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Inferring Data Inter-Relationships Via Fast Hierarchical Models

Inferring Data Inter-Relationships Via Fast Hierarchical Models. Lawrence Carin Duke University www.ece.duke.edu/~lcarin. Sensor Deployed Previously Across Globe. Previous deployments. New deployment. Deploy to New Location. Can Algorithm Infer Which Data from

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Inferring Data Inter-Relationships Via Fast Hierarchical Models

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  1. Inferring Data Inter-Relationships Via Fast Hierarchical Models Lawrence Carin Duke University www.ece.duke.edu/~lcarin

  2. Sensor Deployed Previously Across Globe Previous deployments New deployment Deploy to New Location. Can Algorithm Infer Which Data from Past is Most Relevant for New Sensing Task?

  3. Semi-Supervised & Active Learning • Enormous quantity of unlabeled data -> exploit context via semi-supervised learning • Focus the analyst on most-informative data -> active learning

  4. Technology Employed & Motivation • Appropriately exploit related data from previous experience over sensor “lifetime” • - Transfer learning • Place learning with labeled data in the context of unlabeled data, thereby • exploiting manifold information • - Semi-supervised learning • Reduce load on analyst: only request labeled data on subset of data for which • label acquisition would be most informative • - Active learning

  5. Bayesian Hierarchical Models: Dirichlet Processes • Principled setting for transfer learning • Avoids problems with model selection • Number of mixture components • Number of HMM states [iGMM: Rasmussan, 00], [iHMM: Teh et al., 04,06], [Escobar & West, 95]

  6. 1 Data Sharing: Stick-Breaking View of DP – 1/2 • The Dirichlet process (DP) is a prior on a density function, i.e., G(Θ) ~DP[α,Go(Θ)] • One draw of G(Θ) from DP[α,Go(Θ)]: [Sethuraman, 94]

  7. Data Sharing: Stick-Breaking View of DP – 2/2 1 • As α → 0, the more likely that Beta(1, α) yields large νk , implying more sharing; • a few larger “sticks”, with corresponding likely parameters • As α→∞, sticks very small and roughly the same size, so reduces to Go

  8. di Gaussian or HMM Non-Parametric Mixture Models • Data sample didrawn from a Gaussian/HMM with associated parameters • - Posterior on model parameters indicates which parameters are shared, yielding a • Gaussian/HMM mixture model; no model selection on number of mixture components

  9. Dirichlet Process as a Shared Prior • Cumulative set of data D={d1, d2, …,dn}, with associated parameters • When parameters are shared then the associated data are also shared; data sharing implies • learning from previous/other experiences → Life-long learning • Posterior reflects a balance between the DP-based desire for sharing, constituted by the • prior , against the likelihood function • that rewards parameters that match the data well DP Desire for Sharing Parameters Likelihood’s Desire to Fit Data Posterior Balances these Objectives

  10. we draw Hierarchical Dirichlet Process – 1/2 • A DP prior on the parameters of a Gaussian model yields a GMM in which the number • of mixture components need not be set a priori (non-parametric) • Assume we wish to build N GMMs, each designed using a DP prior • We link the N GMMs via an overarching DP “hyper prior” [Teh et al., 06]

  11. Hierarchical Dirichlet Process – 2/2 • HDP yields a set of GMMs, each of which shares the same parameters , corresponding • to Gaussian mean and covariance, with distinct probabilities of observation • Coefficients an,k represent the probability of transitioning from state n to state k • Naturally yields the structure of an HMM; number of large amplitude coefficients an,k • implicitly determines the most-probable number of states

  12. Computational Challenges in Performing Inference • We have the general challenge of estimating the posterior • The denominator is typically of high dimension (number of parameters in model), and • cannot be computed exactly in reasonable time • Approximations required MCMC Variational Bayes (VB) Accuracy Laplace Computational Complexity [Blei & Jordan, 05]

  13. Graphical Model of the nDP-iHMM [Ni, Dunson, Carin; ICML 07]

  14. How Do You Convince Navy Data Search Works? Validation Not as “Simple” as Text Search Consider Special Kind of Acoustic Data: Music

  15. Multi-Task HMM Learning • Assume we have N sequential data sets • Wish to learn HMM for each of the data sets • Believe that data can be shared between the learning tasks; not independent task • All N HMMs learned jointly, with appropriate data sharing • Use of iHMM avoids the problem of selecting number of states in HMM • Validation on large music database; VB yields fast inference

  16. Demonstration Music Database 525 Jazz 975 Classical 997 Rock Rock Jazz

  17. Classical

  18. Inter-Task Similarity Matrix

  19. Typical Recommendations from Three Genres Classical Jazz Rock

  20. Applications of Interest to Navy • Music search provides a fairly good & objective demonstration of the technology • Other than use of acoustic/speech features (MFCCs), nothing in previous • analysis specifically tied to music – simply data search • Use similar technology for underwater acoustic sensing (MCM) - generative • Use related technology for synthetic aperture radar and EO/IR detection • and classification – discriminative • Technology delivered to NSWC Panama City, and demonstrated independently • on mission-relevant MCM data

  21. Underwater Mine Counter Measures (MCM)

  22. Generative Model - iHMM [Ni & Carin, 07]

  23. Full Posterior on Number of HMM States

  24. Anti-Submarine Warfare (ASW)

  25. Design HMM for all Targets of Interest Over Sensor Lifetime

  26. State Sharing Between ASW Targets

  27. Semi-Supervised Multi-Task Learning

  28. Semi-Supervised Discriminative Multi-Task Learning • Semi-supervised learning implemented via graphical techniques • Multi-task learning implemented via DP • Exploits all available data-driven context • - Data available from previous collections, labeled & unlabeled • - Labeled and unlabeled data from current data set

  29. Graph representation of partially labeled data manifolds (1/2) Construct the graph G=(X,W), with the affinity matrix W, where the (i, j)-th element of W is defined by a Gaussian kernel: Define a Markov random walk on the graph by the transition matrix A, where the (i, j)-th element: which gives the probability of walking from xito xj by a single step Markov random walk. The one-step Markov random walk provides a local similarity measure between data points. [Lu, Liao, Carin; 07] [Szummer & Jaakkola, 02]

  30. Graph representation (2/2) To account for global similarity between data points, we consider a t-step random walk, where the transition matrix is given by A raised to the power of t: It was demonstrated[1] that the t-step Markov random walk would result in a volume of paths connecting the data points in stead of the shortest path that are susceptible to noise; thus it permits us to incorporate global manifold structure in the training data set. The t-step neighborhoodofxi is defined as the set of data points xj with and denoted as [1] Tishby and Slonim, Data clustering by Markovian relaxation and the information bottleneck Method. NIPS 13, 2000

  31. Semi-Supervised Learning Algorithm (1/2) • Neighborhood-based classifier: Define the probability of label yigiven the t-step neighborhood of xi as: where is probability of labeling yigiven a single data point xjand is represented by a standard probabilistic classifier parameterized by • The label yi implicitly propagates over the neighborhood. Thus it is possible to learn a classifier with only a few labels present.

  32. The Algorithm (2/2) • For binary classification problems, we choose the form of as logistic regression classifier: • To enforce sparseness, we impose a normal prior with zero mean and diagonal precision matrix on , and each hyper-parameter has an independent Gamma prior. • Important for transfer learning: The semi-supervised algorithm is inductive and parametric • Place a DP prior on parameters, shared among all tasks

  33. Toy Data for Tasks 1-6

  34. Sharing Data Pooling tasks 1-3 Pooling tasks 1-6

  35. Task similarity for MTL tasks 1-6

  36. Navy-Relevant Data Synthetic Aperture Radar (SAR) Data Collected At 19 Different Locations Across USA

  37. Real Radar Sensor Data • Data from 19 “tasks” or geographical regions • 10 of these regions are relatively highly foliated • 9 regions bare earth, or desert • Algorithm adaptively and autonomously clusters the task-dependent classifier • weights into two basic pools, which agree with truth • Active learning used to define labels of interest for the site under test • Other sites used as auxiliary data, in a “life-long-learning” setting

  38. Supervised MTL: JMLR 07

  39. Previous deployments New deployment • Classifier at new site placed appropriately within context of all available previous data • Both labeled and unlabeled data employed • Found that the algorithm relatively insensitive to particular labeled data selected • Validation with relatively large music database

  40. Reconstruction of Random-Bars with hybrid CS. Example (a) is from [3], and (b-c) are the modified images from (a) by us to represent similar tasks for simultaneous CS inversion. The intensities of all the rectangles are randomly permuted, and the positions of all the rectangles are shifted by distances randomly sampled from a uniform distribution of [-10,10].

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