Recovery conditions of compressed sensing approach to uncertainty quantification

54 mins 45 secs, 797.59 MB, MPEG-4 Video 640x360, 29.97 fps, 44100 Hz, 1.94 Mbits/sec

Share this media item:

Embed this media item:

<iframe width="_width_" height="_height_" src="https://sms.cam.ac.uk/media/2663486/embed" frameborder="0" scrolling="no" allowfullscreen></iframe>

Choose size:

About this item

Available Formats

About this item

Description:	Tran, H Tuesday 6th February 2018 - 09:00 to 10:00


Created:	2018-02-07 14:00
Collection:	Uncertainty quantification for complex systems: theory and methodologies
Publisher:	Isaac Newton Institute
Copyright:	Tran, H
Language:	eng (English)
Distribution:	World (downloadable)
Explicit content:	No
Aspect Ratio:	16:9
Screencast:	No
Bumper:	UCS Default
Trailer:	UCS Default


Abstract:	Co-author: Clayton Webster (UTK/ORNL). This talk is concerned with the compressed sensing approach to reconstruction of high-dimensional functions from limited amount of data. In this approach, the uniform bounds of the underlying global polynomial bases have often been relied on for the complexity analysis and algorithm development. We prove a new, improved recovery condition without using this uniform boundedness assumption, applicable to multidimensional Legendre approximations. Specifically, our sample complexity is established using the unbounded envelope of all polynomials, thus independent of polynomial subspaces. Some consequent, simple criteria for choosing good random sample sets will also be discussed. In the second part, I will discuss the recovery guarantees of nonconvex optimizations. These minimizations are generally closer to l_0 penalty than l_1 norm, thus it is widely accepted (also demonstrated computationally in UQ) that they are able to enhance the sparsity and accuracy of the approximations. However, the theory proving that nonconvex penalties are as good as or better than l1 minimization in sparse reconstruction has not been available beyond a few specific cases. We aim to fill this gap by establishing new recovery guarantees through unified null space properties that encompass most of the currently proposed nonconvex functionals in the literature, verifying that they are truly superior to l_1.

Abstract:

Co-author: Clayton Webster (UTK/ORNL). This talk is concerned with the compressed sensing approach to reconstruction of high-dimensional functions from limited amount of data. In this approach, the uniform bounds of the underlying global polynomial bases have often been relied on for the complexity analysis and algorithm development. We prove a new, improved recovery condition without using this uniform boundedness assumption, applicable to multidimensional Legendre approximations. Specifically, our sample complexity is established using the unbounded envelope of all polynomials, thus independent of polynomial subspaces. Some consequent, simple criteria for choosing good random sample sets will also be discussed. In the second part, I will discuss the recovery guarantees of nonconvex optimizations. These minimizations are generally closer to l_0 penalty than l_1 norm, thus it is widely accepted (also demonstrated computationally in UQ) that they are able to enhance the sparsity and accuracy of the approximations. However, the theory proving that nonconvex penalties are as good as or better than l1 minimization in sparse reconstruction has not been available beyond a few specific cases. We aim to fill this gap by establishing new recovery guarantees through unified null space properties that encompass most of the currently proposed nonconvex functionals in the literature, verifying that they are truly superior to l_1.

Available Formats

Format	Quality	Bitrate	Size
MPEG-4 Video *	640x360	1.94 Mbits/sec	797.59 MB	View	Download
WebM	640x360	570.46 kbits/sec	228.76 MB	View	Download
iPod Video	480x270	522.12 kbits/sec	209.37 MB	View	Download
MP3	44100 Hz	249.76 kbits/sec	100.25 MB	Listen	Download
Auto	(Allows browser to choose a format it supports)

Streaming Media Service Upload

Recovery conditions of compressed sensing approach to uncertainty quantification