Wednesday, February 29, 2012

Low-rank matrix completion by Riemannian optimization: Implementation


I just came across this implementation:


Low-rank matrix completion by Riemannian optimization by Bart Vandereycken. The abstract reads:
The matrix completion problem consists of finding or approximating a low-rank matrix based on a few samples of this matrix. We propose a novel algorithm for matrix completion that minimizes the least square distance on the sampling set over the Riemannian manifold of fi xed-rank matrices. The algorithm is an adaptation of classical non-linear conjugate gradients, developed within the framework of retraction-based optimization on manifolds. We describe all the necessary objects from di erential geometry necessary to perform optimization over this low-rank matrix manifold, seen as a submanifold embedded in the space of matrices. In particular, we describe how metric projection can be used as retraction and how vector transport lets us obtain the conjugate search directions. Additionally, we derive second-order models that can be used in Newton's method based on approximating the exponential map on this manifold to second order. Finally, we prove convergence of a regularized version of our algorithm under the assumption that the restricted isometry property holds for incoherent matrices throughout the iterations. The numerical experiments indicate that our approach scales very well for large-scale problems and compares favorable with the state-of-the-art, while outperforming most existing solvers.


The attendant code is here and is listed in the Matrix Factorization Jungle

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What does a compressive sensing approach bring to the table ?

Following up on yesterday's rant, let me give some perspective as to what compressive sensing brings to the table through a new chosen crop of papers from Arxiv in the past two weeks.

Clearly the next two studies fall into the new algorithmic tools section with the second one making an inference that was not done before by specialists in the field. in other words, CS provides a new insight in an older problem that was not recognized by a dedicated community. 

1.Semi-Quantitative Group Testing by Amin Emad, Olgica Milenkovic. The abstract reads:
We consider a novel group testing procedure, termed semi-quantitative group testing, motivated by a class of problems arising in genome sequence processing. Semi-quantitative group testing (SQGT) is a non-binary pooling scheme that may be viewed as a combination of an adder model followed by a quantizer. For the new testing scheme we define the capacity and evaluate the capacity for some special choices of parameters using information theoretic methods. We also define a new class of disjunct codes suitable for SQGT, termed SQ-disjunct codes. We also provide both explicit and probabilistic code construction methods for SQGT with simple decoding algorithms.
We propose a novel framework for studying causal inference of gene interactions using a combination of compressive sensing and Granger causality techniques. The gist of the approach is to discover sparse linear dependencies between time series of gene expressions via a Granger-type elimination method. The method is tested on the Gardner dataset for the SOS network in E. coli, for which both known and unknown causal relationships are discovered.

This next paper describes a new imaging system which is clearly at low technology readiness level. It has some potential.


An imaging system based on single photon counting and compressive sensing (ISSPCCS) is developed to reconstruct a sparse image in absolute darkness. The single photon avalanche detector and spatial light modulator (SLM) of aluminum micro-mirrors are employed in the imaging system while the convex optimization is used in the reconstruction algorithm. The image of an object in the very dark light can be reconstructed from an under-sampling data set, but with very high SNR and robustness. Compared with the traditional single-pixel camera used a photomultiplier tube (PMT) as the detector, the ISSPCCS realizes photon counting imaging, and the count of photons not only carries fluctuations of light intensity, but also is more intuitive.

The following paper shows a change in the software used in the data processing chain taking place after data has been acquired. There is no change in hardware here even though it might ultimately lead to one.


Emerging sonography techniques often require increasing the number of transducer elements involved in the imaging process. Consequently, larger amounts of data must be acquired and processed. The significant growth in the amounts of data affects both machinery size and power consumption. Within the classical sampling framework, state of the art systems reduce processing rates by exploiting the bandpass bandwidth of the detected signals. It has been recently shown, that a much more significant sample-rate reduction may be obtained, by treating ultrasound signals within the Finite Rate of Innovation framework. These ideas follow the spirit of Xampling, which combines classic methods from sampling theory with recent developments in Compressed Sensing. Applying such low-rate sampling schemes to individual transducer elements, which detect energy reflected from biological tissues, is limited by the noisy nature of the signals. This often results in erroneous parameter extraction, bringing forward the need to enhance the SNR of the low-rate samples. In our work, we achieve SNR enhancement, by beamforming the sub-Nyquist samples obtained from multiple elements. We refer to this process as "compressed beamforming". Applying it to cardiac ultrasound data, we successfully image macroscopic perturbations, while achieving a nearly eight-fold reduction in sample-rate, compared to standard techniques.

The next paper falls under the new conceptual study for a new architecture:

Smart Grids measure energy usage in real-time and tailor supply and delivery accordingly, in order to improve power transmission and distribution. For the grids to operate effectively, it is critical to collect readings from massively-installed smart meters to control centers in an efficient and secure manner. In this paper, we propose a secure compressed reading scheme to address this critical issue. We observe that our collected real-world meter data express strong temporal correlations, indicating they are sparse in certain domains. We adopt Compressed Sensing technique to exploit this sparsity and design an efficient meter data transmission scheme. Our scheme achieves substantial efficiency offered by compressed sensing, without the need to know beforehand in which domain the meter data are sparse. This is in contrast to traditional compressed-sensing based scheme where such sparse-domain information is required a priori. We then design specific dependable scheme to work with our compressed sensing based data transmission scheme to make our meter reading reliable and secure. We provide performance guarantee for the correctness, efficiency, and security of our proposed scheme. Through analysis and simulations, we demonstrate the effectiveness of our schemes and compare their performance to prior arts.

Finally, the last paper shows an improvement in the reconstruction rather than in the actual hardware.

Purpose: To retrospectively evaluate the fidelity of magnetic resonance (MR) spectroscopic imaging data preservation at a range of accelerations by using compressed sensing. Materials and Methods: The protocols were approved by the institutional review board of the university, and written informed consent to acquire and analyze MR spectroscopic imaging data was obtained from the subjects prior to the acquisitions. This study was HIPAA compliant. Retrospective application of compressed sensing was performed on 10 clinical MR spectroscopic imaging data sets, yielding 600 voxels from six normal brain data sets, 163 voxels from two brain tumor data sets, and 36 voxels from two prostate cancer data sets for analysis. The reconstructions were performed at acceleration factors of two, three, four, five, and 10 and were evaluated by using the root mean square error (RMSE) metric, metabolite maps (choline, creatine, N-acetylaspartate [NAA], and/or citrate), and statistical analysis involving a voxelwise paired t test and one-way analysis of variance for metabolite maps and ratios for comparison of the accelerated reconstruction with the original case. Results: The reconstructions showed high fidelity for accelerations up to 10 as determined by the low RMSE (, 0.05). Similar means of the metabolite intensities and hot-spot localization on metabolite maps were observed up to a factor of five, with lack of statistically significant differences compared with the original data. The metabolite ratios of choline to NAA and choline plus creatine to citrate did not show significant differences from the original data for up to an acceleration factor of five in all cases and up to that of 10 for some cases. Conclusion: A reduction of acquisition time by up to 80%, with negligible loss of information as evaluated with clinically relevant metrics, has been successfully demonstrated for hydrogen 1 MR spectroscopic imaging.


In all what do we see ? A compressive sensing approach currently either:

  • provide a means of designing a low TRL hardware  [3]
  • provide a means of defining new architectures [5]
  • provide a means of changing the current computational chain yielding gains at operational level [1, 4,6] (high TRL) and even permit discovery [2]! At this stage there is no change in hardware but it is likely the first step before new hardware gets to be complemented in view of the new data chain pipeline [4].
In short, at this stage, either the changes possible due to compressive sensing are invisible or very few (only one new sensor [3]) at a very low technology maturity level.

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Tuesday, February 28, 2012

Whose heart doesn't sink at the thought of Dirac being inferior to Theora ?

Djalil's take on going from seductive theory to applications got me thinking about how difficult it is to convey to newcomers how technology development really works. In fact,  this was the reason I drew this figure for the Dorkbot presentation recently as this was also the subject of a discussion on the LinkedIn CS group recently:


The scale on the right points to the maturity of a certain technology before it can be used in some operational fashion specifically in industrial applications. When it comes to compressive sensing related sensors, we are currently in the dip for most of them. 
The only technology (MRI) that made the leap did not require a change in hardware. 
It is as simple as that. Other ways you will hear about compressed sensing is when it improves not hardware but processes such as in group testing and/or some sort of competitive encoding. This is why you keep on hearing about those but less about the more fundamental new types of sensors.. In effect all the others are so low on the Technology Readiness Level list that it will take some investment from some niche application to grow them up to ubiquity.



Two truths seem to be coming out of this process so far:







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Joint Trace/TV Minimization: A New Efficient Approach for Spectral Compressive Imaging



Hyperspectral imagery is really one of those technologies we do not have. By that I mean that at a price of $100,000, no tinkerer will ever gets their hands on one of these cameras and as I explained the Dorkbot crowd two weeks ago, if no tinkerer can get their hands on it, then serendipity is unlikely to happen. The technology currently addresses broad needs but what we really need for this technology to be mainstream is the accidental discovery. It sure won't come if it cost 100,000 buckarus. David Brady and others are working on using compressive sensing to drown that cost by one or two orders of magnitude. Some of these advances  will not just come from hardware alone. Hence, I was ecstatic when I received this email last week from Pierre Vandergheynst:



Hi Igor
I'd like to draw your attention on the following paper: http://infoscience.epfl.ch/record/174926that advocates joint trace (or nuclear) - TV norm minimization for hyper spectral images, with really nice performances (see the effect of reconstructing with only m = 0.03 * n on Fig 2).
My student Mohammad is wrapping up the matlab code to be distributed on the same page. The data used in the paper is also publicly available.
Best regards   
Thanks Pierre for the heads-up. Here is the paper: Joint Trace/TV Minimization: A New Efficient Approach for Spectral Compressive Imaging by Mohammad GolbabaeePierre Vandergheynst:. The abstract reads:

In this paper we propose a novel and efficient model for compressed sensing of hyperspectral images. A large-size hyperspectral image can be subsampled by retaining only 3% of its original size, yet robustly recovered using the new approach we present here. Our reconstruction approach is based on minimizing a convex functional which penalizes both the trace norm and the TV norm of the data matrix. Thus, the solution tends to have a simultaneous low-rank and piecewise smooth structure: the two important priors explaining the underlying correlation structure of such data. Through simulations we will show our approach significantly enhances the conventional compression rate-distortion tradeoffs. In particular, in the strong undersampling regimes our method outperforms the standard TV denoising image recovery scheme by more than 17dB in the reconstruction MSE.

I wonder how this technique can used for blind deconvolution. But then eventually one can but wonder how this is going to affect actual compression hardware on satellites [1,2]


References of interest:

  1. CNES Studies for On-Board Compression of High-Resolution Satellite Images
  2.  by Carole Thiebaut and Roberto Camarero
  3. On-board Optical Image Compression for Future High Resolution Remote Sensing Systems

Saturday, February 25, 2012

Research Staff position at MERL

Petros Boufounos sent me the following this week:


Igor,
I hope things are well. We just opened a new position for a member of research staff at MERL with focus on compressive sensing. I would appreciate it if you could post it on Nuit Blanche. The link is here and the posting follows: http://www.merl.com/employment/employment.php#MM2
Thanks!
Petros
Member of Research StaffMultimedia group

Sure Petros ! Here it is:


MERL is seeking qualified and high-caliber applicants for a Research Staff position in the Multimedia Group. The successful candidate will be expected to perform original research in the area of signal acquisition and sensing, with emphasis in compressive sensing and array processing. Further details are outlined below.

Responsibilities:
       • Conduct innovative research on sensing and signal acquisition emphasizing modern acquisition methods and compressive sensing, with applications in ultrasonic, radio, optical, or other sensing modalities.
       • Prepare patent disclosures on newly developed work and assist legal department in finalizing patent applications.
       • Transfer developed technology to business units through R&D labs in Japan including software, documentation and experimental results.
       • Propose new research directions in sensing and signal acquisition technology, and contribute to overall research agenda of the group.
       • Publish results in major international conferences and peer-reviewed journals, and maintain a presence in the academic community.
Qualifications:
       • Applicants are expected to hold a Ph.D. degree in Electrical Engineering, Computer Science, or closely related field.
       • Applicants with 2+ years of post-Ph.D. research experience are preferred. Exceptional candidates including recent Ph.D. graduates and post-doctoral researchers are strongly encouraged to apply.
       • Extensive signal processing background and understanding of sampling, sensing and signal acquisition technologies is required. Direct experience with compressive sensing is also required.
       • Experience with array processing and/or related acquisition systems is preferred.
       • Familiarity with related technologies such as dictionary learning, convex optimization, or greedy algorithms is also preferred.
       • Applicants must have a strong publication record demonstrating novel research achievements.
       • Excellent programming skills (C/C++, Matlab, etc) are required.
       • Excellent presentation, written and inter-personal communication skills are expected.
Mitsubishi Electric Research Laboratories, Inc. is an Equal Opportunity Employer.
PRINCIPALS ONLY apply via email to   avetro@merl.com. No phone calls please.




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Multiple postdoc positions at EPFL

Volkan sent me the following this week:




Hi Igor,
I would like to make an announcement for postdoc positions at my lab. I would really appreciate it if you can feature it on Nuit Blanche this week.....
best,
Volkan

Sure I can Volkan ! Here it is:


============================
Postdoctoral Positions at LIONS
Laboratory for Information and Inference Systems (http://lions.epfl.ch/) at Ecole Polytechnique Federale de Lausanne (EPFL) has multiple openings for energetic postdoctoral fellows in the broad fields of Applied Mathematics, Theoretical Computer Science, and Statistics as part of Prof. Volkan Cevher’s 5-year European Research Council project. Salaries start at CHF 84K. Positions are available immediately.

Our lab provides a fun, collaborative research environment with state-of-the-art facilities at EPFL, one of the leading technical universities worldwide. EPFL is located in Lausanne next to Lake Geneva in a scenic setting.

Topics of interest include, but are not limited to
·         Analysis and design of advanced convex and non-convex optimization methods with applications to inverse problems.
·         Analysis and design of advanced discrete optimization methods with particular emphasis on sublinear, submodular, and approximation algorithms.
·         Learning theory and methods for non-parametric, sparse additive models.
·         Encoder design for compressive and adaptive measurement schemes, including information extractors (e.g., polar codes) and expanders.
·         Advanced linear algebra methods for optimized information extraction from very large dimensional datasets.
·         Analysis and applications of non-iid probabilistic models.
Requirements:
Applicants are expected to have finished, or are about to finish their Ph.D. degrees. They must have an exceptional background at least in one of the following topics: numerical convex optimization, combinatorial optimization, statistics, coding theory, and algorithms.

A track record of relevant publications at top applied mathematics, theoretical computer science, statistics, or engineering journals or conferences is essential.
The working language at EPFL is English.
Application:
Please send your applications via email to Sylvia Sandoz (sylvia.sandoz@epfl.ch).

Application material:
·         Statement of research
·         Curriculum vitae with a list of publications
·         Contact details for 3 references



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Two postdoctoral positions in Signal Processing & Machine Learning at Inria Rennes (France)

Remi Gribonval sent this announcement for two postdocs at INRIA in Rennes, France,


Two postdoctoral positions in Signal Processing & Machine Learning at Inria Rennes (France)

Context
Two postdoc positions are open in the Metiss team (Speech and Audio Processing) at Inria, Rennes, France. The postdocs are funded by PLEASE (Projection, Learning and Sparsity for Efficient data processing), a project sponsored by the ERC (European Research Council), which aims at investigating sparse representations and low-dimensional projections. The research conducted by the postdocs will be at the frontiers of Signal Processing and Machine Learning, with applications to Acoustics & Audio.

Subject
The Metiss team develops mathematical and statistical signal models and algorithms for acoustic and audio applications. In the framework of the PLEASE project, these problems are addressed under the auspices of
sparsity and low-dimensional projections, with the aim of developing new ways to acquire, analyze and process the information content of complex acoustic data (e.g.: compressive acoustic sensing, blind source
separation), as well as large collections of such data for learning (e.g.: multimedia indexing).
A first goal will be to further develop recently achieved mathematical and algorithmic results, to demonstrate their impact on selected acoustic applications, and to disseminate them through the development of software. A second aspect will be to explore machine learning strategies exploiting low-dimensional projections to process large data collections in the context of multimedia indexing.

Environment
The Metiss team gathers around 15 researchers, post-docs, PhD students and engineers with expertise in various fields of mathematical and statistical signal processing and audio. The team is part of the IRISA /
INRIA Rennes - Bretagne Atlantique Research Center, located on the campus of the Université de Rennes I in the historic city of Rennes, capital of Britanny. The center is a major player in computer science and
information technology gathering about 400 scientists (including 90 fulltime researchers, 70 professors and associated professors, and 190 PhD students) in an international environment. The recruited postdocs will
have occasions to interact with several groups at Inria Rennes, including computer scientists and applied mathematicians, and will have access to large-scale computing grids and multimedia databases, as well as
multichannel audio recording equipment.

Qualifications required
Candidates should hold a Ph.D., and will either be applied mathematicians with interest for statistical signal processing and acoustic applications, and good programming skills, or originate from signal processing / computer science with solid background in applied mathematics and statistics.
Previous experience in sparse signal representations or statistical machine learning is preferred, but experience in related areas is suitable.

Starting date: as soon as possible

Duration: one year, renewable

Scientific Contact: remi.gribonval@inria.fr

To apply:
Applicants are requested to send a CV, a list of publications and a brief statement of research interests. This material, together with two letters of reference, shall be sent to Stephanie.lemaile@inria,fr before April 15, 2012.




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Monday, February 20, 2012

Videos: Group Testing Designs, Algorithms, and Applications to Biology

There are four videos from the meeting on the Group Testing Designs, Algorithms, and Applications to Biology  IMA meeting. Enjoy!



Tutorial: Sparse signal recovery
February 13, 2012 11:15 am - 12:15 pm

Keywords of the presentation: streaming algorithms, group testing, sparse signal recovery, introduction.

My talk will be a tutorial about sparse signal recovery but, more importantly, I will provide an overview of what the research problems are at the intersection of biological applications of group testing, streaming algorithms, sparse signal recovery, and coding theory. The talk should help set the stage for the rest of the workshop.


Tutorial: Cost effective sequencing of rare genetic variations
February 13, 2012 10:00 am - 11:00 am

In the past few years, we have experienced a paradigm shift in human genetics. Accumulating lines of evidence have highlighted the pivotal role of rare genetic variations in a wide variety of traits and diseases. Studying rare variations is a needle in a haystack problem, as large cohorts have to be assayed in order to trap the variations and gain statistical power. The performance of DNA sequencing is exponentially growing, providing sufficient capacity to profile an extensive number of specimens. However, sample preparation schemes do not scale as sequencing capacity. A brute force approach of preparing hundredths to thousands of specimens for sequencing is cumbersome and cost-prohibited. The next challenge, therefore, is to develop a scalable technique that circumvents the bottleneck in sample preparation.

My tutorial will provide background on rare genetic variations and DNA sequencing. I will present our sample prep strategy, called DNA Sudoku, that utilizes combinatorial pooling/compressed sensing approach to find rare genetic variations. More importantly, I will discuss several major distinction from the classical combinatorial due to sequencing specific constraints.



Identification of rare alleles and their carriers using compressed se(que)nsing
February 13, 2012 2:00 pm - 3:00 pm

Keywords of the presentation: compressed sensing, group testing, genetics, rare alleles

Identification of rare variants by resequencing is important both for detecting novel variations and for screening individuals for known disease alleles. New technologies enable low-cost resequencing of target regions, although it is still prohibitive to test more than a few individuals. We propose a novel pooling design that enables the recovery of novel or known rare alleles and their carriers in groups of individuals. The method is based on combining next-generation sequencing technology with a Compressed Sensing (CS) approach. The approach is general, simple and efficient, allowing for simultaneous identification of multiple variants and their carriers. It reduces experimental costs, i.e., both sample preparation related costs and direct sequencing costs, by up to 70 fold, and thus allowing to scan much larger cohorts. We demonstrate the performance of our approach over several publicly available data sets, including the 1000 Genomes Pilot 3 study. We believe our approach may significantly improve cost effectiveness of future association studies, and in screening large DNA cohorts for specific risk alleles.

We will present initial results of two projects that were initiated following publication. The first project concerns identification of de novo SNPs in genetic disorders common among Ashkenazi Jews, based on sequencing 3000 DNA samples. The second project in plant genetics involves identifying SNPs related to water and silica homeostasis in Sorghum bicolor, based on sequencing 3000 DNA samples using 1-2 Illumina lanes.

Joint work with Amnon Amir from the Weizmann Institute of Science, and Or Zuk from the Broad Institute of MIT and Harvard





RNA Structure Characterization from High-Throughput Chemical Mapping Experiments
February 13, 2012 3:45 pm - 4:45 pm

Keywords of the presentation: RNA structure characterization, high-throughput sequencing, maximum likelihood estimation

New regulatory roles continue to emerge for both natural and engineered noncoding RNAs, many of which have specific secondary and tertiary structures essential to their function. This highlights a growing need to develop technologies that enable rapid and accurate characterization of structural features within complex RNA populations. Yet, available structure characterization techniques that are reliable are also vastly limited by technological constraints, while the accuracy of popular computational methods is generally poor. These limitations thus pose a major barrier to the comprehensive determination of structure from sequence and thereby to the development of mechanistic understanding of transcriptome dynamics. To address this need, we have recently developed a high-throughput structure characterization technique, called SHAPE-Seq, which simultaneously measures quantitative, single nucleotide-resolution, secondary and tertiary structural information for hundreds of RNA molecules of arbitrary sequence. SHAPE-Seq combines selective 2’-hydroxyl acylation analyzed by primer extension (SHAPE) chemical mapping with multiplexed paired-end deep sequencing of primer extension products. This generates millions of sequencing reads, which are then analyzed using a fully automated data analysis pipeline. Previous bioinformatics methods, in contrast, are laborious, heuristic, and expert-based, and thus prohibit high-throughput chemical mapping.

In this talk, I will review recent developments in experimental RNA structure characterization as well as advances in sequencing technologies. I will then describe the SHAPE-Seq technique, focusing on its automated data analysis method, which relies on a novel probabilistic model of a SHAPE-Seq experiment, adjoined by a rigorous maximum likelihood estimation framework. I will demonstrate the accuracy and simplicity of our approach as well as its applicability to a general class of chemical mapping techniques and to more traditional SHAPE experiments that use capillary electrophoresis to identify and quantify primer extension products.

This is joint work with Lior Pachter, Julius Lucks, Stefanie Mortimer, Shujun Luo, Cole Trapnell, Gary Schroth, Jennifer Doudna and Adam Arkin.


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