Abbott, T. G. 2008. Generalizations of Kempe’s universality theorem. M.Phil. thesis, Massachusetts Institute of Technology. (353)Google Scholar

Adiprasito, K. 2019. FAQ on the g-theorem and the hard Lefschetz theorem for face rings. Rend. Mat. Appl., VII. Ser., 40(2), 97–111. (393)Google Scholar

Adiprasito, K., Papadakis, S. A., and Petrotou, V. 2021. Anisotropy, biased pairings, and the Lefschetz property for pseudomanifolds and cycles. arXiv:2101.07245. (393)Google Scholar

Adiprasito, K. A., and Benedetti, B. 2014. The Hirsch conjecture holds for normal flag complexes. Math. Oper. Res., 39(4), 1340–1348. (335, 338)CrossRefGoogle Scholar

Adiprasito, K. A., and Sanyal, R. 2016. Relative Stanley-Reisner theory and upper bound theorems for Minkowski sums. Publ. Math., Inst. Hautes Étud. Sci., 124, 99–163. (277, 304)CrossRefGoogle Scholar

Adler, I., and Dantzig, G. 1974. Maximum diameter of abstract polytopes. Math. Program. Study, 1, 20–40. (335, 336)CrossRefGoogle Scholar

Alon, N., and Kalai, G. 1985. A simple proof of the upper bound theorem. Eur. J. Comb., 6(3), 211–214. (393)CrossRefGoogle Scholar

Altshuler, A., and Shemer, I. 1984. Construction theorems for polytopes. Isr. J. Math., 47(2–3), 99–110. (105, 153)CrossRefGoogle Scholar

Andreev, E. M. 1970a. On convex polyhedra in Lobachevskij spaces. Math. USSR, Sb., 10, 413–440. (212)CrossRefGoogle Scholar

Andreev, E. M. 1970b. On convex polyhedra of finite volume in Lobachevskii space. Math. USSR, Sb., 12, 255–259. (212)CrossRefGoogle Scholar

Ardila, F., and Develin, M. 2009. Tropical hyperplane arrangements and oriented matroids. Math. Z., 262(4), 795–816. (110)CrossRefGoogle Scholar

Asimow, L., and Roth, B. 1978. The rigidity of graphs. Trans. Amer. Math. Soc., 245, 279–289. (352)CrossRefGoogle Scholar

Asimow, L., and Roth, B. 1979. The rigidity of graphs. II. J. Math. Anal. Appl., 68(1), 171–190. (360)CrossRefGoogle Scholar

Athanasiadis, C. A. 2009. On the graph connectivity of skeleta of convex polytopes. Discrete Comput. Geom., 42(2), 155–165. (231, 252)CrossRefGoogle Scholar

Athanasiadis, C. A. 2011. Some combinatorial properties of flag simplicial pseudomanifolds and spheres. Ark. Mat., 49(1), 17–29. (221)CrossRefGoogle Scholar

Avis, D., and Moriyama, S. 2009. On combinatorial properties of linear program digraphs. Pages 1–13 of: Polyhedral computation. CRM Proc. Lecture Notes, vol. 48. Providence, RI: AMS. (176)CrossRefGoogle Scholar

Babson, E., Finschi, L., and Fukuda, K. 2001. Cocircuit graphs and efficient orientation reconstruction in oriented matroids. Eur. J. Comb., 22(5), 587–600. (271)CrossRefGoogle Scholar

Babson, E. K., Billera, L. J., and Chan, C. S. 1997. Neighborly cubical spheres and a cubical lower bound conjecture. Isr. J. Math., 102, 297–315. (263, 391, 399)CrossRefGoogle Scholar

Bajmóczy, E. G., and Bárány, I. 1979. On a common generalization of Borsuk’s and Radon’s theorem. Acta Math. Acad. Sci. Hung., 34(3), 347–350. (43)CrossRefGoogle Scholar

Balinski, M. L. 1961. On the graph structure of convex polyhedra in n-space. Pac. J. Math., 11, 431–434. (161, 231, 232, 254)CrossRefGoogle Scholar

Bárány, I. 1982. A generalization of Carathéodory’s theorem. Discrete Math., 40(2–3), 141–152. (42)CrossRefGoogle Scholar

Bárány, I. 2021. Combinatorial convexity. Providence, RI: AMS. (42, 43)CrossRefGoogle Scholar

Bárány, I., and Rote, G. 2006. Strictly convex drawings of planar graphs. Doc. Math., 11, 369–391. (198)CrossRefGoogle Scholar

Barnette, D. W. 1969. A simple 4-dimensional nonfacet. Isr. J. Math., 7, 16–20. (339, 389)CrossRefGoogle Scholar

Barnette, D. W. 1971. The minimum number of vertices of a simple polytope. Isr. J. Math., 10, 121–125. (236, 350, 371, 372, 374, 378, 392)CrossRefGoogle Scholar

Barnette, D. W. 1973a. Generating planar 4-connected graphs. Isr. J. Math., 14, 1–13. (221)CrossRefGoogle Scholar

Barnette, D. W. 1973b. Graph theorems for manifolds. Isr. J. Math., 16, 62–72. (254)CrossRefGoogle Scholar

Barnette, D. W. 1973c. A proof of the lower bound conjecture for convex polytopes. Pac. J. Math., 46, 349–354. (236, 340, 350, 371, 372, 374, 378, 392, 393)CrossRefGoogle Scholar

Barnette, D. W. 1974a. The projection of the f-vectors of 4-polytopes onto the (E, S)-plane. Discrete Math., 10, 201–216. (341, 343)CrossRefGoogle Scholar

Barnette, D. W. 1974b. An upper bound for the diameter of a polytope. Discrete Math., 10, 9–13. (319, 323, 327, 339)CrossRefGoogle Scholar

Barnette, D. W. 1982. Decompositions of homology manifolds and their graphs. Isr. J. Math., 41, 203–212. (254)CrossRefGoogle Scholar

Barnette, D. W. 1987a. 5-connected 3-polytopes are refinements of octahedra. J. Comb. Theory, Ser. B, 42(2), 250–254. (221, 228, 395)CrossRefGoogle Scholar

Barnette, D. W. 1987b. Two “simple” 3-spheres. Discrete Math., 67, 97–99. (212, 272, 397)CrossRefGoogle Scholar

Barnette, D. W., and Grünbaum, B. 1969. On Steinitz’s theorem concerning convex 3-polytopes and on some properties of planar graphs. Pages 27–40 of: The many facets of graph theory (Proc. Conf., Western Mich. Univ., Kalamazoo, Mich., 1968). Berlin: Springer-Verlag. (212)CrossRefGoogle Scholar

Barnette, D. W., and Grünbaum, B. 1970. Preassigning the shape of a face. Pac. J. Math., 32, 299–306. (212)CrossRefGoogle Scholar

Barnette, D. W., and Reay, J. R. 1973. Projections of f-vectors of four-polytopes. J. Comb. Theory, Ser. A, 15, 200–209. (341, 342)CrossRefGoogle Scholar

Batagelj, V. 1989. An improved inductive definition of two restricted classes of triangulations of the plane. Pages 11–18 of: Combinatorics and graph theory, vol. 25. Warsaw: Banach Cent. Publ. (221, 228, 395)Google Scholar

Bayer, M. 1987. The extended f-vectors of 4-polytopes. J. Comb. Theory, Ser. A, 44, 141–151. (386, 387, 393)CrossRefGoogle Scholar

Bayer, M. M. 2018. Graphs, skeleta and reconstruction of polytopes. Acta Math. Hung., 155, 61–73. (272)Google Scholar

Bayer, M. M., and Billera, L. J. 1984. Counting faces and chains in polytopes and posets. Pages 207–252 of: Green, C. (ed), Combinatorics and algebra (Proc. Conf., Boulder/Colo. 1983), Contemp. Math., vol. 34. Providence, RI: Amer. Math. Soc. (393)Google Scholar

Bayer, M. M., and Billera, L. J. 1985. Generalized Dehn–Sommerville relations for polytopes, spheres and Eulerian partially ordered sets. Invent. Math., 79, 143–157. (340, 381, 390)CrossRefGoogle Scholar

Beineke, L. W. 1968. On derived graphs and digraphs. Beitr. Graphentheorie, Int. Kolloquium Manebach (DDR) 1967, 17–23 (1968). (426)Google Scholar

Beineke, L. W. 1970. Characterizations of derived graphs. J. Comb. Theory, 9, 129–135. (426)CrossRefGoogle Scholar

Berger, M. 2009. Geometry I. Universitext. Berlin: Springer-Verlag. Translated from the 1977 French original by M. Cole and S. Levy. (16, 42, 153)Google Scholar

Billera, L. J., and Lee, C. W. 1981. A proof of the sufficiency of McMullen’s conditions for f-vectors of simplicial convex polytopes. J. Comb. Theory, Ser. B, 31(3), 237–255. (372, 378)CrossRefGoogle Scholar

Björner, A., and Vorwerk, K. 2015. On the connectivity of manifold graphs. Proc. Am. Math. Soc., 143(10), 4123–4132. (254)CrossRefGoogle Scholar

Björner, A., Edelman, P. H., and Ziegler, G. M. 1990. Hyperplane arrangements with a lattice of regions. Discrete Comput. Geom., 5(3), 263–288. (270)CrossRefGoogle Scholar

Blind, R., and Blind, G. 1994. Gaps in the numbers of vertices of cubical polytopes, I. Discrete Comput. Geom., 11(3), 351–356. (184, 229)CrossRefGoogle Scholar

Blind, G., and Blind, R. 1998. The almost simple cubical polytopes. Discrete Math., 184(1–3), 25–48. (93)CrossRefGoogle Scholar

Blind, G., and Blind, R. 1999. Shellings and the lower bound theorem. Discrete Comput. Geom., 21(4), 519–526. (374, 393)CrossRefGoogle Scholar

Blind, G., and Blind, R. 2003. On a class of equifacetted polytopes. Pages 69–78 of: Discrete geometry. Monogr. Textbooks Pure Appl. Math., vol. 253. New York: Dekker. (389, 392, 399)Google Scholar

Blind, R., and Mani-Levitska, P. 1987. Puzzles and polytope isomorphisms. Aequationes Math., 34(2–3), 287–297. (256)CrossRefGoogle Scholar

Bollobás, B., and Thomason, A. 1996. Highly linked graphs. Combinatorica, 16(3), 313–320. (255)Google Scholar

Bondy, J. A., and Murty, U. S. R. 2008. Graph theory. Graduate Texts in Mathematics, vol. 244. New York: Springer. (xi, 164, 407, 408, 409, 410, 417, 422, 427)CrossRefGoogle Scholar

Bonichon, N., Felsner, S., and Mosbah, M. 2007. Convex drawings of 3-connected plane graphs. Algorithmica, 47(4), 399–420. (198)CrossRefGoogle Scholar

Bonifas, N., Di Summa, M., Eisenbrand, F., Hähnle, N., and Niemeier, M. 2014. On sub-determinants and the diameter of polyhedra. Discrete Comput. Geom., 52(1), 102–115. (335)CrossRefGoogle Scholar

Brehm, U., and Sarkaria, K. S. 1992. Linear vs piecewise linear embeddability of simplicial complexes. 92/52. Max-Planck-Institut für Mathematik. (225)Google Scholar

Bremner, D., and Schewe, L. 2011. Edge-graph diameter bounds for convex polytopes with few facets. Exp. Math., 20(3), 229–237. (335)CrossRefGoogle Scholar

Bricard, R. 1897. Mémoire sur la théorie de l’octaèdre articulé. J. Math. Pures Appl., 3, 113–148. (366)Google Scholar

Brightwell, G. R., and Scheinerman, E. R. 1993. Representations of planar graphs. SIAM J. Discrete Math., 6(2), 214–229. (214)CrossRefGoogle Scholar

Brinkmann, G., Greenberg, S., Greenhill, C., McKay, B.D, Thomas, R., and Wollan, P. 2005. Generation of simple quadrangulations of the sphere. Discrete Math., 305(1), 33–54. (221, 228, 230, 395)CrossRefGoogle Scholar

Brøndsted, A. 1982. A dual proof of the upper bound theorem. Pages 39–43 of: Convexity and related combinatorial geometry (Norman, Okla., 1980). Lecture Notes in Pure and Appl. Math., vol. 76. New York: Dekker. (393)Google Scholar

Brøndsted, A. 1983. An introduction to convex polytopes. Graduate Texts in Mathematics, vol. 90. New York: Springer-Verlag. (x, 32, 42, 70, 87, 88, 152, 153, 229, 393)Google Scholar

Brouwer, L. E. J. 1912. Beweis des Jordan’schen Satzes für den n-dimensionalen Raum. Math. Ann., 71, 314–319. (401)CrossRefGoogle Scholar

Bruggesser, H., and Mani, P. 1971. Shellable decompositions of cells and spheres. Math. Scand., 29, 197–205. (123, 128)CrossRefGoogle Scholar

Bui, H. T., Pineda-Villavicencio, G., and Ugon, J. 2024. The linkedness of cubical polytopes: Beyond the cube. Discrete Math., 347(3), 113801. (245)CrossRefGoogle Scholar

Bui, H. T., Pineda-Villavicencio, G., and Ugon, J. 2021. The linkedness of cubical polytopes: The cube. Electron. J. Comb., 28, P3.45. (249, 253)CrossRefGoogle Scholar

Bunt, L. N. H. 1934. Bijdrage tot de theorie der convexe puntverzamelingen. Thesis, University of Groningen, Amsterdam. (43)Google Scholar

Cai, M.C. 1993. The number of vertices of degree k in a minimally k-edge-connected graph. J. Comb. Theory, Ser. B, 58(2), 225–239. (415)CrossRefGoogle Scholar

Carathéodory, C. 1907. Über den Variabilitätsbereich der Koeffizienten von Potenzreihen, die gegebene Werte nicht annehmen. Math. Ann., 64, 95–115. (20, 42)CrossRefGoogle Scholar

Chartrand, G., and Stewart, M. J. 1969. The connectivity of line-graphs. Math. Ann., 182(3), 170–174. (414)CrossRefGoogle Scholar

Chartrand, G., Kaugars, A., and Lick, D. R. 1972. Critically n-connected graphs. Proc. Am. Math. Soc., 32(1), 63–68. (413)Google Scholar

Conforti, M., Cornuéjols, G., and Zambelli, G. 2014. Integer programming. Vol. 271. Cham: Springer. (58)CrossRefGoogle Scholar

Connelly, R., and Guest, S. D. 2022. Frameworks, tensegrities, and symmetry. Cambridge: Cambridge University Press. (351, 371, 392)Google Scholar

Cordovil, R., and Duchet, P. 2000. Cyclic polytopes and oriented matroids. Eur. J. Comb., 21(1), 49–64. (101)CrossRefGoogle Scholar

Courdurier, M. 2006. On stars and links of shellable polytopal complexes. J. Comb. Theory, Ser. A, 113(4), 692–697. (154)Google Scholar

Cremona, L. 1890. Graphical statics. Two treatises on the graphical calculus and reciprocal figures in graphical statics. Oxford: Clarendon Press. (198)Google Scholar

Criado, F., and Santos, F. 2017. The maximum diameter of pure simplicial complexes and pseudo-manifolds. Discrete Comput. Geom., 58(3), 643–649. (338)CrossRefGoogle Scholar

Danaraj, G., and Klee, V. 1974. Shellings of spheres and polytopes. Duke Math. J., 41, 443–451. (173, 229)CrossRefGoogle Scholar

Dancis, J. 1984. Triangulated n-manifolds are determined by their [n/2]+ 1-skeletons. Topol. Appl., 18(1), 17–26. (263)CrossRefGoogle Scholar

Dantzig, G. B. 1963. Linear programming and extensions. Princeton, NJ: Princeton University Press. (306)Google Scholar

Davies, J., and Pfender, F. 2021. Edge-maximal graphs on orientable and some nonorientable surfaces. J. Graph Theory, 98(3), 405–425. (420)CrossRefGoogle Scholar

Davis, C. 1954. Theory of positive linear dependence. Am. J. Math., 76(4), 733–746. (34)CrossRefGoogle Scholar

De Loera, J. A., Kim, E. D., Onn, S., and Santos, F. 2009. Graphs of transportation polytopes. J. Comb. Theory, Ser. A, 116(8), 1306–1325. (110)CrossRefGoogle Scholar

De Loera, J. A., Rambau, J., and Santos, F. 2010. Triangulations: Structures for algorithms and applications. Algorithms and Computation in Mathematics, vol. 25. Berlin: Springer-Verlag. (154)CrossRefGoogle Scholar

de Verdière, Y. C. 1991. Un principe variationnel pour les empilements de cercles. Invent. Math., 104(1), 655–669. (212)CrossRefGoogle Scholar

Dehn, M. 1905. Die Eulersche Formel im Zusammenhang mit dem Inhalt in der nichteuklidischen Geometrie. Math. Ann., 61, 561–586. (131)CrossRefGoogle Scholar

Dehn, M. 1916. Über die Starrheit konvexer Polyeder. Math. Ann., 77, 466–473. (364, 366, 367)CrossRefGoogle Scholar

Del Pia, A., and Michini, C. 2016. On the diameter of lattice polytopes. Discrete Comput. Geom., 55(3), 681–687. (333, 335)CrossRefGoogle Scholar

Deo, S. 2018. Algebraic topology. A primer. 2nd ed. Vol. 27. New Delhi: Hindustan Book Agency; Singapore: Springer. (401)CrossRefGoogle Scholar

Develin, M. 2004. LP-orientations of cubes and crosspolytopes. Adv. Geom., 4(4), 459–468. (175, 226)CrossRefGoogle Scholar

Deza, A., and Pournin, L. 2018. Improved bounds on the diameter of lattice polytopes. Acta Math. Hung., 154(2), 457–469. (335)CrossRefGoogle Scholar

Deza, A., and Pournin, L. 2019. Diameter, decomposability, and Minkowski sums of polytopes. Can. Math. Bull., 62(4), 741–755. (299, 302)CrossRefGoogle Scholar

Diestel, R. 2017. Graph theory. 5th ed. Graduate Texts in Mathematics, vol. 173. Berlin: Springer-Verlag. (xi, 165, 181, 182, 215, 255, 405, 408, 411, 412, 414, 415, 416, 417, 419, 420, 423, 424, 425)CrossRefGoogle Scholar

Dirac, G. A. 1960. In abstrakten Graphen vorhandene vollständige 4-Graphen und ihre Unterteilungen. Math. Nachr., 22, 61–85. (417)CrossRefGoogle Scholar

Doolittle, J. 2018. A minimal counterexample to strengthening of Perles’s conjecture. arXiv:809.00662. (271)Google Scholar

Doolittle, J., Nevo, E., Pineda-Villavicencio, G., Ugon, J., and Yost, D. 2018. On the reconstruction of polytopes. Discrete Comput. Geom., 61(2), 285–302. (272, 397)Google Scholar

Edelsbrunner, H. 2012. Algorithms in combinatorial geometry. 1st ed. Berlin: Springer. (153)Google Scholar

Eggleston, H. G., Grünbaum, Branko, and Klee, Victor. 1964. Some semicontinuity theorems for convex polytopes and cell-complexes. Comment. Math. Helv., 39, 165–188. (105, 153)CrossRefGoogle Scholar

Ehrenborg, R., and Hetyei, G. 1995. Generalizations of Baxter’s theorem and cubical homology. J. Comb. Theory, Ser. A, 69(2), 233–287. (227)CrossRefGoogle Scholar

Eisenbrand, F., Hähnle, N., Razborov, A., and Rothvoß, T. 2010. Diameter of polyhedra: Limits of abstraction. Math. Oper. Res., 35(4), 786–794. (335, 336, 338, 339)Google Scholar

Elmasry, A., Mehlhorn, K., and Schmidt, J. M. 2013. Every DFS tree of a 3-connected graph contains a contractible edge. J. Graph Theory, 72(1–2), 112–121. (412, 425)Google Scholar

Eppstein, D. n.d. Twenty-one proofs of Euler’s formula: V − E + F = 2. Accessed 22 September 2021. www.ics.uci.edu/~eppstein/junkyard/euler/. (418)Google Scholar

Erickson, J. 2020. Tutte’s spring embedding. http://jeffe.cs.illinois.edu/teaching/topology20/notes/12-spring-embedding.pdf. (230)Google Scholar

Euler, L. 1736. Solutio problematis ad geometriam situs pertinentis. Comment. Acad. Sci. U. Petrop., 8 (Reprinted in Opera Omnia Series Prima, Vol. 7. pp. 1-10, 1766.), 128–140. (404)Google Scholar

Euler, L. 1758a. Demonstratio nonnullarum insignium proprietatum quibas solida hedris planis inclusa sunt praedita. Novi Comm. Acad. Sci. Imp. Petropol., 4, 140–160. (130, 418)Google Scholar

Euler, L. 1758b. Elementa doctrinae solidorum. Novi Comm. Acad. Sci. Imp. Petropol., 4, 109–140. (128, 130, 418)Google Scholar

Ewald, G. 1996. Combinatorial convexity and algebraic geometry. Graduate Texts in Mathematics, vol. 168. New York: Springer-Verlag. (393)CrossRefGoogle Scholar

Ewald, G., and Shephard, G. C. 1974. Stellar subdivisions of boundary complexes of convex polytopes. Math. Ann., 210, 7–16. (150)CrossRefGoogle Scholar

Farkas, J. 1898. Die algebraischen Grundlagen der Anwendungen des Fourier’schen Principes in der Mechanik. Ungar. Ber., 15, 25–40. (152)Google Scholar

Farkas, J. 1901. Theorie der einfachen Ungleichungen. J. Reine Angew. Math., 124, 1–27. (152)Google Scholar

Fáry, I. 1948. On straight line representation of planar graphs. Acta Sci. Math., 11, 229–233. (158)Google Scholar

Felsner, S., and Rote, G. 2019. On primal-dual circle representations. Pages 8:1–8:18 of: Fineman, Jeremy, and Mitzenmacher, Michael (eds), Simplicity in Algorithms (Proc. 2nd Symposium, San Diego, 2019). OpenAccess Series in Informatics (OASIcs), vol. 69. Schloss Dagstuhl–Leibniz-Zentrum für Informatik. (230)Google Scholar

Firsching, M. 2020. The complete enumeration of 4-polytopes and 3-spheres with nine vertices. Isr. J. Math., 240, 417–441. (228, 307, 395)CrossRefGoogle Scholar

Fleming, B., and Karu, K. 2010. Hard Lefschetz theorem for simple polytopes. J. Algebr. Comb., 32(2), 227–239. (393)CrossRefGoogle Scholar

Flores, A. 1934. Über n-dimensionale Komplexe, die im R_2n+1 absolut selbstverschlungen sind. Ergeb. Math. Kolloq., 6, 4–7. (155, 225)Google Scholar

Fortuna, E., Frigerio, R., and Pardini, R. 2016. Projective geometry: Solved problems and theory review. Vol. 104. Switzerland: Springer. (42)CrossRefGoogle Scholar

Fourier, J. B. J. 1827. Analyse des travaux de l’Académie Royale des Sciences pendant l’année 1824. Partie mathématique. (46)Google Scholar

Francese, C., and Richeson, D. 2007. The flaw in Euler’s proof of his polyhedral formula. Am. Math. Mon., 114(4), 286–296. (128)CrossRefGoogle Scholar

Franklin, P. 1934. A six color problem. J. Math. Phys., 13, 363–369. (420)CrossRefGoogle Scholar

Friedman, E. J. 2009. Finding a simple polytope from its graph in polynomial time. Discrete Comput. Geom., 41(2), 249–256. (256, 264, 265, 269)CrossRefGoogle Scholar

Friedmann, O. 2011. A subexponential lower bound for Zadeh’s pivoting rule for solving linear programs and games. Pages 192–206 of: Integer programming and combinatoral optimization (Proc. 15th international conference, IPCO 2011, New York, 2011). Berlin: Springer. (306)Google Scholar

Fukuda, K. 2004. From the zonotope construction to the Minkowski addition of convex polytopes. J. Symbolic Comput., 38(4), 1261–1272. (303, 304)CrossRefGoogle Scholar

Fukuda, K. 2022. Frequently asked questions in polyhedral computation. https://people.inf.ethz.ch/fukudak/. (52)Google Scholar

Fusy, Éric. 2006. Counting d-polytopes with d + 3 vertices. Electron. J. Comb., 13(1), R23. (144)CrossRefGoogle Scholar

Gale, D. 1954. Irreducible convex sets. Pages 217–218 of: Proceedings of the International Congress of Mathematics, vol. II. (278)Google Scholar

Gale, D. 1963. Neighborly and cyclic polytopes. Pages 225–232 of: Proc. Sympos. Pure Math, vol. 7. (95)CrossRefGoogle Scholar

Gallet, M., Grasegger, G., Legerský, J., and Schicho, J. 2021. Combinatorics of Bricard’s octahedra. C. R., Math., Acad. Sci. Paris, 359(1), 7–38. (367)Google Scholar

Gallier, J. 2011. Geometric methods and applications. 2nd ed. Texts in Applied Mathematics, vol. 38. New York: Springer. (8, 42, 153)CrossRefGoogle Scholar

Gallivan, S. 1985. Disjoint edge paths between given vertices of a convex polytope. J. Comb. Theory, Ser. A, 39(1), 112–115. (231, 247, 254, 255, 396)CrossRefGoogle Scholar

Gawrilow, E., and Joswig, M. 2000. Polymake: A framework for analyzing convex polytopes. Pages 43–73 of: Kalai, G., Ziegler, G.M. (eds) Polytopes— Combinatorics and computation. DMV Sem., vol. 29. Basel: Birkhäuser. (262)CrossRefGoogle Scholar

Geelen, J. 2012. On how to draw a graph. www.math.uwaterloo.ca/~jfgeelen/Publications/tutte.pdf. (230)Google Scholar

Gluck, H. 1975. Almost all simply connected closed surfaces are rigid. Pages 225–239 of: Geometric topology (Proc. Conf. Park City 1974), Lect. Notes Math. vol. 438 Berlin: Springer. (361)CrossRefGoogle Scholar

Goodman, J. E., O’Rourke, J., and Tóth, C. D. (eds). 2017. Handbook of discrete and computational geometry. 3rd ed. Boca Raton, FL: Chapman & Hall/CRC. (110, 272, 353, 393)Google Scholar

Graham, R. L., Knuth, D. E., and Patashnik, O. 1994. Concrete mathematics: A foundation for computer science. 2nd ed. New York: Addison-Wesley. (375)Google Scholar

Graver, J. E. 2001. Counting on frameworks: Mathematics to aid the design of rigid structures. Vol. 25 of The Dolciani Mathematical Expositions, Washington, DC: Mathematical Association of America. (392)CrossRefGoogle Scholar

Graver, J., Servatius, B., and Servatius, H. 1993. Combinatorial rigidity. Providence, RI: American Mathematical Society. (392)CrossRefGoogle Scholar

Gruber, P. M. 2007. Convex and discrete geometry. Grundlehren der Mathematischen Wissenschaften [Fundamental Principles of Mathematical Sciences], vol. 336. Berlin: Springer. (x, 128, 154)Google Scholar

Grünbaum, B. 1963. Unambiguous polyhedral graphs. Isr. J. Math., 1, 235–238. (101, 102, 104, 153)CrossRefGoogle Scholar

Grünbaum, B. 1965. On the facial structure of convex polytopes. Bull. Am. Math. Soc., 71, 559–560. (220, 230)CrossRefGoogle Scholar

Grünbaum, B. 1969. Imbeddings of simplicial complexes. Comment. Math. Helv., 44, 502–513. (225)CrossRefGoogle Scholar

Grünbaum, B. 2003. Convex polytopes. 2nd ed. Graduate Texts in Mathematics, vol. 221. New York: Springer-Verlag. (x, 101, 102, 131, 133, 135, 136, 142, 151, 153, 154, 212, 218, 220, 228, 230, 256, 257, 258, 272, 303, 320, 340, 341, 344, 378, 395)CrossRefGoogle Scholar

Grünbaum, B., and Shephard, G. C. 1987. Some problems on polyhedra. J. Geom., 29, 182–189. (214)CrossRefGoogle Scholar

Haase, C., and Ziegler, G. M. 2002. Examples and counterexamples for the Perles conjecture. Discrete Comput. Geom., 28(1), 29–44. (271)CrossRefGoogle Scholar

Halin, R. 1966. Zu einem Problem von B. Grünbaum. Arch. Math., 17, 566–568. (220, 228, 395)CrossRefGoogle Scholar

Halin, R. 1969. A theorem on n-connected graphs. J. Comb. Theory, 7, 150–154. (413)CrossRefGoogle Scholar

Halmos, P. R. 1974. Finite-dimensional vector spaces. 2nd ed. New York: Springer-Verlag. (42)CrossRefGoogle Scholar

Helly, Ed. 1923. Über Mengen konvexer Körper mit gemeinschaftlichen Punkten. Jahresber. Dtsch. Math.-Ver., 32, 175–176. (42)Google Scholar

Hirata, T., Kubota, K., and Saito, O. 1984. A sufficient condition for a graph to be weakly k-linked. J. Comb. Theory, Ser. B, 36(1), 85–94. (255)CrossRefGoogle Scholar

Hodge, W. V. D., and Pedoe, D. 1994. Methods of algebraic geometry (Cambridge Mathematical Library). Cambridge: Cambridge University Press. (10)CrossRefGoogle Scholar

Hoffman, A. J., and Kruskal, J. G. 1956. Integral boundary points of convex polyhedra. Ann. Math. Stud., 38, 223–246. (58)Google Scholar

Holmes, B. 2018. On the diameter of dual graphs of Stanley-Reisner rings and Hirsch type bounds on abstractions of polytopes. Electron. J. Comb., 25(1), P1.60. (339)CrossRefGoogle Scholar

Holt, F., and Klee, V. 1999. A proof of the strict monotone 4-step conjecture. Pages 201–216 of: Advances in discrete and computational geometry (Prof. Conf. 1996 AMS-IMS-SIAM South Hadley, MA, 1996). Contemp. Math., vol. 223. Providence, RI: Amer. Math. Soc. (253)Google Scholar

Holt, F. B., and Klee, V. 1998. Many polytopes meeting the conjectured Hirsch bound. Discrete Comput. Geom., 20(1), 1–17. (332, 339)CrossRefGoogle Scholar

Hopcroft, J. E., and Kahn, P. J. 1992. A paradigm for robust geometric algorithms. Algorithmica, 7(4), 339–380. (211, 230)CrossRefGoogle Scholar

Höppner, A., and Ziegler, G. M. 2000. A census of flag-vectors of 4-polytopes. Pages 105–110 of: Kalai, G., Ziegler, G.M. (eds) Polytopes—Combinatorics and computation. DMV Sem., vol. 29. Basel: Birkhäuser. (343)CrossRefGoogle Scholar

Huck, A. 1991. A sufficient condition for graphs to be weakly k-linked. Graphs Comb., 7(4), 323–351. (250, 251)CrossRefGoogle Scholar

Ishizeki, T., and Takeuchi, F. 1999. Geometric shellings of 3-polytopes. Pages 132–135 of: Proc. 11th Canadian Conference on Computational Geometry. (175)Google Scholar

Izmestiev, I. 2009. Projective background of the infinitesimal rigidity of frameworks. Geom. Dedicata, 140, 183–203. (363)CrossRefGoogle Scholar

Jänich, K. 1984. Topology. Undergraduate Texts in Mathematics. New York: Springer-Verlag. (402)CrossRefGoogle Scholar

Jockusch, W. 1993. The lower and upper bound problems for cubical polytopes. Discrete Comput. Geom., 9(2), 159–163. (391, 399)CrossRefGoogle Scholar

Jordan, C. 1882. Cours d’analyse de l’École Polytechnique. 3 vol. Paris: Gauthier-Villars. (157, 229, 257, 401)Google Scholar

Joswig, M. 2000. Reconstructing a non-simple polytope from its graph. Pages 167–176 of: Kalai, G., Ziegler, G.M. (eds) Polytopes—Combinatorics and computation. DMV Sem., vol. 29. Basel: Birkhäuser. (269, 271)CrossRefGoogle Scholar

Joswig, M. 2002. Projectivities in simplicial complexes and colorings of simple polytopes. Math. Z., 240(2), 243–259. (230)CrossRefGoogle Scholar

Joswig, M., and Ziegler, G. M. 2000. Neighborly cubical polytopes. Discrete Comput. Geom., 24(2–3), 325–344. (391, 399)CrossRefGoogle Scholar

Joswig, M., Kaibel, V., Pfetsch, M. E., and Ziegler, G. M. 2001. Vertex-facet incidences of unbounded polyhedra. Adv. Geom., 1(1), 23–36. (310)CrossRefGoogle Scholar

Joswig, M., Kaibel, V., and Körner, F. 2002. On the k-systems of a simple polytope. Isr. J. Math., 129, 109–117. (226, 269)CrossRefGoogle Scholar

Kaibel, V. 2003. Reconstructing a simple polytope from its graph. Pages 105–118 of: Jünger, M., Reinelt, G., Rinaldi, G. (eds) Combinatorial optimization—Eureka, you shrink! Lecture Notes in Comput. Sci., vol. 2570. Berlin: Springer. (264)CrossRefGoogle Scholar

Kalai, G. 1987. Rigidity and the lower bound theorem. I. Invent. Math., 88(1), 125–151. (340, 350, 373, 374, 385, 389, 392)CrossRefGoogle Scholar

Kalai, G. 1988a. A new basis of polytopes. J. Comb. Theory, Ser. B, 49(2), 191–209. (390)CrossRefGoogle Scholar

Kalai, G. 1988b. A simple way to tell a simple polytope from its graph. J. Comb. Theory, Ser. A, 49(2), 381–383. (171, 256, 272)CrossRefGoogle Scholar

Kalai, G. 1990. On low-dimensional faces that high-dimensional polytopes must have. Combinatorica, 10(3), 271–280. (179, 181, 229, 389)CrossRefGoogle Scholar

Kalai, G. 1992. Upper bounds for the diameter and height of graphs of convex polyhedra. Discrete Comput. Geom., 8(4), 363–372. (335, 336)CrossRefGoogle Scholar

Kalai, G. 1997. Linear programming, the simplex algorithm and simple polytopes. Math. Programming, 79(1–3), 217–233. (306)CrossRefGoogle Scholar

Kalai, G., and Kleitman, D. J. 1992. A quasi-polynomial bound for the diameter of graphs of polyhedra. Bull. Am. Math. Soc., New Ser., 26(2), 315–316. (320, 336)Google Scholar

Kalai, G. (coordinator). 2010. Polymath 3: Polynomial Hirsch conjecture. http://gilkalai.wordpress.com/2010/09/29/polymath-3-polynomial-hirsch-conjecture. (338)Google Scholar

Kallay, M. 1979. Decomposability of convex polytopes. Ph.D. thesis, The Hebrew University of Jerusalem, Jerusalem. (295)Google Scholar

Kallay, M. 1982. Indecomposable polytopes. Isr. J. Math., 41(3), 235–243. (286, 291, 297, 300, 303, 304)CrossRefGoogle Scholar

Kallay, M. 1984. Decomposability of polytopes is a projective invariant. Pages 191–196 of: Convexity and graph theory (Jerusalem, 1981). North-Holland Math. Stud., vol. 87. Amsterdam: North-Holland. (302, 304)Google Scholar

Karavelas, M. I., and Tzanaki, E. 2016a. A geometric approach for the upper bound theorem for Minkowski sums of convex polytopes. Discrete Comput. Geom., 56(4), 966–1017. (277, 304)CrossRefGoogle Scholar

Karavelas, M. I., and Tzanaki, E. 2016b. The maximum number of faces of the Minkowski sum of two convex polytopes. Discrete Comput. Geom., 55, 748–785. (277, 304)CrossRefGoogle Scholar

Karmarkar, N. 1984. A new polynomial-time algorithm for linear programming. Combinatorica, 4, 373–395. (306)CrossRefGoogle Scholar

Kawarabayashi, K., Kostochka, A., and Yu, G. 2006. On sufficient degree conditions for a graph to be k-linked. Comb. Probab. Comput., 15(5), 685–694. (255)CrossRefGoogle Scholar

Kelmans, A. K. 1980. Concept of a vertex in a matroid and 3-connected graphs. J. Graph Theory, 4, 13–19. (182)CrossRefGoogle Scholar

Khachiyan, L. G. 1979. A polynomial algorithm in linear programming. Dokl. Akad. Nauk SSSR, 244, 1093–1096. (52, 306)Google Scholar

Kim, E. D., and Santos, F. 2010a. Companion to “An update on the Hirsch conjecture”. arXiv:0912.4235. (339)Google Scholar

Kim, E. D., and Santos, F. 2010b. An update on the Hirsch conjecture. Jahresber. Dtsch. Math.-Ver., 112(2), 73–98. (339)CrossRefGoogle Scholar

Klee, V. 1964. A combinatorial analogue of Poincaré’s duality theorem. Can. J. Math., 16, 517–531. (131)CrossRefGoogle Scholar

Klee, V. 1964a. Diameters of polyhedral graphs. Can. J. Math., 16, 602–614. (318, 335)Google Scholar

Klee, V. 1964b. On the number of vertices of a convex polytope. Can. J. Math., 16, 701–720. (106, 153, 392)CrossRefGoogle Scholar

Klee, V. 1964c. A property of d-polyhedral graphs. J. Math. Mech., 13, 1039–1042. (253)Google Scholar

Klee, V., and Minty, G. J. 1972. How good is the simplex algorithm? Pages 159–175 of: Inequalities III (Proc. 3rd Symp., Los Angeles 1969). (306)Google Scholar

Klee, V., and Walkup, D. W. 1967. The d-step conjecture for polyhedra of dimension d < 6. Acta Math., 117, 53–78. (305, 306, 307, 308, 310, 311, 312, 317, 320, 335, 338, 339)CrossRefGoogle Scholar

Kleinschmidt, P., and Onn, S. 1992. On the diameter of convex polytopes. Discrete Math., 102(1), 75–77. (333)CrossRefGoogle Scholar

Koebe, P. 1936. Kontaktprobleme der konformen Abbildung. Ber. Sächs. Akad. Wiss. Leipzig, Math.-phys. Kl. 88, 141–164. (212)Google Scholar

König, D. 1936. Theorie der endlichen und unendlichen Graphen. Kombinatorische Topologie der Streckenkomplexe. XI + 258 S. Leipzig, Akademische Verlagsge-sellschaft (Mathematik in Monographien, Bd. 16). (410)Google Scholar

Krein, M., and Milman, D. 1940. On extreme points of regular convex sets. Stud. Math., 9, 133–138. (43)CrossRefGoogle Scholar

Kriesell, M. 2002. A survey on contractible edges in graphs of a prescribed vertex connectivity. Graphs Comb., 18(1), 1–30. (427)CrossRefGoogle Scholar

Kuratowski, K. 1930. Sur le probleme des courbes gauches en topologie. Fundam. Math., 15, 271–283. (403, 423)CrossRefGoogle Scholar

Kusunoki, T., and Murai, S. 2019. The numbers of edges of 5-polytopes with a given number of vertices. Ann. Comb., 23(1), 89–101. (343)CrossRefGoogle Scholar

Larman, D. G. 1970. Paths on polytopes. Proc. Lond. Math. Soc., 20, 161–178. (327, 336)CrossRefGoogle Scholar

Larman, D. G., and Mani, P. 1970. On the existence of certain configurations within graphs and the 1-skeletons of polytopes. Proc. London Math. Soc., 20, 144–160. (220, 226, 228, 229, 231, 245, 247, 249, 254, 255, 395)CrossRefGoogle Scholar

Lauritzen, N. 2013. Undergraduate convexity: From Fourier and Motzkin to Kuhn and Tucker. Hackensack, NJ: World Scientific Publishing. (38, 42, 152)CrossRefGoogle Scholar

Lebesgue, H. 1911. Sur l’invariance du nombre de dimensions d’un espace et sur le théorème de M. Jordan relatif aux variétés formées. C. R. Acad. Sci., Paris, 152, 841–843. (401)Google Scholar

Lee, C. W. 1991. Regular triangulations of convex polytopes. Pages 443–456 of: Gritzmann, P. and Sturmfels, B. (eds) Applied geometry and discrete mathematics: The Victor Klee Festschrift. DIMACS Ser. Discrete Math. Theoret. Comput. Sci., vol. 4. (111, 153)Google Scholar

Lee, C. W. 2013. Polytopes: Course notes. www.ms.uky.edu/~lee/ma714fa13/notes.pdf. (392)Google Scholar

Ling, J. M. 2007. New Non-Linear Inequalities for Flag-Vectors of 4-Polytopes. Discrete Comput. Geom., 37(3), 455–469. (388, 390)CrossRefGoogle Scholar

Liu, G. Z. 1990. Proof of a conjecture on matroid base graphs. Sci. China Ser. A, 33, 1329–1337. (426)Google Scholar

Lockeberg, E. R. 1977. Refinements in boundary complexes of polytopes. Ph.D. thesis, University College London. (227, 228, 230, 253, 395, 396)Google Scholar

Lovász, L. 2007. Combinatorial problems and exercises. 2nd ed. Providence, RI: AMS Chelsea Publishing. (415)Google Scholar

Lovász, L. 2019. Graphs and geometry. Providence, RI: Colloquium Publications. (194, 211, 212, 214, 230, 361, 362, 371, 392)CrossRefGoogle Scholar

Lutz, F. H. 2004. Small examples of nonconstructible simplicial balls and spheres. SIAM J. Discrete Math., 18(1), 103–109. (393)CrossRefGoogle Scholar

Lutz, F. H. 2008. Combinatorial 3-manifolds with 10 vertices. Beitr. Algebra Geom., 49(1), 97–106. (393)Google Scholar

MacLane, S. 1937. A combinatorial condition for planar graphs. Fundam. Math., 28, 22–32. (181, 182)CrossRefGoogle Scholar

Mader, W. 1971. Minimale n-fach kantenzusammenhängende Graphen. Math. Ann., 191, 21–28. (415)CrossRefGoogle Scholar

Mader, W. 1974. Kantendisjunkte Wege in Graphen. Monatsh. Math., 78, 395–404. (415)CrossRefGoogle Scholar

Mader, W. 1985. Paths in graphs, reducing the edge-connectivity only by two. Graphs Comb., 1(1), 81–89. (426)CrossRefGoogle Scholar

Mader, W. 1986. Kritisch n-fach kantenzusammenhängende Graphen. (Critically n-edge-connected graphs). J. Comb. Theory, Ser. B, 40, 152–158. (415)CrossRefGoogle Scholar

Mader, W. 1995. On vertices of degree n in minimally n-edge-connected graphs. Comb. Probab. Comput., 4(1), 81–95. (415)CrossRefGoogle Scholar

Maharry, J. 1999. An excluded minor theorem for the octahedron. J. Graph Theory, 31(2), 95–100. (221, 228, 230, 395)3.0.CO;2-N>CrossRefGoogle Scholar

Maharry, J. 2000. A characterization of graphs with no cube minor. J. Comb. Theory, Ser. B, 80(2), 179–201. (221, 230)CrossRefGoogle Scholar

Maksimenko, A. M. 2009. The diameter of the ridge-graph of a cyclic polytope. Discrete Math. Appl., 19(1), 47–53. (335)CrossRefGoogle Scholar

Marden, A., and Rodin, B. 1990. On Thurston’s formulation and proof of Andreev’s theorem. Pages 103–115 of: Ruscheweyh, S., Saff, E. B., Salinas, L. C., and Varga, R. S. (eds), Computational methods and function theory (Proc. Conf., Valparaíso/Chile 1989). Lect. Notes Math., vol. 1435. Berlin: Springer. (212)CrossRefGoogle Scholar

Matoušek, J. 2002. Lectures on discrete geometry. Graduate Texts in Mathematics, vol. 212. New York: Springer-Verlag. (153)CrossRefGoogle Scholar

Matoušek, J. 2003. Using the Borsuk-Ulam theorem. Berlin: Springer-Verlag. (225)Google Scholar

Matschke, B., Santos, F., and Weibel, C. 2015. The width of five-dimensional prismatoids. Proc. Lond. Math. Soc., 110(3), 647–672. (331, 332)CrossRefGoogle Scholar

Maxwell, J. C. 1864. XLV. On reciprocal figures and diagrams of forces. Philos. Mag, 27(182), 250–261. (198)CrossRefGoogle Scholar

Maxwell, J. C. 1869. On reciprocal figures, frams, and diagrams of forces. Trans. R. Soc. Edinb., 26, 1–40. (198)CrossRefGoogle Scholar

McMullen, P. 1970. The maximum numbers of faces of a convex polytope. Mathematika, 17, 179–184. (94, 153, 302, 340, 374, 375, 378, 393, 397)Google Scholar

McMullen, P. 1971a. The minimum number of facets of a convex polytope. J. Lond. Math. Soc., 3, 350–354. (347)CrossRefGoogle Scholar

McMullen, P. 1971b. The numbers of faces of simplicial polytopes. Isr. J. Math., 9, 559–570. (340, 377, 378)CrossRefGoogle Scholar

McMullen, P. 1976. Constructions for projectively unique polytopes. Discrete Math., 14(4), 347–358. (150, 152)CrossRefGoogle Scholar

McMullen, P. 1987. Indecomposable convex polytopes. Isr. J. Math., 58(3), 321–323. (289, 292, 304)Google Scholar

McMullen, P. 1993. On simple polytopes. Invent. Math., 113(2), 419–444. (393)CrossRefGoogle Scholar

McMullen, P., and Shephard, G. C. 1971. Convex polytopes and the upper bound conjecture. London: Cambridge University Press. (141, 142, 153, 154)CrossRefGoogle Scholar

McMullen, P., and Walkup, D. W. 1971. A generalized lower-bound conjecture for simplicial polytopes. Mathematika, 18, 264–273. (372, 374)CrossRefGoogle Scholar

Menger, K. 1927. Zur allgemeinen Kurventheorie. Fundam. Math., 10(1), 96–115. (403, 415)CrossRefGoogle Scholar

Mészáros, G. 2015. Linkedness and path-pairability in the Cartesian product of graphs. Ph.D. thesis, Central European University. (253)Google Scholar

Mészáros, G. 2016. On linkedness in the Cartesian product of graphs. Period. Math. Hung., 72(2), 130–138. (253)CrossRefGoogle Scholar

Meyer, W., and Kay, D. C. 1973. A convexity structure admits but one real linearization of dimension greater than one. J. Lond. Math. Soc., II. Ser., 7, 124–130. (22)CrossRefGoogle Scholar

Meyer, W. J. 1969. Minkowski addition of convex sets. Ph.D. thesis, The University of Wisconsin. (297, 300, 301, 304)Google Scholar

Mihalisin, J., and Klee, V. 2000. Convex and linear orientations of polytopal graphs. Discrete Comput. Geom., 24(2–3), 421–435. (174)CrossRefGoogle Scholar

Minkowski, H. 1896. Geometrie der zahlen. Leipzig: Teubner. (43, 152)Google Scholar

Minkowski, H. 1911. Gesammelte Abhandlungen von Hermann Minkowski. Unter Mitwirkung von Andreas Speiser und Hermann Weyl, herausgegeben von David Hilbert. Band I, II. Leipzig: Teubner. (43)Google Scholar

Mohar, B. 1993. A polynomial time circle packing algorithm. Discrete Math., 117(1), 257–263. (214)CrossRefGoogle Scholar

Mohar, B., and Thomassen, C. 2001. Graphs on surfaces. Baltimore, MD: Johns Hopkins University Press. (157, 158, 182, 212, 214, 229, 230)CrossRefGoogle Scholar

Morris, S. A. 2020. Topology without tears. www.topologywithouttears.net/topbook.pdf. (402)Google Scholar

Motzkin, T. 1935. Sur quelques propriétés caractéristiques des ensembles convexes. Atti Accad. Naz. Lincei, Rend., VI. Ser., 21, 562–567. (43)Google Scholar

Motzkin, T. 1936. Beiträge zur Theorie der linearen Ungleichungen. Thesis, University of Basel. (46, 152)Google Scholar

Motzkin, T. S. 1957. Comonotone curves and polyhedra. Bull. Am. Math. Soc., 63. (374)Google Scholar

Mulmuley, K. 1993. Computational geometry: An introduction through randomized algorithms. Englewood Cliffs, NJ: Prentice Hall. (393)Google Scholar

Murai, S., and Nevo, E. 2013. On the generalized lower bound conjecture for polytopes and spheres. Acta Math., 210(1), 185–202. (374)CrossRefGoogle Scholar

Naddef, D. 1989. The Hirsch conjecture is true for (0,1)-polytopes. Math. Program., 45, 109–110. (333)CrossRefGoogle Scholar

Nevo, E. 2022. Private Communication. (258)Google Scholar

Nevo, E., Pineda-Villavicencio, G., Ugon, J., and Yost, D. 2019. Almost simplicial polytopes I. The lower and upper bound theorems. Can. J. Math., 72(2). (393)Google Scholar

Okamura, H. 1984. Multicommodity flows in graphs. II. Jpn. J. Math., New Ser., 10(1), 99–116. (255)CrossRefGoogle Scholar

Pach, J., and Agarwal, P. K. 1995. Combinatorial geometry. New York: John Wiley & Sons. (212)CrossRefGoogle Scholar

Pak, I. 2010. Lectures on discrete and polyhedral geometry. www.math.ucla.edu/~pak/book.htm. (392)Google Scholar

Papadakis, S. A., and Petrotou, V. 2020. The characteristic 2 anisotropicity of simplicial spheres. arXiv:2012.09815. (393)Google Scholar

Perles, M. A., and Prabhu, N. 1993. A property of graphs of convex polytopes. J. Comb. Theory, Ser. A, 62(1), 155–157. (235, 252)CrossRefGoogle Scholar

Perles, M. A., and Shephard, G. C. 1967. Facets and nonfacets of convex polytopes. Acta Math., 119, 113–145. (389, 391, 399)CrossRefGoogle Scholar

Perles, M. A., Martini, H., and Kupitz, Y. S. 2009. A Jordan–Brouwer separation theorem for polyhedral pseudomanifolds. Discrete Comput. Geom., 42(2), 277–304. (402)CrossRefGoogle Scholar

Pestenjak, B. 1999. An algorithm for drawing planar graphs. Softw. Pract. Exper., 29(11), 973–984. (207)Google Scholar

Pfeifle, J., Pilaud, V., and Santos, F. 2012. Polytopality and Cartesian products of graphs. Isr. J. Math., 192(1), 121–141. (272)CrossRefGoogle Scholar

Pilaud, V., Pineda-Villavicencio, G., and Ugon, J. 2023. Edge connectivity of simplicial polytopes. Eur. J. Comb., 113, 103752. (231, 236, 237)CrossRefGoogle Scholar

Pineda-Villavicencio, G. 2021. A new proof of Balinski’s theorem on the connectivity of polytopes. Discrete Math., 344, 112408. (254, 427)CrossRefGoogle Scholar

Pineda-Villavicencio, G. 2022. Cycle space of graphs of polytopes. arXiv:2208.02579. (229)Google Scholar

Pineda-Villavicencio, G., and Schröter, B. 2022. Reconstructibility of matroid polytopes. SIAM J. Discrete Math., 36(1), 490–508. (269)CrossRefGoogle Scholar

Pineda-Villavicencio, G., and Ugon, J. 2018. Polymake script to construct polytopes with isomorphic skeletons. http://guillermo.com.au/pdfs/ConstructPolytope-A.txt. (263)Google Scholar

Pineda-Villavicencio, G., and Yost, D. 2022. A lower bound theorem for d-polytopes with 2d +1 vertices. SIAM J. Discrete Math., 36, 2920–2941. (168, 350, 391, 399)CrossRefGoogle Scholar

Pineda-Villavicencio, G., Ugon, J., and Yost, D. 2018. The excess degree of a polytope. SIAM J. Discrete Math., 32(3), 2011–2046. (168, 169, 229, 296, 304, 343)CrossRefGoogle Scholar

Pineda-Villavicencio, G., Ugon, J., and Yost, D. 2019. Lower bound theorems for general polytopes. Eur. J. Comb., 79, 27–45. (344)Google Scholar

Pineda-Villavicencio, G., Ugon, J., and Bui, H. T. 2020a. Connectivity of cubical polytopes. J. Combin. Theory Ser. A, 169, 105–126. (254)Google Scholar

Pineda-Villavicencio, G., Ugon, J., and Yost, D. 2020b. Polytopes close to being simple. Discrete Comput. Geom., 64, 200–215. (270)CrossRefGoogle Scholar

Pineda-Villavicencio, G., Ugon, J., and Yost, D. 2022. Minimum number of edges of d-polytopes with 2d +2 vertices. Electron. J. Comb., 29(3), P3.18. (168, 350, 391, 399)CrossRefGoogle Scholar

Pisanski, T., and Žitnik, A. 2009. Representing graphs and maps. Pages 151–180 of: Gross, J., and Tucker, T. (authors) and Beineke, L., and Wilson, R. (eds), Topics in topological graph theory. Cambridge: Cambridge University Press. (207)CrossRefGoogle Scholar

Poincaré, H. 1893. Sur la généralisation d’un théorème d’Euler relatif aux polyèdres. C. R. Acad. Sci., Paris, 117, 144–145. (128)Google Scholar

Preparata, F. P., and Shamos, M. I. 1985. Computational geometry: An introduction. Berlin, Heidelberg: Springer-Verlag. (153)CrossRefGoogle Scholar

Przesławski, K., and Yost, D. 2008. Decomposability of polytopes. Discrete Comput. Geom., 39(1–3), 460–468. (303, 304)CrossRefGoogle Scholar

Przesławski, K., and Yost, D. 2016. More indecomposable polytopes. Extr. Math., 31, 169–188. (290, 295, 298, 303, 304)Google Scholar

Radon, J. 1921. Mengen konvexer Körper, die einen gemeinsamen Punkt enthalten. Math. Ann., 83, 113–115. (20, 42)CrossRefGoogle Scholar

Reid, M., and Szendroi, B. 2005. Geometry and topology. Cambridge: Cambridge University Press. (42)CrossRefGoogle Scholar

Ribó Mor, A., Rote, G., and Schulz, A. 2011. Small grid embeddings of 3-polytopes. Discrete Comput. Geom., 45(1), 65–87. (211)CrossRefGoogle Scholar

Richter-Gebert, J. 2006. Realization spaces of polytopes. Berlin: Springer. (64, 197, 211, 228, 230, 395)Google Scholar

Robertson, N., and Seymour, P. D. 1995. Graph minors. XIII. The disjoint paths problem. J. Comb. Theory, Ser. B, 63(1), 65–110. (240)CrossRefGoogle Scholar

Roshchina, V., Sang, T., and Yost, D. 2018. Compact convex sets with prescribed facial dimensions. Pages 167–175 of: de Gier, J., Praeger, C. E., and Tao, T. (eds), 2016 MATRIX Annals. Cham: Springer. (33)CrossRefGoogle Scholar

Roth, B. 1981. Rigid and flexible frameworks. Am. Math. Mon., 88(1), 6–21. (364, 392)CrossRefGoogle Scholar

Rowlands, R. 2022. Reconstructing d-manifold subcomplexes of cubes from their (d{2 + 1)-skeletons. Discrete Comput. Geom., 67, 492–502. (263)CrossRefGoogle Scholar

Sachs, H. 1994. Coin graphs, polyhedra, and conformal mapping. Discrete Math., 134(1), 133–138. (212, 230)CrossRefGoogle Scholar

Sallee, G. T. 1967. Incidence graphs of convex polytopes. J. Combinatorial Theory, 2, 466–506. (161, 166, 229, 238, 251, 252)CrossRefGoogle Scholar

Santos, F. 2012. A counterexample to the Hirsch conjecture. Ann. Math., 176(1), 383–412. (107, 108, 153, 305, 306, 328, 329, 331, 332, 339)CrossRefGoogle Scholar

Santos, F. 2013. Recent progress on the combinatorial diameter of polytopes and simplicial complexes. Top, 21(3), 426–460. (335, 336, 337, 338, 339)CrossRefGoogle Scholar

Santos, F., Stephen, T., and Thomas, H. 2012. Embedding a pair of graphs in a surface, and the width of 4-dimensional prismatoids. Discrete Comput. Geom., 47(3), 569–576. (331)CrossRefGoogle Scholar

Sanyal, R., and Ziegler, G. M. 2010. Construction and analysis of projected deformed products. Discrete Comput. Geom., 43(2), 412–435. (263)CrossRefGoogle Scholar

Sarkaria, K. S. 1991. Kuratowski complexes. Topology, 30(1), 67–76. (225)CrossRefGoogle Scholar

Schild, G. 1993. Some minimal nonembeddable complexes. Topology Appl., 53(2), 177–185. (225)CrossRefGoogle Scholar

Schläfli, L. (1901) 1850–52. Theorie der vielfachen Kontinuität. Vol. 38. Basel: Birkhäuser. (128)CrossRefGoogle Scholar

Schlegel, V. 1883. Theorie der homogen zusammengesetzten Raumgebilde (On the theory of homogeneous composed space forms). Nova Acta, 44, 343–459. (153)Google Scholar

Schneider, R. 2014. Convex bodies: The Brunn-Minkowski theory. 2nd ed. Vol. 151. Cambridge: Cambridge University Press. (278, 303)Google Scholar

Schramm, O. 1992. How to cage an egg. Invent. Math., 107(3), 543–560. (230)CrossRefGoogle Scholar

Schrijver, A. 1986. Theory of linear and integer programming. New York: John Wiley & Sons. (152)Google Scholar

Seymour, P. D. 1980. Disjoint paths in graphs. Discrete Math., 29(3), 293–309. (240)CrossRefGoogle Scholar

Shemer, I. 1982. Neighborly polytopes. Isr. J. Math., 43(4), 291–314. (263)Google Scholar

Shephard, G. C. 1963. Decomposable convex polyhedra. Mathematika, 10, 89–95. (278, 293, 300, 304)CrossRefGoogle Scholar

Shifrin, T., and Adams, M. 2011. Linear algebra: A geometric approach. 2nd ed. New York: W. H. Freeman. (42)Google Scholar

Silverman, R. 1973. Decomposition of plane convex sets. I. Pac. J. Math., 47, 521–530. (278, 289)CrossRefGoogle Scholar

Smilansky, Z. 1986a. Decomposability of polytopes and polyhedra. Ph.D. thesis, Hebrew University of Jerusalem. (297, 301)Google Scholar

Smilansky, Z. 1986b. An indecomposable polytope all of whose facets are decomposable. Mathematika, 33(2), 192–196. (301, 303, 397)CrossRefGoogle Scholar

Smilansky, Z. 1987. Decomposability of polytopes and polyhedra. Geom. Dedicata, 24(1), 29–49. (292, 300, 301, 302, 304, 397)CrossRefGoogle Scholar

Smilansky, Z. 1990. A nongeometric shelling of a 3-polytope. Isr. J. Math., 71(1), 29–32. (175)CrossRefGoogle Scholar

Soltan, V. 2015. Lectures on convex sets. Hackensack: World Scientific. (42)CrossRefGoogle Scholar

Sommerville, D. M. Y. 1927. The relations connecting the angle-sums and volume of a polytope in space of n dimensions. Proc. R. Soc. Lond., A, 115(770), 103–119. (131)Google Scholar

Sommerville, D. M. Y. 1958. An introduction to the geometry of n dimensions. New York: Dover Publications. (153)Google Scholar

Spielman, D. A. 2019. Spectral and algebraic graph theory. http://cs-www.cs.yale.edu/homes/spielman/sagt/sagt.pdf. (194, 230)Google Scholar

Stanley, R. P. 1975. The upper bound conjecture and Cohen-Macaulay rings. Stud. Appl. Math., 54, 135–142. (393)CrossRefGoogle Scholar

Stanley, R. P. 1980. The number of faces of a simplicial convex polytope. Adv. Math., 35, 236–238. (378, 393)CrossRefGoogle Scholar

Stanley, R. P. 1996. Combinatorics and commutative algebra. 2nd ed. Progress in Mathematics, vol. 41. Boston, MA: Birkhäuser. (393)Google Scholar

Steinitz, E. 1906. Über die Eulerschen Polyederrelationen. Arch. der Math. u. Phys., 11, 86–88. (340, 341)Google Scholar

Steinitz, E. 1922. Polyeder und raumeinteilungen. Encyclop. d. math. Wiss., 3, 1–139. (198, 211)Google Scholar

Sturmfels, B. 1987. Cyclic polytopes and d-order curves. Geom. Dedicata, 24(1), 103–107. (100)CrossRefGoogle Scholar

Sturmfels, B. 1988. Some applications of affine Gale diagrams to polytopes with few vertices. SIAM J. Discrete Math., 1(1), 121–133. (145, 212)CrossRefGoogle Scholar

Sturmfels, B. 1996. Gröbner bases and convex polytopes. Vol. 8. Providence, RI: American Mathematical Society. (110)Google Scholar

Sukegawa, N. 2019. An asymptotically improved upper bound on the diameter of polyhedra. Discrete Comput. Geom., 62(3), 690–699. (323)CrossRefGoogle Scholar

Tay, T.-S. 1995. Lower-bound theorems for pseudomanifolds. Discrete Comput. Geom., 13(2), 203–216. (374)CrossRefGoogle Scholar

Thomas, R., and Wollan, P. 2005. An improved linear edge bound for graph linkages. Eur. J. Comb., 26(3–4), 309–324. (249, 255)CrossRefGoogle Scholar

Thomas, R., and Wollan, P. 2008. The extremal function for 3-linked graphs. J. Comb. Theory, Ser. B, 98(5), 939–971. (254, 396)CrossRefGoogle Scholar

Thomassen, C. 1980a. 2-linked graphs. Eur. J. Comb., 1(4), 371–378. (240, 249, 250, 254, 396, 412, 427)CrossRefGoogle Scholar

Thomassen, C. 1980b. Planarity and duality of finite and infinite graphs. J. Comb. Theory, Ser. B, 29(2), 244–271. (423)CrossRefGoogle Scholar

Thomassen, C. 1981. Nonseparating cycles in k-connected graphs. J. Graph Theory, 5, 351–354. (426)CrossRefGoogle Scholar

Thurston, W. P. 1980. The geometry and topology of three-manifolds. Lecture notes at Princeton University, http://library.msri.org/books/gt3m/PDF/Thurston-gt3m.pdf. (212)Google Scholar

Timan, A. F. 1963. Theory of approximation of functions of a real variable. New York: Pergamon Press. (100)Google Scholar

Todd, M. J. 1980. The monotonic bounded Hirsch conjecture is false for dimension at least 4. Math. Oper. Res., 5, 599–601. (307, 309, 310)CrossRefGoogle Scholar

Todd, M. J. 2002. The many facets of linear programming. Math. Program., 91(3), 417–436. (306)CrossRefGoogle Scholar

Todd, M. J. 2014. An improved Kalai-Kleitman bound for the diameter of a polyhedron,. SIAM J. Discrete Math., 28, 1944–1947. (319, 320, 322, 339)CrossRefGoogle Scholar

Tutte, W. T. 1963. How to draw a graph. Proc. Lond. Math. Soc., 13, 743–768. (155, 164, 165, 182, 184, 186, 214, 230)CrossRefGoogle Scholar

Tverberg, H. 1966. A generalization of Radon’s theorem. J. Lond. Math. Soc., 41, 123–128. (42)CrossRefGoogle Scholar

Van Kampen, E. R. 1932. Komplexe in euklidischen Räumen. Abh. Math. Semin. Univ. Hamb., 9, 72–78. (155, 225)CrossRefGoogle Scholar

Wagner, K. 1937. Über eine Eigenschaft der ebenen Komplexe. Math. Ann., 114, 570–590. (423)CrossRefGoogle Scholar

Walkup, D. W. 1970. The lower bound conjecture for 3- and 4-manifolds. Acta Math., 125, 75–107. (372)CrossRefGoogle Scholar

Webster, R. 1994. Convexity. New York: Oxford University Press. (xi, 3, 20, 21, 23, 24, 25, 27, 28, 32, 35, 37, 38, 42, 130, 140, 141, 144, 152, 153, 154, 229, 402)CrossRefGoogle Scholar

Werner, A., and Wotzlaw, R. F. 2011. On linkages in polytope graphs. Adv. Geom., 11(3), 411–427. (231, 245, 249, 254, 255, 396)CrossRefGoogle Scholar

West, D. B. 2001. Introduction to graph theory. 2nd ed. Upper Saddle River, NJ: Prentice Hall. (414, 427)Google Scholar

Weyl, H. 1935. Elementare theorie der konvexen polyeder. Comment. Math. Helv., 7, 290–306. (152)CrossRefGoogle Scholar

Whiteley, W. 1984. Infinitesimally rigid polyhedra. I. Statics of frameworks. Trans. Amer. Math. Soc., 285(2), 431–465. (367, 370)CrossRefGoogle Scholar

Whiteley, W. 1992. Matroids and rigid structures. Pages 1–53 of: White, N. (ed), Matroid Applications (Encyclopedia of Mathematics and its Applications). Cambridge: Cambridge University Press. (392)Google Scholar

Whiteley, W. 1996. Some matroids from discrete applied geometry. Pages 171–311 of: Matroid theory (Seattle, WA, 1995). Contemp. Math., vol. 197. Providence, RI: Amer. Math. Soc. (388)Google Scholar

Whitney, H. 1932. Congruent graphs and the connectivity of graphs. Am. J. Math., 54(1), 150–168. (414, 417, 426)CrossRefGoogle Scholar

Whitney, H. 1932. Non-separable and planar graphs. Trans. Am. Math. Soc., 34, 339–362. (403, 423, 424)CrossRefGoogle Scholar

Whitney, H. 1933. 2-isomorphic graphs. Am. J. Math., 55, 245–254. (164)CrossRefGoogle Scholar

Williamson Hoke, K. 1988. Completely unimodal numberings of a simple polytope. Discrete Appl. Math., 20(1), 69–81. (226)CrossRefGoogle Scholar

Wotzlaw, R. F. 2009. Incidence graphs and unneighborly polytopes. Ph.D. thesis, Technical University of Berlin. (230, 252)Google Scholar

Xue, L. 2021. A proof of Grünbaum’s lower bound conjecture for general polytopes. Isr. J. Math., 245, 991–1000. (340, 344, 392)CrossRefGoogle Scholar

Xue, L. 2022. A lower bound theorem for strongly regular CW spheres up to 2d + 1. arXiv:2207.13839. (350, 388)CrossRefGoogle Scholar

Yaglom, I. M. 1973. Geometric transformations III: Affine and projective transformations. New York: Random House. (153)CrossRefGoogle Scholar

Yang, Y. 2021. A note on the diameter of convex polytope. Discrete Appl. Math., 289, 534–538. (335)CrossRefGoogle Scholar

Yost, D. 2007. Some indecomposable polyhedra. Optimization, 56(5–6), 715–724. (303)CrossRefGoogle Scholar

Ziegler, G. M. 1995. Lectures on polytopes. Graduate Texts in Mathematics, vol. 152. New York: Springer-Verlag. (x, 46, 50, 74, 75, 102, 114, 123, 134, 136, 149, 152, 153, 154, 174, 212, 229, 303, 331, 338, 393, 394)CrossRefGoogle Scholar

Ziegler, G. M. 2000. Lectures on 0{1-polytopes. Pages 1–41 of: Kalai, G., Ziegler, G.M. (eds) Polytopes—Combinatorics and computation. DMV Sem., vol. 29. Basel: Birkhäuser. (333)Google Scholar

Ziegler, G. M. 2007. Convex polytopes: extremal constructions and f -vector shapes. Pages 617–691 of: Miller, E., Reiner, V., and Sturmfels, B. (eds), Geometric combinatorics. IAS/Park City Math. Ser., vol. 13. Providence, RI: Amer. Math. Soc. (211)CrossRefGoogle Scholar