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Nonlinear methods in discrete optimization László Lovász Eötvös Loránd University, Budapest lovasz@cs.elte.hu
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planar graph Fáry-Wagner Every simple planar graph can be drawn in the plane with straight edges Exercise 1: Prove this.
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Rubber bands and planarity Every 3-connected planar graph can be drawn with straight edges and convex faces. Tutte (1963)
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Rubber bands and planarity outer face fixed to convex polygon edges replaced by rubber bands Energy: Equilibrium:
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G 3-connected planar rubber band embedding is planar Exercise 2. (a) Let L be a line intersecting the outer polygon P, and let U be the set of nodes of G that fall on a given (open) side of L. Then U induces a connected subgraph of G. (b) There cannot exists a node and a line such that the node and all its neighbors fall on this line. (c) Let ab be an edge that is not an edge of P, and let F and F’ be the two faces incident with ab. Prove that all the other nodes of F fall on one side of the line through this edge, and all the other nodes of F’ are mapped on the other side. (d) Prove the theorem above. Tutte
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Discrete Riemann Mapping Theorem Coin representation Koebe (1936) Every planar graph can be represented by touching circles
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Can this be obtained from a rubber band representation? Tutte representation optimal circles Want: Minimize: Optimum satisfies i:
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Rubber bands and strengths rubber bands have strengths c ij > 0 Energy: Equilibrium:
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Update strengths: The procedure converges to an equilibrium, where Exercise 3. The edges of a simple planar map are 2-colored with red and blue. Prove that there is always a node where the red edges (and so also the blue edges) are consecutive.
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There is a node where “too strong” edges (and “too weak” edges) are consecutive.
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A direct optimization proof [Colin de Verdiere] Variables: Set log radii of circles representing nodes log radii of circles inscribed in facets minimize p i From any Tutte representation
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Polar polytope
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Blocking polyhedra Fulkerson 1970 convex, ascending Exercise 4. Let K be the dominant of the convex hull of edgesets of s-t paths. Prove that the blocker is the dominant of the convex hull of edge-sets of s-t cuts.
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Energy convex, ascending (recessive)
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x : shortest vector in K x *: shortest vector in K *
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Generalized energy convex, ascending (recessive)
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Exercise 5. Prove these inequalities. Also prove that they are sharp. x : shortest vector in K x *: shortest vector in K *
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Example 1. Example 2. s-t flows of value 1 and “everything above” electrical resistance between nodes s and t
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Example 3 Traffic jams (directed) s t time to cross e ~ traffic through e = x e N N cars from s to t average travel time: (x e ): flow of value 1 from s to t Best average travel time = distance of 0 from the directed flow polytope
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3 3 3 3 2 2 2 5 4 1 10 Brooks-Smith-Stone-Tutte 1940 0 3 4 5 6 7 9 Square tilings I
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3 3 3 3 2 2 2 5 4 1 10
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3 1 4 5 3 9 9 2 2 2 3 3 Square tilings II
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Every triangulation of a quadrilateral can be represented by a square tiling of a rectangle. Schramm
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3 1 4 5 3 9 10 9 2 2 2 3 3
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Every triangulation of a quadrilateral can be represented by a square tiling of a rectangle. Schramm If the triangulation is 5-connected, then the representing squares are non-degeenerate.
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K =convex hull of nodesets of u-v paths + + n u v s t x : shortest vector in K x *: shortest vector in K * x gives lengths of edges of the squares. Exercise 6. The blocker of K is the dominant of the convex hull of s-t paths. Exercise 7. (a) How to get the position of the center of each square? (b) Complete the proof.
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Unit vector flows skew symmetric vector flow Trivial necessary condition: G is 2-edge-connected.
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Conjecture 1. For d=2, every 4-edge-connected graph has a unit vector flow. Conjecture 2. For d=3, every 2-edge-connected graph has a unit vector flow. Theorem. For d=7, every 2-edge-connected graph has a unit vector flow. Jain It suffices to consider 3-edge-connected 3-regular graphs Exercise 8. Prove conjecture 2 for planar graphs.
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[Schramm] unit vector flow?
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Conjecture 2’. Conjecture 2’’. Every 3-regular 3-connected graph can be drawn on the sphere so that every edge is an arc of a large circle, and at every node, any two edges form 120 o. Exercise 9. Conjectures 2' and 2" are equivalent to Conjecture 2.
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Antiblocking polyhedra Fulkerson 1971 convex corner (polarity in the nonnegative orthant)
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The stable set polytope
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Graph entropy Körner 1973 p : probability distribution on V(G)
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connected iff distinguishable Want: encode most of V(G) t by 0-1 words of min length, so that distinguishable words get different codes. (measure of “complexity” of G )
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Csiszár, Körner, Lovász, Marton, Simonyi
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