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How to Cut Pseudoparabolas into Segments Seminar on Geometric Incidences By: Almog Freizeit
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A Reminder 08.12.2014 Seminar on Geometric Incidences 2
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Székely’s method 08.12.2014 Seminar on Geometric Incidences 3
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Our goal We want to apply Székely’s method to circles with arbitrary radii. The problem: the graph is not simple What can we do? We will make the Székely’s graph simple: Cutting into pseudo- segments. Each pair of pseudo-segments intersects at most once, and the resulting graph is guaranteed to be simple. 08.12.2014 Seminar on Geometric Incidences 4
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Our goal Example: Original P and CCutting into pseudo-segmentsThe Székely graph 08.12.2014 Seminar on Geometric Incidences 5
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Our goal 08.12.2014 Seminar on Geometric Incidences 6
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Hisao Tamaki and Takeshi Tokuyama, 1998 The bounds are not tight!! 08.12.2014 Seminar on Geometric Incidences 7
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Terminologies Let Γ be an arrangement of pseudoparabolas. The arrangement subdivides the plane into faces. We use the terms cell, edge and vertex for two-, one- and zero-dimensional respectively. When two pseudoparabolas intersect twice, they form a closed curve, which we call a lens. We say a lens is a 1-lens if no curve crosses the lens. Observation: The cutting number of Γ is not less then the number of 1-lenses 08.12.2014 Seminar on Geometric Incidences 8
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Lower bound 08.12.2014 Seminar on Geometric Incidences 9
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Lower bound Very carefully, we counted the number of incidences in this arrangement and succeeded to prove the desired lower bound. 08.12.2014 Seminar on Geometric Incidences 10
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Lower bound 08.12.2014 Seminar on Geometric Incidences 11
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Lower bound 08.12.2014 Seminar on Geometric Incidences 12
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Lower bound 08.12.2014 Seminar on Geometric Incidences 13
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Lower bound 08.12.2014 Seminar on Geometric Incidences 14
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Lower bound 08.12.2014 Seminar on Geometric Incidences 15
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Upper bound 08.12.2014 Seminar on Geometric Incidences 16
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Some notations about Hypergraphs 08.12.2014 Seminar on Geometric Incidences 17
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Our Hypergraph We define a hypergraph H(Γ)=(X,E): X: the set of edges of the arrangement Γ. E: each hyperedge is a set of nodes which its corresponding set of edges in the arrangement forms a lens. 08.12.2014 Seminar on Geometric Incidences 18
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Computing a covering A greedy algorithm for computing a covering is the following: 1. Find a node of maximum degree 2. Insert the node to the covering, and remove it and all hyperedges containing it. 3. If all hyperedges are covered, EXIT; Else GOTO 1. Lovász showed that the greedy algorithm achieves a covering size at most logd(H)+1 times the size of the covering of H. We neither use nor prove this fact, yet we will use and prove a key inequality from his proof. 08.12.2014 Seminar on Geometric Incidences 20
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Lovász’s Inequality 08.12.2014 Seminar on Geometric Incidences 21
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Lovász’s Inequality 08.12.2014 Seminar on Geometric Incidences 22
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Lovász’s Inequality 08.12.2014 Seminar on Geometric Incidences 23
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So what we had so far? 08.12.2014 Seminar on Geometric Incidences 24
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08.12.2014 Seminar on Geometric Incidences 25 (The graph is undirected)
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08.12.2014 Seminar on Geometric Incidences 28 Upper envelope
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On the other hand, the upper envelope of A(C) has at most 5 edges, and the lower envelope of A(D) has at most 7 edges (board) Let's place those envelopes together on the plane 08.12.2014 Seminar on Geometric Incidences 29
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08.12.2014 Seminar on Geometric Incidences 32 Extremal edges
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08.12.2014 Seminar on Geometric Incidences 33 Near 1-lens
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Upper bound 08.12.2014 Seminar on Geometric Incidences 37
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What about circles? We can obtain these bounds to an arrangement of arbitrary circles as well: We are given an arrangement of n circles. Each pair of circles intersect at most twice, but a circle is not an x- monotone curve Let's cut each circle with its horizontal diameter, and divide it into an upper half-circle and a lower half-circle. Now we connect two vertical downward (resp. upward) rays to an upper (resp. lower) half-circle at its endpoints, and obtain an x- monotone curve separating the plane. It is easy to see that every pair of curves intersects at most twice 08.12.2014 Seminar on Geometric Incidences 38
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What about circles? 08.12.2014 Seminar on Geometric Incidences 39
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Overview 08.12.2014 Seminar on Geometric Incidences 40
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Other results 08.12.2014 Seminar on Geometric Incidences 41
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Terminologies 08.12.2014 Seminar on Geometric Incidences 42
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Terminologies 08.12.2014 Seminar on Geometric Incidences 43
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Bounding the number of lunes 08.12.2014 Seminar on Geometric Incidences 44
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Let's define a graph 08.12.2014 Seminar on Geometric Incidences 45
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Let's define a graph Lemma: G is a planar Proof: we will show that the plane embedding of G defined before has no pair of crossing edges. This will be a special case of the following more general lemma: 08.12.2014 Seminar on Geometric Incidences 46
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G is a planar 08.12.2014 Seminar on Geometric Incidences 47
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G is a planar 08.12.2014 Seminar on Geometric Incidences 48
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Case 1 08.12.2014 Seminar on Geometric Incidences 49
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Case 1 08.12.2014 Seminar on Geometric Incidences 50
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Case 1 08.12.2014 Seminar on Geometric Incidences 51
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Case 2 08.12.2014 Seminar on Geometric Incidences 52
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Case 3 08.12.2014 Seminar on Geometric Incidences 53
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Bounding number of lunes 08.12.2014 Seminar on Geometric Incidences 54
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Questions? 08.12.2014 Seminar on Geometric Incidences 55
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Thank you! 08.12.2014 Seminar on Geometric Incidences 56
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