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Learning Combinatorial Optimization Algorithms Over Graphs
Learning Combinatorial Optimization Algorithms Over Graphs
Learning Combinatorial Optimization Over Graphs
Roles
Abhi (intro),
Pranav/Avlin (actual paper),
Daniel (Conclusion: performance, adv, disadv, criticism)
Intro
1) Graph Theory (MLP, TSP, Maxcut) -
Common Problems to Solve are:
Minimum Vertex Cover: Given a ‘graph’ G, find the minimum number of vertices to tick, so that every single edge is covered. G=(V,E,w).
Where G is the Graph, V are the vertices, E is the edge, and w is the optimal solution
Maximum Cut: Given a ‘graph’ G,
Travelling Salesman Problem
2) Reinforcement Learning -
Actual Paper:
Conclusions (Performance, advantages, disadvantages): A3C? S2V?
Criticism:

Revision as of 19:09, 19 March 2018

Learning Combinatorial Optimization Algorithms Over Graphs

Learning Combinatorial Optimization Over Graphs

Roles Abhi (intro), Pranav/Avlin (actual paper), Daniel (Conclusion: performance, adv, disadv, criticism)

Intro 1) Graph Theory (MLP, TSP, Maxcut) - Common Problems to Solve are: Minimum Vertex Cover: Given a ‘graph’ G, find the minimum number of vertices to tick, so that every single edge is covered. G=(V,E,w). Where G is the Graph, V are the vertices, E is the edge, and w is the optimal solution Maximum Cut: Given a ‘graph’ G, Travelling Salesman Problem

2) Reinforcement Learning -


Actual Paper:


Conclusions (Performance, advantages, disadvantages): A3C? S2V?


Criticism:

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