng, L. Yuan, Acute Triangulations of the Cuboctahedral Surface, LNCS 7033 (2011) pp. 73, 82.
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1. B. Schauerte, C. T. Zamfirescu, Regular graphs in which every pair of points is missed by some longest cycle, Ann. Univ. Craiova, Math. Comp. Sci. Ser. 33 (2006).
2. M. Axenovich, When do three longest paths have a common vertex?, Discrete Math. Algorithms Appl. 1 No. 1 (2009) pp. 115, 120.
152. On the length of the cut locus on surfaces (with J. Itoh), Rend. Circ. Mat. Palermo Suppl. 70 (2002) 53-58.
153. [1] Acute triangulations of triangles on the sphere (with J. Itoh), Rend. Circ. Mat. Palermo Suppl. 70 (2002) 59-64.
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2. L. Yuan, C. T. Zamfirescu, Bollettino U.M.I. (8) 10-B (2007) p. 937.
3. J. Itoh, H. Maehara, Ryukyu Math. J. 21 (2008) pp. 16, 22.
4. S. Saraf, Acute and nonobtuse triangulations of polyhedral surfaces, Eur. J. Comb. 30 (2009).
5. J. Brandts, S. Korotov, M. Krizek, J. Solc, On nonobtuse simplicial partitions, SIAM Rev. 51 (2009).
6. H. Maehara, On a proper acute triangulation of a polyhedral surface, Discrete Math. 311 (2011) pp. 1903, 1909.
155. Total curvature and spiralling shortest paths (with I. Bárány and K. Kuperberg), Discrete Comput. Geom. 30 (2003) 167-176.
156. Qualitative infinite version of Erdös' problem about empty polygons, in: Goodman-Pollack Festschrift (2003) 849-853.
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1. C. T. Zamfirescu, Bull. Math. Soc. Sci. Math. Roumanie 47 (2004) pp. 189, 192.
2. L. Yuan, C. T. Zamfirescu, Bollettino U.M.I. (8) 10-B (2007).
3. J. Itoh, H. Maehara, Ryukyu Math. J. 21 (2008) pp. 16, 22.
4. J. Itoh and L. Yuan. Acute triangulations of flat tori, Eur. J. Comb. 30 (2009) pp. 1, 2, 4.
5. L. Yuan, Acute triangulations of trapezoids, Discrete Appl. Math. 158 (2010).
6. V. Pambuccian, Acute Triangulation of a Triangle in a General Setting, Canad. Math. Bull. 53, No. 3 (2010) pp. 534, 541.
7. L. Yuan. Acute Triangulations of Pentagons, Bull. Math. Soc. Sci. Math. Roum. 53 (101), No. 4 (2010).
8. H. Maehara, On a proper acute triangulation of a polyhedral surface, Discrete Math. 311 (2011) pp. 1903, 1909.
9. X. Feng, L. Yuan, Acute Triangulations of the Cuboctahedral Surface, LNCS 7033 (2011) pp. 74, 82.
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2. C. Vîlcu, Math. Ann. 340 (2008).
3. C. Vîlcu, J. Math. Soc. Japan Vol. 60 (2008).
4. J. Itoh, C. Vîlcu, What do cylinders look like?, J. Geom. 95 (2009).
5. M. Berger, Jacob's ladder of differential geometry (2009).
6. R. Espínola, A. Fernández-León, B. Piatek, Fixed Points of Single- and Set-Valued Mappings in Uniformly Convex Metric Spaces with No Metric Convexity, Fixed Point Theory Appl. 2010 (2010) pp. 13, 14, 16.
7. F. Chazal, D. Cohen-Steiner, Q. Mérigot, Boundary Measures for Geometric Inference, Foundat. Comput. Math. 10 No. 2 (2010).
8. R. Espínola, C. Li, G. López, Nearest and farthest points in spaces of curvature bounded below, J. Approx. Theory 162 (2010) pp. 1365, 1366, 1375, 1380.
9. J. P. Moreno, Porosity and unique completion in strictly convex spaces, Math. Z. 267, No. 1-2 (2011).
10. J. Rataj, L. Zajicek, Properties of distance functions on convex surfaces and applications, Czechoslovak Math. J. 61, No. 1 (2011).
11. J. P. Revalski, N. V. Zhivkov, Small sets in best approximation theory, J. Global Optim. 50, No. 1 (2011).
12. R. Espínola, A. Nicolae, Mutually nearest and farthest points of sets and the Drop Theorem in geodesic spaces, Monatsh. Math. 165 (2012).
13. J. Itoh, C. Vîlcu, Cut locus structures on graphs, Discrete Math. 312 (2012).
159. [4] Extending Stechkin's theorem and beyond, Abstract Appl. Analysis 2004 (2004) 255-258.
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1. A. Kaewcharoen, W. A. Kirk, Abstr. Appl. Analysis 2006 (2006) pp. 1, 10.
2. R. Espínola, N. Hussain, Common Fixed Points for Multimaps in Metric Spaces, Fixed Point Theory Appl. (2010) pp. 7, 13.
3. R. Espínola, C. Li, G. López, Nearest and farthest points in spaces of curvature bounded below, J. Approx. Theory 162 (2010) pp. 1365, 1366, 1368, 1380.
4. R. Espínola, A. Nicolae, Mutually nearest and farthest points of sets and the Drop Theorem in geodesic spaces, Monatsh. Math. 165 (2012).
160. On the length of the cut locus for finitely many points (with J. Itoh), Adv. Geom., 5 (2005) 97-106.
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1. F. S. De Blasi, N. V. Zhivkov, On typical sets in Banach spaces and a parametric Kuratowski–Ulam theorem, Monatsh. Math. 158 (2009).
2. F. S. De Blasi, T. Hu, J.-C. Huang, Generic Tychonov well-posedness in spaces of convex sets, Bull. Math. Soc. Sci. Math. Roumanie 54 (2011).
3. J. Rouyer, Generic properties of compact metric spaces , Topol. Appl. 158 (2011).
162. [1] On the perimeter of a triangle in a Minkowski plane (with H. Maehara), Am. Math. Mon. 112 (2005) 521-522.
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1. G. Averkov, Colloq. Math. 107 (2007).
163. [2] Simplices passing through a hole (with J. Itoh), J. Geom. 83 (2005) 65-70.
cited by:
1. Y. Tanoue, Regular triangular pyramids held by a circle, J. Geom. 94 (2009).
2. H. Maehara, N. Tokushige, Regular simplices passing through holes, Geom. Dedicata 145 (2010).
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1. C. Vîlcu, Math. Ann. 340 (2008).
2. J. Itoh, J. Rouyer, C. Vîlcu, Indag. Math. 19 (2008).
3. J. Itoh, C. Vîlcu, Criteria for farthest points on convex surfaces, Math. Nachr. 282 (2009).
4. J. Itoh, C. Vîlcu, What do cylinders look like?, J. Geom. 95 (2009).
5. J. Rouyer, On antipodes on a convex polyhedron II, Adv. Geom. 10 (2010).
6. K. Ieiri, J. Itoh, C. Vîlcu, Quasigeodesics and farthest points on convex surfaces, Adv. Geom. 11 (2011).
165. [1] On the number of shortest paths between points on manifolds, Rend. Circ. Mat. Palermo Suppl. 77 (2006) 643-647.
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1. C. Vîlcu, Math. Ann. 340 (2008).
166. [4] Tetrahedra passing through a circular or square hole (with J. Itoh and Y. Tanoue), Rend. Circ. Mat. Palermo Suppl. 77 (2006) 349-354.
cited by:
1. Rouyer J., Rev. Roum. Math. Pures Appl. 48 (2003) pp. 97, 103.
2. Y. Tanoue, Regular triangular pyramids held by a circle, J. Geom. 94 (2009).
3. H. Maehara, N. Tokushige, Regular simplices passing through holes, Geom. Dedicata 145 (2010).
4. H. Maehara, N. Tokushige, Classification of the Congruent Embeddings of a Tetrahedron into a Triangular Prism, Graphs Comb. 27, No. 3 (Proc. of the Japan Conference on Computational Geometry and Graphs (JCCGG2009)) (2011).
167. [2] On the critical points of a Riemannian surface, Adv. Geom. 6 (2006) 493-500.
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1. C. Vîlcu, J. Math. Soc. Japan 60 (2008) pp. 61, 64.
2. R. Cardenes, J. Maria Pozo, H. Bogunovic, I. Larrabide, A. F. Frangi, Automatic Aneurysm Neck Detection Using Surface Voronoi Diagrams, IEEE Transactions on Medical Imaging 30 (2011).
168. [10] Acute triangulations of the regular dodecahedral surface (with J. Itoh), Eur. J. Comb. 28 (2007) 1072-1086.
cited by:
1. C. T. Zamfirescu, Bull. Math. Soc. Sci. Math. Roumanie 47 (2004) pp. 189, 192.
2. L. Yuan, C. T. Zamfirescu, Bollettino U.M.I. (8) 10-B (2007).
3. J. Itoh, H. Maehara, Ryukyu Math. J. 21 (2008) pp. 16, 22.
4. J. Itoh and L. Yuan. Acute triangulations of flat tori, Eur. J. Comb. 30 (2009) pp. 1, 4.
5. L. Yuan, Acute triangulations of trapezoids, Discrete Appl. Math. 158 (2010).
6. V. Pambuccian, Acute Triangulation of a Triangle in a General Setting, Canad. Math. Bull. 53, No. 3 (2010) pp. 534, 541.
7. L. Yuan, Acute Triangulations of Pentagons, Bull. Math. Soc. Sci. Math. Roum. 53 (101), No. 4 (2010).
8. H. Maehara, On a proper acute triangulation of a polyhedral surface, Discrete Math. 311 (2011) pp. 1903, 1909.
9. J. W. Barrett, E. Sueli, Finite Element Approximation of Kinetic Dilute Polymer Models with Microscopic Cut-Off, ESAIM-Math. Modell. Numer. Anal. 45 (2011).
10. X. Feng, L. Yuan, Acute Triangulations of the Cuboctahedral Surface, LNCS 7033 (2011) pp. 73, 82.
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cited by:
1. C. Vîlcu, Math. Ann. 340 (2008).
2. C. Vîlcu, J. Math. Soc. Japan Vol. 60 (2008).
3. J. Itoh, C. Vîlcu, Criteria for farthest points on convex surfaces, Math. Nachr. 282 (2009).
4. J. Rouyer, A characterization of the real projective plane, Int. J. Math. 21 (2010).
5. K. Ieiri, J. Itoh, C. Vîlcu, Quasigeodesics and farthest points on convex surfaces, Adv. Geom. 11 (2011).
170. [5] Acute triangulations of flat Möbius strips (with L. Yuan), Discrete Comput. Geom. 37 (2007) 671-676.
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1. J. Itoh and L. Yuan, Acute triangulations of flat tori, Eur. J. Comb. 30 (2009) pp. 2, 4.
2. L. Yuan, Acute triangulations of trapezoids, Discrete Appl. Math. 158 (2010).
3. V. Pambuccian, Acute Triangulation of a Triangle in a General Setting, Canad. Math. Bull. 53, No. 3 (2010) pp. 534, 541.
4. L. Yuan, Acute Triangulations of Pentagons, Bull. Math. Soc. Sci. Math. Roum. 53 (101), No. 4 (2010).
5. X. Feng, L. Yuan, Acute Triangulations of the Cuboctahedral Surface, LNCS 7033 (2011) pp. 74, 83.
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1. B. Schauerte, C. T. Zamfirescu, Regular graphs in which every pair of points is missed by some longest cycle, Ann. Univ. Craiova, Math. Comp. Sci. Ser. 33 (2006).
2. G. Wiener, M. Araya, On planar hypohamiltonian graphs, Proceedings of the joint conference on applied mathematics. Kyoto, Japan, 17 Dec. 2009 - 19 Dec. 2009, pp. 31-36, Paper 10 (2009). Cited on pages 31 and 35.
3. G. Wiener and M. Araya, On planar hypohamiltonian graphs, J. Graph Theory 67, No. 1 (2011).
4. M. Araya and G. Wiener, On cubic planar hypohamiltonian and hypotraceable graphs, Electron. J. Comb. 18, No. 1, #P85 (2011).
172. Hamiltonicity of topological grid graphs (with Ch. Zamfirescu), J. Universal Comp. Sci. 13 (2007) 1791-1800.
173. [1] Antipodal trees and mutually critical points on surfaces, Adv. Geom. 7 (2007) 385-390.
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174. [1] Viewing and realizing diameters, J. Geom. 88, 1-2 (2008) 194-199.
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1. J. P. Moreno and A. Seeger, Visibility and diameter maximization of convex bodies, Forum Mathematicum 23, No. 1 (2011).
175. Minkowski's theorem for arbitrary convex sets, Eur. J. Comb. 29 (2008) 1956-1958.
176. Polytopes passing through circles, Periodica Math. Hung. 57 (2008) 227-230.
177. Some remarks on simple closed geodesics of surfaces with ends (with J. Itoh and F. Ohtsuka), Bull. Math. Soc. Sci. Math. Roumanie 52, 3 (2009) 311-319.
178. [2] Hamiltonian properties of generalized Halin graphs (with S. Malik and A. M. Qureshi), Can. Math. Bull. 52 (2009) 416-423.
cited by:
1. S. Malik, A. M. Qureshi, and T. Zamfirescu. Hamiltonicity of Cubic 3-connected k-Halin graphs, Electron. J. Combin. 20, 1 (2013) #P66.
2. C. T. Zamfirescu and T. Zamfirescu. Hamiltonian properties of generalized pyramids, Math. Nachr. 284, 13 (2011) 1739-1747.
179. The Majority in Convexity. Part I: Smoothness, Curvature and Consequences, Editura Univ. Bucuresti (2009).
180. [1] Hamiltonian Connectedness in Directed Toeplitz Graphs (with S. Malik), Bull. Math. Soc. Sci. Math. Roumanie 53, 2 (2010) 145-156.
cited by:
1. R. Euler and T. Zamfirescu. On Planar Toeplitz Graphs, Graphs Combin. 29, 5 (2013) 1311-1327.
181. Non-expanding mappings in graphs, Adv. Appl. Math. Sci. 6 (2010) 23-32.
182. Pushing convex and other bodies through rings and holes, An. Univ. Vest Timisoara, Ser. Mat.-Inf. 48, 1-2 (2010) 299-306.
183. Paolo Pizzetti: The forgotten originator of triangle comparison geometry (with V. Pambuccian), Historia Math. 38, 3 (2011) 415-422.
184. Moderation of convex bodies (with J. Itoh), J. Convex Analysis 18, 3 (2011) 865-872.
185. [1] Hamiltonian properties of generalized pyramids (with C. T. Zamfirescu), Math. Nachr. 284, 13 (2011) 1739-1747.
cited by:
1. S. Malik, A. M. Qureshi, and T. Zamfirescu. Hamiltonicity of Cubic 3-Connected k-Halin Graphs, Electron. J. Combin. 20, 1 (2013) #P66.
186. [1] Acute triangulations of double planar convex bodies (with L. Yuan), Publ. Math. Debrecen 81, 1-2 (2012) 121-126.
cited by:
1. C. T. Zamfirescu. Survey of two-dimensional acute triangulations, Discrete Math. 313, 1 (2013) 35-49.
187. Large Curvature on Typical Convex Surfaces (with K. Adiprasito), J. Convex Analysis 19, 2 (2012) 385-391.
188. On Longest Paths in Triangular Lattice Graphs (with A. D. Jumani), Utilitas Math. 89 (2012) 269-273.
189. [1] Planar Lattice Graphs with Gallai's Property (with F. Nadeem and A. Shabbir), Graphs Combin. 29 (2013) 1523-1529.
cited by:
1. Y. Bashir and T. Zamfirescu. Lattice graphs with Gallai's property, Bull. Math. Soc. Sci. Math. Roumanie 56, 1 (2013) 65-71.
190. On Planar Toeplitz Graphs (with R. Euler), Graphs Combin. 29 (2013) 1311-1327.
191. Highly non-concurrent longest cycles in lattice graphs (with A. Shabbir), Discrete Math. 313 (2013) 1908-1914.
192. Every point is critical (with I. Bárány, J. Itoh and C. Vîlcu), Adv. Math. 235 (2013) 390-397.
193. Lattice graphs with Gallai's property (with Y. Bashir), Bull. Math. Soc. Sci. Math. Roumanie 56, 1 (2013) 65-71.
194. Hamiltonicity of cubic 3-connected k-Halin graphs (with S. Malik and A. M. Qureshi), Electron. J. Combin. 20, 1 (2013) #P66.
195. Intersecting longest paths and longest cycles: A survey (with A. Shabbir and C. T. Zamfirescu), Electron. J. Graph Theory Appl. 1, 1 (2013) 56-76.
196. Balanced triangulations (with L. Jia, L. Yuan, and C. T. Zamfirescu), Discrete Math. 313 (2013) 2178-2191.
197. Circles holding typical convex bodies (with I. Bárány), Libertas Math. 33 (2013) 21-25.
198. Holding Circles and Fixing Frames (with I. Bárány), Discrete Comput. Geom. 50 (2013) 1101-1111.
199. Typical simplicially convex bodies, Adv. Geom. 14 (2014) 109-115.
200. Lattice graphs with non-concurrent longest cycles (with A. D. Jumani and C. T. Zamfirescu), Rend. Sem. Mat. Univ. Padova 132 (2014) 75-82.
201. Right convexity, J. Convex Analysis 21 (2014) 253-260.
202. Hamiltonian connectedness of Toeplitz graphs (with F. Nadeem and A. Shabbir), Mathematics in the 21st Century 6th World Conference, Lahore, March 2013, Springer proceedings in Mathematics and statistics 98 (2014) 135-149.
203. Few Alexandrov Surfaces are Riemann (with K. Adiprasito), J. Nonlinear and Convex Analysis 16 (2015) 1147-1153.
204. When is a Disk Trapped by Four Lines? (with L. Montejano), Graphs Combin. 31 (2015) 467-476.
205. Acute Triangulations of Archimedean Surfaces. The Truncated Tetrahedron (with X. Feng and L. Yuan), Bull. Math. Soc. Sci. Math. Roumanie 58 (2015) 271-282.
206. Right triple convex completion, J. Convex Analysis 22 (2015) 291-301.
207. Dissecting the square into five congruent parts (with L. Yuan and C. T. Zamfirescu), Discrete Math. 339 (2016) 288-298.
208. Critical points on convex surfaces, to appear.

Curriculum Vitae

Current grant: CNCS UEFISCDI, PN-II-ID-PCE-2011-3-0533