Computational Analysis of Ballistic Saturation Velocity in Low-Dimensional Nano-MOSFET

AbstractIdentifying the stylistic signatures characteristic of different genres is of central importance to literary theory and criticism. In this article we report a large-scale computational analysis of Latin prose and verse using a combination of quantitative stylistics and supervised machine learning. We train a set of classifiers to differentiate prose and poetry with high accuracy (>97%) based on a set of twenty-six text-based, primarily syntactic features and rank the relative importance of these features to identify a low-dimensional set still sufficient to achieve excellent classifier performance. This analysis demonstrates that Latin prose and verse can be classified effectively using just three top features. From examination of the highly ranked features, we observe that measures of the hypotactic style favored in Latin prose (i.e. subordinating constructions in complex sentences, such as relative clauses) are especially useful for classification.

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Single-Cell Gene Expression Profiling and Cell State Dynamics: Collecting Data, Correlating Data Points and Connecting the Dots

10.1101/044743 ◽

2016 ◽

Cited By ~ 1

Author(s):

Carsten Marr ◽

Joseph X. Zhou ◽

Sui Huang

Keyword(s):

Single Cell ◽

Computational Analysis ◽

Expression Profiles ◽

Cell Populations ◽

Monitoring Methods ◽

Time Resolved ◽

Cell State ◽

Data Points ◽

Low Dimensional ◽

Protein Expression Profiles

AbstractSingle-cell analyses of transcript and protein expression profiles – more precisely, single-cell resolution analysis of molecular profiles of cell populations – have now entered the center stage with widespread applications of single-cell qPCR, single-cell RNA-Seq and CyTOF. These high-dimensional population snapshot techniques are complemented by low-dimensional time-resolved, microscopy-based monitoring methods. Both fronts of advance have exposed a rich heterogeneity of cell states within uniform cell populations in many biological contexts, producing a new kind of data that has stimulated a series of computational analysis methods for data visualization, dimensionality reduction, and cluster (subpopulation) identification. The next step is now to go beyond collecting data and correlating data points: to connect the dots, that is, to understand what actually underlies the identified data patterns. This entails interpreting the “clouds of points” in state space as a manifestation of the underlying molecular regulatory network. In that way control of cell state dynamics can be formalized as a quasi-potential landscape, as first proposed by Waddington. We summarize key methods of data acquisition and computational analysis and explain the principles that link the single-cell resolution measurements to dynamical systems theory.

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WGEVIA: A Graph Level Embedding Method for Microcircuit Data

Frontiers in Computational Neuroscience ◽

10.3389/fncom.2020.603765 ◽

2021 ◽

Vol 14 ◽

Author(s):

Xiaomin Wu ◽

Shuvra S. Bhattacharyya ◽

Rong Chen

Keyword(s):

Computational Analysis ◽

Weighted Graph ◽

Graph Embedding ◽

Machine Learning Algorithms ◽

Neural Dynamics ◽

Cognition And Emotion ◽

Neural Activities ◽

Low Dimensional ◽

Embedding Methods ◽

General Method

Functional microcircuits are useful for studying interactions among neural dynamics of neighboring neurons during cognition and emotion. A functional microcircuit is a group of neurons that are spatially close, and that exhibit synchronized neural activities. For computational analysis, functional microcircuits are represented by graphs, which pose special challenges when applied as input to machine learning algorithms. Graph embedding, which involves the conversion of graph data into low dimensional vector spaces, is a general method for addressing these challenges. In this paper, we discuss limitations of conventional graph embedding methods that make them ill-suited to the study of functional microcircuits. We then develop a novel graph embedding framework, called Weighted Graph Embedding with Vertex Identity Awareness (WGEVIA), that overcomes these limitations. Additionally, we introduce a dataset, called the five vertices dataset, that helps in assessing how well graph embedding methods are suited to functional microcircuit analysis. We demonstrate the utility of WGEVIA through extensive experiments involving real and simulated microcircuit data.

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