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 outlier model


Dynamic angular synchronization under smoothness constraints

arXiv.org Machine Learning

Given an undirected measurement graph $\mathcal{H} = ([n], \mathcal{E})$, the classical angular synchronization problem consists of recovering unknown angles $\theta_1^*,\dots,\theta_n^*$ from a collection of noisy pairwise measurements of the form $(\theta_i^* - \theta_j^*) \mod 2\pi$, for all $\{i,j\} \in \mathcal{E}$. This problem arises in a variety of applications, including computer vision, time synchronization of distributed networks, and ranking from pairwise comparisons. In this paper, we consider a dynamic version of this problem where the angles, and also the measurement graphs evolve over $T$ time points. Assuming a smoothness condition on the evolution of the latent angles, we derive three algorithms for joint estimation of the angles over all time points. Moreover, for one of the algorithms, we establish non-asymptotic recovery guarantees for the mean-squared error (MSE) under different statistical models. In particular, we show that the MSE converges to zero as $T$ increases under milder conditions than in the static setting. This includes the setting where the measurement graphs are highly sparse and disconnected, and also when the measurement noise is large and can potentially increase with $T$. We complement our theoretical results with experiments on synthetic data.


Probabilistic Inference of Alternative Splicing Events in Microarray Data

Neural Information Processing Systems

Alternative splicing (AS) is an important and frequent step in mammalian gene expression that allows a single gene to specify multiple products, and is crucial for the regulation of fundamental biological processes. The extent of AS regulation, and the mechanisms involved, are not well un- derstood. We have developed a custom DNA microarray platform for surveying AS levels on a large scale. We present here a generative model for the AS Array Platform (GenASAP) and demonstrate its utility for quantifying AS levels in different mouse tissues. Learning is performed using a variational expectation maximization algorithm, and the parame- ters are shown to correctly capture expected AS trends.


What is predictive analytics? Transforming data into future insights.

#artificialintelligence

Predictive Analytics is a division of advanced analytics which is used to forecast uncertain future events. Predictive analytics make use of an array of technologies from different domains such as data mining, statistics, modeling, machine learning, and artificial intelligence to analyze historic data to forecast the future. It uses a stack of data mining, predictive modeling and analytical methodologies to bring together the management, information technology, and modeling business process to forecast the future. The historical and transactional patterns of data can be used for risk identification and future opportunities. Predictive analytics models detect correlation among many factors to assess risk with a particular set of conditions to give a score or weightage.


Predictive Analytics Insights

#artificialintelligence

Predictive analytics is a data analytics category that helps connect data to meaningful action by drawing accurate predictions about current circumstances and potential events. Enable the company to use predictive modeling to leverage trends detected in historical data to detect possible threats and opportunities before they arise. Here are a few use-cases that demand predictive modeling. Predictive Analytics helps executives and management to scale back risks, optimize operations, and increase revenue. Here are a few examples.


Fast, Parameter free Outlier Identification for Robust PCA

arXiv.org Machine Learning

Robust PCA, the problem of PCA in the presence of outliers has been extensively investigated in the last few years. Here we focus on Robust PCA in the column sparse outlier model. The existing methods for column sparse outlier model assumes either the knowledge of the dimension of the lower dimensional subspace or the fraction of outliers in the system. However in many applications knowledge of these parameters is not available. Motivated by this we propose a parameter free outlier identification method for robust PCA which a) does not require the knowledge of outlier fraction, b) does not require the knowledge of the dimension of the underlying subspace, c) is computationally simple and fast. Further, analytical guarantees are derived for outlier identification and the performance of the algorithm is compared with the existing state of the art methods.


Randomized Robust Subspace Recovery for High Dimensional Data Matrices

arXiv.org Machine Learning

This paper explores and analyzes two randomized designs for robust Principal Component Analysis (PCA) employing low-dimensional data sketching. In one design, a data sketch is constructed using random column sampling followed by low dimensional embedding, while in the other, sketching is based on random column and row sampling. Both designs are shown to bring about substantial savings in complexity and memory requirements for robust subspace learning over conventional approaches that use the full scale data. A characterization of the sample and computational complexity of both designs is derived in the context of two distinct outlier models, namely, sparse and independent outlier models. The proposed randomized approach can provably recover the correct subspace with computational and sample complexity that are almost independent of the size of the data. The results of the mathematical analysis are confirmed through numerical simulations using both synthetic and real data.


Probabilistic Inference of Alternative Splicing Events in Microarray Data

Neural Information Processing Systems

Alternative splicing (AS) is an important and frequent step in mammalian gene expression that allows a single gene to specify multiple products, and is crucial for the regulation of fundamental biological processes. The extent of AS regulation, and the mechanisms involved, are not well understood. We have developed a custom DNA microarray platform for surveying AS levels on a large scale. We present here a generative model for the AS Array Platform (GenASAP) and demonstrate its utility for quantifying AS levels in different mouse tissues. Learning is performed using a variational expectation maximization algorithm, and the parameters are shown to correctly capture expected AS trends. A comparison of the results obtained with a well-established but low throughput experimental method demonstrate that AS levels obtained from GenASAP are highly predictive of AS levels in mammalian tissues.


Probabilistic Inference of Alternative Splicing Events in Microarray Data

Neural Information Processing Systems

Alternative splicing (AS) is an important and frequent step in mammalian gene expression that allows a single gene to specify multiple products, and is crucial for the regulation of fundamental biological processes. The extent of AS regulation, and the mechanisms involved, are not well understood. We have developed a custom DNA microarray platform for surveying AS levels on a large scale. We present here a generative model for the AS Array Platform (GenASAP) and demonstrate its utility for quantifying AS levels in different mouse tissues. Learning is performed using a variational expectation maximization algorithm, and the parameters are shown to correctly capture expected AS trends. A comparison of the results obtained with a well-established but low throughput experimental method demonstrate that AS levels obtained from GenASAP are highly predictive of AS levels in mammalian tissues.


Probabilistic Inference of Alternative Splicing Events in Microarray Data

Neural Information Processing Systems

Alternative splicing (AS) is an important and frequent step in mammalian gene expression that allows a single gene to specify multiple products, and is crucial for the regulation of fundamental biological processes. The extent of AS regulation, and the mechanisms involved, are not well understood. We have developed a custom DNA microarray platform for surveying AS levels on a large scale. We present here a generative model for the AS Array Platform (GenASAP) and demonstrate its utility for quantifying AS levels in different mouse tissues. Learning is performed using a variational expectation maximization algorithm, and the parameters are shown to correctly capture expected AS trends. A comparison of the results obtained with a well-established but low throughput experimental method demonstrate that AS levels obtained from GenASAP are highly predictive of AS levels in mammalian tissues.