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Maximum and Maximal Cliques | Graph Theory, Clique Number
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Classroom Contents
Graph Theory - Complete Course on Fundamentals and Advanced Topics
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- 1 What is a Graph? | Graph Theory
- 2 What are Adjacent Vertices? | Graph Theory
- 3 What is the Order of a Graph? | Graph Theory
- 4 What is the Size of a Graph? | Graph Theory
- 5 Order and Size of a Graph | Graph Theory
- 6 Empty Graph, Trivial Graph, and the Null Graph | Graph Theory
- 7 What are Adjacent Edges? | Graph Theory
- 8 What is a Subgraph? | Graph Theory
- 9 What is a Spanning Subgraph? | Graph Theory
- 10 Proper and Improper Subgraphs | Graph Theory
- 11 What is a Vertex Induced Subgraph? | Graph Theory
- 12 What is an Edge-Induced Subgraph? | Graph Theory
- 13 What is a Walk? | Graph Theory
- 14 What is a Trail? | Graph Theory
- 15 What is a Path? | Graph Theory
- 16 Proof: If There is a u-v Walk then there is a u-v Path | Every Walk Contains a Path, Graph Theory
- 17 What is a Circuit? | Graph Theory
- 18 What is a Graph Cycle? | Graph Theory, Cycles, Cyclic Graphs, Simple Cycles
- 19 Connected and Disconnected Graphs | Graph Theory
- 20 What are Connected Vertices? | Graph Theory
- 21 What are Connected Graphs? | Graph Theory
- 22 Connection as an Equivalence Relation | Graph Theory
- 23 What is a Component of a Graph? | Connected Components, Graph Theory
- 24 Explaining Components of Graphs | Graph Theory
- 25 Graphs Have at Least n-m Components | Graph Theory
- 26 Size and Degree from Vertex Deleted Subgraphs | Graph Theory
- 27 Distance, Diameter, and Geodesics | Graph Theory
- 28 Distance Between Two Vertices in Graphs | Graph Theory
- 29 What are Geodesics? | Graph Theory
- 30 Diameter of a Graph | Graph Theory
- 31 Proof: Connected Graph Contains Two Non-Cut Vertices | Graph Theory, Connected Graphs
- 32 What is a Path Graph? | Graph Theory
- 33 What are Cycle Graphs? | Graph Theory, Graph Cycles, Cyclic Graphs
- 34 What is a Complete Graph? | Graph Theory
- 35 Number of Edges in a Complete Graph (Using Combinations) | Graph Theory, Combinatorics
- 36 How Many Graphs on n Vertices? | Graph Theory
- 37 What is the Complement of a Graph? | Graph Theory, Graph Complements, Self Complementary Graphs
- 38 Proof: A Graph or its Complement Must be Connected | Graph Theory, Graph Complements
- 39 What is a Bipartite Graph? | Graph Theory
- 40 Proof: Closed Odd Walk contains Odd Cycle | Graph Theory
- 41 Proof: Bipartite Graphs have no Odd Cycles | Graph Theory, Bipartite Theorem, Proofs
- 42 Proof: If a Graph has no Odd Cycles then it is Bipartite | Graph Theory, Bipartite Theorem
- 43 How to Tell if Graph is Bipartite (by hand) | Graph Theory
- 44 What are Complete Bipartite Graphs? | Graph Theory, Bipartite Graphs
- 45 Intro to Hypercube Graphs (n-cube or k-cube graphs) | Graph Theory, Hypercube Graph
- 46 Overview of Loops in Graph Theory | Graph Loop, Multigraphs, Pseudographs
- 47 Intro to Directed Graphs | Digraph Theory
- 48 Parallel Edges in Multigraphs and Digraphs | Graph Theory, Multiple Edges, Multisets
- 49 What is the Degree of a Vertex? | Graph Theory
- 50 Neighborhood of a Vertex | Open and Closed Neighborhoods, Graph Theory
- 51 The First Theorem of Graph Theory | Graph Theory
- 52 Proof: Every Graph has an Even Number of Odd Degree Vertices | Graph Theory
- 53 Proof: Degree Sum Condition for Connected Graphs | Connected Graphs, Nonadjacent Vertices
- 54 Proof: Minimum Degree Condition for Connected Graphs | Graph Theory
- 55 What are Regular Graphs? | Graph Theory
- 56 What are Cubic Graphs? | Graph Theory
- 57 Simple Definition of Petersen Graph | Graph Theory
- 58 Degree Sequence of a Graph | Graph Theory, Graphical Sequences
- 59 Which Sequences are Graphical? (Degree Sequences and Havel-Hakimi algorithm) | Graph Theory
- 60 What are Irregular Graphs? (and why they are boring) | Graph Theory
- 61 What are Isomorphic Graphs? | Graph Isomorphism, Graph Theory
- 62 Isomorphic Graphs Have the Same Degree Sequence | Graph Theory
- 63 Graph Automorphisms and Vertex Transitive Graphs | Graph Theory
- 64 Edge Subtraction and Bridges in Graphs | Graph Theory, Edge Deletion
- 65 What are Bridges of Graphs? | Graph Theory, Edge Deletion
- 66 Proof: An Edge is a Bridge iff it Lies on No Cycles | Graph Theory
- 67 Intro to Tree Graphs | Trees in Graph Theory, Equivalent Definitions
- 68 Proof: Graph is a Tree iff Unique Paths for Each Vertex Pair | Graph Theory, Tree Graphs
- 69 Proof: Tree Graphs Have at Least Two End Vertices | Graph Theory
- 70 Proof: Tree Graph of Order n Has Size n-1 | Graph Theory
- 71 Proof: Forest Graphs have n-k Edges | Graph Theory
- 72 Proof: Connected Graph of Order n Has at least n-1 Edges | Graph Theory
- 73 Proof: Every Connected Graph has a Spanning Tree | Graph Theory
- 74 Kruskal's Algorithm for Minimum Spanning Trees (MST) | Graph Theory
- 75 Prim's Algorithm for Minimum Spanning Trees (MST) | Graph Theory
- 76 Proof on Cut Vertices Incident with Bridges | Graph Theory
- 77 Important Theorem about Cut Vertices | Graph Theory
- 78 Proof of a Characterization of Cut Vertices | Graph Theory
- 79 Proof: A Furthest Vertex is not a Cut Vertex | Graph Theory, Connected Graphs
- 80 What are Non-Separable Graphs? | Graph Theory
- 81 Vertex Cuts in Graphs (and a bit on Connectivity) | Graph Theory
- 82 Vertex Connectivity of a Graph | Graph Theory
- 83 Simple Bounds on Vertex Connectivity | Graph Theory
- 84 Vertex Connectivity of the Petersen Graph | Graph Theory
- 85 Edge Cuts and Edge Connectivity | Graph Theory
- 86 Edge Connectivity of Complete Graphs | Graph Theory
- 87 What are Vertex Separating Sets? | Graph Theory
- 88 What are Vertex Disjoint Paths? | Graph Theory
- 89 Intro to Menger's Theorem | Graph Theory, Connectivity
- 90 Proof: Menger's Theorem | Graph Theory, Connectivity
- 91 Eulerian Circuits and Eulerian Graphs | Graph Theory
- 92 Unicursal Graphs and Unicursal Lines | Semi-Eulerian Trails, Graph Theory
- 93 Proof: Graph is Eulerian iff All Vertices have Even Degree | Euler Circuits, Graph Theory
- 94 Hamiltonian Cycles, Graphs, and Paths | Hamilton Cycles, Graph Theory
- 95 Proof: Ore's Theorem for Hamiltonian Graphs | Sufficient Condition for Hamilton Graphs, Graph Theory
- 96 Proof: Necessary Component Condition for Graphs with Hamiltonian Paths | Graph Theory
- 97 Proof: Necessary Component Condition for Hamiltonian Graphs | Graph Theory
- 98 Proof: Dirac's Theorem for Hamiltonian Graphs | Hamiltonian Cycles, Graph Theory
- 99 Indegree and Outdegree in Directed Graphs | Graph Theory
- 100 In-Neighborhoods and Out-Neighborhoods in Digraphs | Graph Theory
- 101 Orientations of Graphs | Directed Graphs, Digraph Theory
- 102 What are Symmetric Digraphs? | Graph Theory
- 103 First Theorem of Directed Graphs | Digraph Theory
- 104 Underlying Graphs of Digraphs | Directed Graphs, Graph Theory
- 105 Weakly Connected Directed Graphs | Digraph Theory
- 106 Strongly Connected Directed Graphs | Graph Theory
- 107 Intro to Tournament Graphs | Graph Theory
- 108 Transitive Tournaments (Directed Graphs) | Graph Theory
- 109 Proof: Tournament is Transitive iff it has No Cycles | Graph Theory
- 110 Proof for Distances from Tournament's Maximum Outdegree Vertex | Graph Theory
- 111 Proof: Every Tournament has Hamiltonian Path | Graph Theory
- 112 Proof: Vertices of Strong Tournament Lie on Triangles | Graph Theory
- 113 Matchings, Perfect Matchings, Maximum Matchings, and More! | Graph Theory
- 114 Perfect Matchings on Complete Graphs | Graph Theory
- 115 Hall's Theorem and Condition for Bipartite Matchings | Graph Theory
- 116 Proof: Hall's Marriage Theorem for Bipartite Matchings | Graph Theory
- 117 Proof: Regular Bipartite Graph is Balanced | Graph Theory
- 118 Proof: Regular Bipartite Graph has a Perfect Matching | Graph Theory
- 119 Edge Covers and Edge Covering Numbers of Graphs | Graph Theory
- 120 Independent Vertex Sets and Independence Numbers | Graph Theory
- 121 Vertex Covers and Vertex Covering Numbers | Graph Theory
- 122 Complement of Vertex Cover is Independent Vertex Set | Graph Theory
- 123 Complement of Independent Set is Vertex Cover | Graph Theory
- 124 What are Graph Decompositions? | Graph Decomposition, Graph Theory
- 125 What are Planar Graphs? | Graph Theory
- 126 Proof: Euler's Formula for Plane Graphs | Graph Theory
- 127 Proof: Upper Bound for the Size of Planar Graphs | Graph Theory
- 128 Every Planar Graph has a Vertex of Degree 5 or Less | Graph Theory
- 129 Which Complete Graphs are Planar? | Graph Theory
- 130 Edges that Lie on One Boundary of a Region in a Plane Graph | Graph Theory
- 131 Degree of a Face in a Plane Graph | Graph Theory
- 132 Vertex Colorings and the Chromatic Number of Graphs | Graph Theory
- 133 Chromatic Number of Bipartite Graphs | Graph Theory
- 134 Chromatic Number of Complete Graphs | Graph Theory
- 135 What is a Clique? | Graph Theory, Cliques
- 136 Does Chromatic Number n Imply Clique on n Vertices? | Graph Theory
- 137 Edge Colorings and Chromatic Index of Graphs | Graph Theory
- 138 Subtracting a Vertex from a Graph (Vertex Deletion) | Graph Theory
- 139 What are Star Graphs? | Graph Theory
- 140 What is a Highly Irregular Graph? | Locally Irregular Graph, Graph Theory
- 141 Graph Representation with an Adjacency Matrix | Graph Theory, Adjaceny Matrices
- 142 What is a Maximal Clique? | Graph Theory, Cliques, Maximal Cliques
- 143 A Proof on Hamiltonian Complete Bipartite Graphs | Graph Theory, Hamiltonian Graphs
- 144 Maximum and Maximal Cliques | Graph Theory, Clique Number
- 145 Proof: Non-Regular Graph has Adjacent Vertices with Distinct Degrees | Connected Graphs
- 146 Proof: Two Longest Paths Have a Common Vertex | Graph Theory, Connected Graphs
- 147 Proof: A Graph or its Complement is not Bipartite | Graph Theory, Bipartite Graphs
- 148 Proof: Graph with all Even Degree Vertices has no Bridges | Graph Theory
- 149 Proof: Complement of Regular Non-Eulerian Graph is Eulerian | Graph Theory, Euler Graphs
- 150 Minimum and Maximum Degree Vertices in Complement Graphs | Graph Complements, Graph Theory
- 151 Bound on the Sum of Minimum Degrees of Graphs and their Complements | Graph Theory Proofs
- 152 Proof: Connected Graph with a Bridge must have a Cut Vertex | Graph Theory
- 153 Proof: Cut Vertex is not a Cut Vertex of the Complement Graph | Graph Theory
- 154 Resolving Sets and Metric Dimension of Graphs | Graph Theory
- 155 What are the Maximum and Maximal Cliques of this Graph? | Graph Theory
- 156 Bipartite Graphs with Isolated Vertices | Graph Theory, Complete Bipartite Graphs
- 157 Proof: Graph with n Vertices and n-1 Edges is a Tree | Graph Theory
- 158 Proof: A Bridge is the Unique Path connecting its End Vertices | Graph Theory
- 159 Proof: Every Edge of a Tree is a Bridge | Graph Theory
- 160 Proof: Every Graph Contains Minimum Degree Length Path | Graph Theory
- 161 Proof: Graph has a Cycle Longer than its Minimum Degree | Graph Theory
- 162 Graphs are Metric Spaces | Graph Theory
- 163 Eccentricity of a Vertex | Graph Theory
- 164 Diameter and Radius of Graphs | Graph Theory
- 165 Graph Diameter is Bounded by Radius | Graph Theory
- 166 Diameter and Radius of Tree Graphs | Graph Theory
- 167 Eccentricities of Adjacent Vertices Differ by at Most 1 | Graph Theory
- 168 Dominating Sets and Domination Number of Graphs | Graph Theory
