1,258 research outputs found
Lower bounds on the rank and symmetric rank of real tensors
We lower bound the rank of a tensor by a linear combination of the ranks of
three of its unfoldings, using Sylvester's rank inequality. In a similar way,
we lower bound the symmetric rank by a linear combination of the symmetric
ranks of three unfoldings. Lower bounds on the rank and symmetric rank of
tensors are important for finding counterexamples to Comon's conjecture. A real
counterexample to Comon's conjecture is a tensor whose real rank and real
symmetric rank differ. Previously, only one real counterexample was known. We
divide the construction into three steps. The first step involves linear spaces
of binary tensors. The second step considers a linear space of larger
decomposable tensors. The third step is to verify a conjecture that lower
bounds the symmetric rank, on a tensor of interest. We use the construction to
build an order six real tensor whose real rank and real symmetric rank differ.Comment: 26 pages, 3 figures, v2: updated to match published versio
Identifiability of overcomplete independent component analysis
Independent component analysis (ICA) studies mixtures of independent latent
sources. An ICA model is identifiable if the mixing can be recovered uniquely.
It is well-known that ICA is identifiable if and only if at most one source is
Gaussian. However, this applies only to the setting where the number of sources
is at most the number of observations. In this paper, we generalize the
identifiability of ICA to the overcomplete setting, where the number of sources
exceeds the number of observations. We give an if and only if characterization
of the identifiability of overcomplete ICA. The proof studies linear spaces of
rank one symmetric matrices. For generic mixing, we present an identifiability
condition in terms of the number of sources and the number of observations. We
use our identifiability results to design an algorithm to recover the mixing
matrix from data and apply it to synthetic data and two real datasets.Comment: 28 pages, 7 figure
DiGiME: An Interactive Experience to Ease the Education of Social Information Sharing
Ever since digital and social media activities made their way into our day-to-day lives, things have become very different. People are continuously glued to their mobile devices, including children. Besides the tv screen time, mobile media time for 0-to-8 year-olds has tripled between 2013 and 2017, from an average of 15 minutes per day to 48 minutes per day1. As digital exposure is increasing at earlier ages, the danger of social information sharing increases as well.
Children do not often realize that they are giving out a vast quantity of their personal information, and even their parents\u27 to the internet while being online. They are a particular vulnerable population when speaking of digital marketing and advertising - they could be easily manipulated and persuaded towards sharing their personal information and using the services or products.
This thesis project intends to raise awareness about the impact of online safety among children and their parents, and also seeks to explore the possible communicational ways of helping parents helping their kids better protect their online user data in the meantime. The goal is to find an easy tool to serve as an easy-to-learn life lesson for both the kids and their parents, with parents leading the way. And the project should communicate the idea of safety does not happen by accident and people should help their loved ones better manage and protect their online data
Carbothermal Synthesis of Spherical AlN Fillers
Micro-sized spherical AlN particles have presented great commercial potential as thermally conductive fillers for high-performance thermal interface materials, benefiting from their high thermal conductivity and good fluidity in the polymers. In this chapter, recent research progress in the carbothermal synthesis of spherical AlN fillers is highlighted. The influences of various synthetic parameters, including N2 gas pressure, additive content, additive particle size, reaction temperature, reaction time, carbon content, and additive types, on the nitridation rate and the particle size and morphology of final AlN powders are summarized. More importantly, the growth mechanism of micro-sized spherical AlN granules is deeply discussed as well
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