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  <title><![CDATA[PhD Defense by Jeffrey Pavelka]]></title>
  <body><![CDATA[<p>Title: Scaling-based Methods in Optimization and Cut Generation</p>

<p>Advisor: Dr. Sebastian Pokutta</p>

<p>&nbsp;</p>

<p>Committee Members:</p>

<p>Dr. Chelsea White</p>

<p>Dr. Alejandro Toriello</p>

<p>Dr. Santanu Dey</p>

<p>Dr. Marc Pfetsch (TU Darmstadt)</p>

<p>&nbsp;</p>

<p>Date and time: Thursday, February 16th, 10:00 AM.</p>

<p>&nbsp;</p>

<p>Location: ISyE Main Building, room 341.</p>

<p>&nbsp;</p>

<p>Abstract:</p>

<p>&nbsp;</p>

<p>This thesis addresses both theoretical and practical concerns in integer programming. In Chapter 2 we discuss scaling-based primal methods for integer programming. Such methods optimize by repeatedly solving augmentation problems - given a polytope, cost vector, and feasible solution, either return a solution with improved objective value or assert that none exists. It is known that with clever scaling of the objective vector,&nbsp;one can optimize by solving only&nbsp;polynomially many augmentation sub-problems. We discuss two known scaling algorithms - bit scaling and geometric scaling - and prove tightened bounds on the number of augmentations necessary. We also explore the practical&nbsp;feasibility of such schemes with a computational study.</p>

<p>&nbsp;</p>

<p>Chapter 3&nbsp;addresses questions regarding Chvatal-Gomory (CG) cuts for 0/1 polytopes. The CG rank of such polytopes is known to be&nbsp;O(n^2\log(n)) in general. We prove a tighter bound for such polyhedra which, while still O(n^2\log(n)) in general, implies asymptotically improved bounds for several classes of polyhedra. Furthermore, we address the question of complexity for the separation problem over a family of cuts related to CG cuts, called mod-k cuts. We show this problem to be NP complete.</p>

<p>&nbsp;</p>

<p>Finally, Chapter 4 turns away from integer programming theory, instead focusing on an application in inventory management. We study a scenario (inspired by collaboration with a large online retailer) in which replenishment opportunities arise according to a process outside our control. We devise a stochastic model for use in this scenario, and test its&nbsp;usefulness by way of a simulation study using actual sales data from our collaborator.&nbsp;Of particular interest here is the use of data-driven prediction techniques to tune model parameters. We demonstrate that predictions culled from sophisticated machine learning techniques (e.g.\ neural network regression) can provide a boost in performance as compared to simpler, classical techniques (e.g.\ moving averages).</p>

<p>&nbsp;</p>
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