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X-WR-CALNAME;VALUE=TEXT:Seminar: Sitan Chen (University of California, Berkeley): "Learning Polynomial Transformations"
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SUMMARY:Seminar: Sitan Chen (University of California, Berkeley): "Learning Polynomial Transformations"
DESCRIPTION:<p>	<strong><drupal-media data-entity-type="media" data-entity-uuid="c7c9ec49-4b22-4762-93c8-8f082000c9af" alt="Sitan Chen" data-view-mode="hwp_small"></drupal-media><br>Speaker:</strong> Sitan Chen (UC Berkeley)<br><strong>Title: </strong>Learning Polynomial Transformations<br><strong>Abstract: </strong><span style="sans-serif"><span style="caret-color:#000000"><span style="font-style:normal"><span style="font-variant-caps:normal"><span style="font-weight:normal"><span style="letter-spacing:normal"><span style="orphans:auto"><span style="text-transform:none"><span style="white-space:normal"><span style="widows:auto"><span style="word-spacing:0px"><span style="-webkit-text-size-adjust:auto"><span style="text-decoration:none">Generative models like variational auto-encoders, generative adversarial networks, and flow-based models have exploded in popularity as extraordinarily effective ways of modeling real-world data. At their heart, these models attempt to learn a parametric transformation of a simple, low-dimensional distribution into a complex, high-dimensional one. Yet despite their immense practical impact, very little is known about the learnability of such distributions from a theoretical perspective.</span></span></span></span></span></span></span></span></span></span></span></span></span><br><span style="sans-serif"><span style="caret-color:#000000"><span style="font-style:normal"><span style="font-variant-caps:normal"><span style="font-weight:normal"><span style="letter-spacing:normal"><span style="orphans:auto"><span style="text-transform:none"><span style="white-space:normal"><span style="widows:auto"><span style="word-spacing:0px"><span style="-webkit-text-size-adjust:auto"><span style="text-decoration:none">This talk concerns arguably the most natural incarnation of this problem: given samples from the pushforward of the Gaussian under an unknown polynomial <em>p</em>: <span style="background-color:white">ℝ</span><em>r</em> <span style="background-color:white">→</span> <span style="background-color:white">ℝ</span><em>d</em>, can we approximately recover <em>p</em> (up to trivial symmetries)? I'll present the first polynomial-time algorithms for this task. These results leverage the sum-of-squares hierarchy, which has emerged from the theoretical computer science community in recent years as a powerful algorithmic tool for solving a number of high-dimensional statistical problems. Along the way, I will also highlight an intriguing connection to tensor ring decomposition, a popular variant of the matrix product state ansatz.</span></span></span></span></span></span></span></span></span></span></span></span></span><br><span style="sans-serif"><span style="caret-color:#000000"><span style="font-style:normal"><span style="font-variant-caps:normal"><span style="font-weight:normal"><span style="letter-spacing:normal"><span style="orphans:auto"><span style="text-transform:none"><span style="white-space:normal"><span style="widows:auto"><span style="word-spacing:0px"><span style="-webkit-text-size-adjust:auto"><span style="text-decoration:none">Based on joint work with Jerry Li, Yuanzhi Li, and Anru Zhang.</span></span></span></span></span></span></span></span></span></span></span></span></span></p><p>	 </p>
LOCATION:https://harvard.zoom.us/j/779283357?pwd=MitXVm1pYUlJVzZqT3lwV2pCT1ZUQT09
STATUS:CONFIRMED
DTSTART:20220510T133000Z
DTEND:20220510T133000Z
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