Computing the Largest Entries in a Matrix Product via Sampling
Abstract not provided.
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Jump to search filtersTensor Analysis for Sparse Data
Abstract not provided.
Tensor Analysis for Sparse Data
Abstract not provided.
Directed closure measures for networks with reciprocity
Journal of Complex Networks
Abstract not provided.
Tensor Rank Prediction via Cross Validation
Abstract not provided.
Accelerating Community Detection by using k-core subgraphs
Abstract not provided.
Real-Valued Symmetric Tensor Decompositions
Abstract not provided.
Fast Algorithms for Evolving graphs via Assays Sampling & Theory Phase II: Quarter 1 Report
Abstract not provided.
Sandia Software for Networks from DARPA GRAPHS Program
Abstract not provided.
An Adaptive Power Method for the Generalized Tensor Eigenproblem
Abstract not provided.
Analytical and Algorithmic Challenges in Network Analysis
Abstract not provided.
Community Detection for Large Graphs
Abstract not provided.
Generating Large Graphs for benchmarking
Abstract not provided.
Wedge sampling for computing clustering coefficients and triangle counts on large graphs
Statistical Analysis and Data Mining
Graphs are used to model interactions in a variety of contexts, and there is a growing need to quickly assess the structure of such graphs. Some of the most useful graph metrics are based on triangles, such as those measuring social cohesion. Algorithms to compute them can be extremely expensive, even for moderately sized graphs with only millions of edges. Previous work has considered node and edge sampling; in contrast, we consider wedge sampling, which provides faster and more accurate approximations than competing techniques. Additionally, wedge sampling enables estimating local clustering coefficients, degree-wise clustering coefficients, uniform triangle sampling, and directed triangle counts. Our methods come with provable and practical probabilistic error estimates for all computations. We provide extensive results that show our methods are both more accurate and faster than state-of-the-art alternatives. © 2014 Wiley Periodicals, Inc.
An adaptive shifted power method for computing generalized tensor eigenpairs
SIAM Journal on Matrix Analysis and Applications
Several tensor eigenpair definitions have been put forth in the past decade, but these can all be unified under generalized tensor eigenpair framework, introduced by Chang, Pearson, and Zhang [J. Math. Anal. Appl., 350 (2009), pp. 416-422]. Given mth-order, n-dimensional realvalued symmetric tensors A and B, the goal is to find λ ε ℝ and x ε ℝn, x ≠= 0 such that Axm-1 = λBxm-1. Different choices for B yield different versions of the tensor eigenvalue problem. We present our generalized eigenproblem adaptive power (GEAP) method for solving the problem, which is an extension of the shifted symmetric higher-order power method (SS-HOPM) for finding Z-eigenpairs. A major drawback of SS-HOPM is that its performance depended on choosing an appropriate shift, but our GEAP method also includes an adaptive method for choosing the shift automatically.
Newton-based Optimization for Nonnegative Tensor Factorizations
Optimization Methods and Software
Abstract not provided.
Characterizing Networks
Abstract not provided.
The Block Two-level Erdos Renyi (BTER) Graph Model
Abstract not provided.
Maintaining An Online Publication List
Abstract not provided.
An Adaptive Power Method for the Generalized Tensor Eigenproblem
Abstract not provided.
Challenges of Modeling Directed Networks
Abstract not provided.
Newton-Based Optimization for Nonnegative Tensor Factorizations
Proposed for publication in ArXiV, and then SIAM J on Matrix Analysis and Applications.
Abstract not provided.
Analyzing Modeling and Generating BIG Networks
Abstract not provided.
A Scalable Null Model to Match All Degree Distributions: In Out and Reciprocal
Abstract not provided.
On Reciprocity in Massively Multiplayer Online Game Networks
Proposed for publication in arXiv.
Abstract not provided.
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