Three-dimensional modelling using spatial regression machine learning and hydrogeological basement VES

In this article, we introduce three-dimensional Serious Games (3DSGs) under an evidence-centered design (ECD) framework and use an organizational neuroscience-based eye-tracking measure to capture implicit behavioral signals associated with leadership skills. While ECD is a well-established framework used in the design and development of assessments, it has rarely been utilized in organizational research. The study proposes a novel 3DSG combined with organizational neuroscience methods as a promising tool to assess and recognize leadership-related behavioral patterns that manifest during complex and realistic social situations. We offer a research protocol for assessing task- and relationship-oriented leadership skills that uses ECD, eye-tracking measures, and machine learning. Seamlessly embedding biological measures into 3DSGs enables objective assessment methods that are based on machine learning techniques to achieve high ecological validity. We conclude by describing a future research agenda for the combined use of 3DSGs and organizational neuroscience methods for leadership and human resources.

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Assessing biases, relaxing moralism: On ground-truthing practices in machine learning design and application

Big Data & Society ◽

10.1177/20539517211013569 ◽

2021 ◽

Vol 8 (1) ◽

pp. 205395172110135

Author(s):

Florian Jaton

Keyword(s):

Machine Learning ◽

William James ◽

A Priori ◽

Learning Algorithms ◽

Three Dimensional ◽

Ground Truth ◽

Machine Learning Algorithms ◽

Ground Truthing ◽

Set Up ◽

The Moment

This theoretical paper considers the morality of machine learning algorithms and systems in the light of the biases that ground their correctness. It begins by presenting biases not as a priori negative entities but as contingent external referents—often gathered in benchmarked repositories called ground-truth datasets—that define what needs to be learned and allow for performance measures. I then argue that ground-truth datasets and their concomitant practices—that fundamentally involve establishing biases to enable learning procedures—can be described by their respective morality, here defined as the more or less accounted experience of hesitation when faced with what pragmatist philosopher William James called “genuine options”—that is, choices to be made in the heat of the moment that engage different possible futures. I then stress three constitutive dimensions of this pragmatist morality, as far as ground-truthing practices are concerned: (I) the definition of the problem to be solved (problematization), (II) the identification of the data to be collected and set up (databasing), and (III) the qualification of the targets to be learned (labeling). I finally suggest that this three-dimensional conceptual space can be used to map machine learning algorithmic projects in terms of the morality of their respective and constitutive ground-truthing practices. Such techno-moral graphs may, in turn, serve as equipment for greater governance of machine learning algorithms and systems.

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Supervised machine-learning approach for the optimal arrangement of active hotspots in three-dimensional integrated circuits

IEEE Transactions on Components Packaging and Manufacturing Technology ◽

10.1109/tcpmt.2021.3109662 ◽

2021 ◽

pp. 1-1

Author(s):

Srikanth Rangarajan ◽

Leila Choobineh ◽

Bahgat Sammakia

Keyword(s):

Machine Learning ◽

Integrated Circuits ◽

Three Dimensional ◽

Supervised Machine Learning ◽

Learning Approach ◽

Optimal Arrangement ◽

Machine Learning Approach

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Label-Free Identification of Lymphocyte Subtypes Using Three-Dimensional Quantitative Phase Imaging and Machine Learning

Journal of Visualized Experiments ◽

10.3791/58305 ◽

2018 ◽

Cited By ~ 4

Author(s):

Jonghee Yoon ◽

YoungJu Jo ◽

Young Seo Kim ◽

Yeongjin Yu ◽

Jiyeon Park ◽

...

Keyword(s):

Machine Learning ◽

Three Dimensional ◽

Phase Imaging ◽

Label Free ◽

Quantitative Phase Imaging ◽

Quantitative Phase

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SVFX: a machine-learning framework to quantify the pathogenicity of structural variants

10.1101/739474 ◽

2019 ◽

Cited By ~ 2

Author(s):

Sushant Kumar ◽

Arif Harmanci ◽

Jagath Vytheeswaran ◽

Mark B. Gerstein

Keyword(s):

Machine Learning ◽

Large Scale ◽

Three Dimensional ◽

Point Mutations ◽

Dimensional Structure ◽

Rapid Decline ◽

Ras Signaling ◽

Cancer Genes ◽

Structural Variations ◽

Pathogenic Variants

AbstractA rapid decline in sequencing cost has made large-scale genome sequencing studies feasible. One of the fundamental goals of these studies is to catalog all pathogenic variants. Numerous methods and tools have been developed to interpret point mutations and small insertions and deletions. However, there is a lack of approaches for identifying pathogenic genomic structural variations (SVs). That said, SVs are known to play a crucial role in many diseases by altering the sequence and three-dimensional structure of the genome. Previous studies have suggested a complex interplay of genomic and epigenomic features in the emergence and distribution of SVs. However, the exact mechanism of pathogenesis for SVs in different diseases is not straightforward to decipher. Thus, we built an agnostic machine-learning-based workflow, called SVFX, to assign a “pathogenicity score” to somatic and germline SVs in various diseases. In particular, we generated somatic and germline training models, which included genomic, epigenomic, and conservation-based features for SV call sets in diseased and healthy individuals. We then applied SVFX to SVs in six different cancer cohorts and a cardiovascular disease (CVD) cohort. Overall, SVFX achieved high accuracy in identifying pathogenic SVs. Moreover, we found that predicted pathogenic SVs in cancer cohorts were enriched among known cancer genes and many cancer-related pathways (including Wnt signaling, Ras signaling, DNA repair, and ubiquitin-mediated proteolysis). Finally, we note that SVFX is flexible and can be easily extended to identify pathogenic SVs in additional disease cohorts.

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Enabling Technology for Remote Prosthetic Alignment Tuning

Military Medicine ◽

10.1093/milmed/usaa453 ◽

2021 ◽

Vol 186 (Supplement_1) ◽

pp. 659-664

Author(s):

David A Boone ◽

Sarah R Chang

Keyword(s):

Machine Learning ◽

Learning Algorithm ◽

Three Dimensional ◽

Coordinate Measuring Machine ◽

Software Application ◽

Prosthetic Socket ◽

Prosthetic Alignment ◽

Prosthesis Alignment ◽

Alignment Tool ◽

Measuring Machine

ABSTRACT Introduction This research has resulted in a system of sensors and software for effectively adjusting prosthetic alignment with digital numeric control. We called this suite of technologies the Prosthesis Smart Alignment Tool (ProSAT) system. Materials and Methods The ProSAT system has three components: a prosthesis-embedded sensor, an alignment tool, and an Internet-connected alignment expert system application that utilizes machine learning to analyze prosthetic alignment. All components communicate via Bluetooth. Together, they provide for numerically controlled prosthesis alignment adjustment. The ProSAT components help diagnose and guide the correction of very subtle, difficult-to-see imbalances in dynamic gait. The sensor has been cross-validated against kinetic measurement in a gait laboratory, and bench testing was performed to validate the performance of the tool while adjusting a prosthetic socket based on machine learning analyses from the software application. Results The three-dimensional alignment of the prosthetic socket was measured pre- and postadjustment from two fiducial points marked on the anterior surface of the prosthetic socket. A coordinate measuring machine was used to derive an alignment angular offset from vertical for both conditions: pre- and postalignment conditions. Of interest is the difference in the angles between conditions. The ProSAT tool is only controlling the relative change made to the alignment, not an absolute position or orientation. Target alignments were calculated by the machine learning algorithm in the ProSAT software, based on input of kinetic data samples representing the precondition and where a real prosthetic misalignment condition was known a priori. Detected misalignments were converted by the software to a corrective adjustment in the prosthesis alignment being tested. We demonstrated that a user could successfully and quickly achieve target postalignment change within an average of 0.1°. Conclusions The accuracy of a prototype ProSAT system has been validated for controlled alignment changes by a prosthetist. Refinement of the ergonomic form and technical function of the hardware and clinical usability of the mobile software application are currently being completed with benchtop experiments in advance of further human subject testing of alignment efficiency, accuracy, and user experience.

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Development of a Pattern Recognition Tool for the Classification of Electronic Tongue Signals Using Machine Learning

Chemistry Proceedings ◽

10.3390/csac2021-10447 ◽

2021 ◽

Vol 5 (1) ◽

pp. 21

Author(s):

Edgar G. Mendez-Lopez ◽

Jersson X. Leon-Medina ◽

Diego A. Tibaduiza

Keyword(s):

Machine Learning ◽

Dimensionality Reduction ◽

Performance Measures ◽

Sensor Array ◽

Three Dimensional ◽

Electronic Tongue ◽

Sensor Arrays ◽

Classification Performance ◽

Supervised Machine Learning ◽

Electrochemical Tests

Electronic tongue type sensor arrays are made of different materials with the property of capturing signals independently by each sensor. The signals captured when conducting electrochemical tests often have high dimensionality, which increases when performing the data unfolding process. This unfolding process consists of arranging the data coming from different experiments, sensors, and sample times, thus the obtained information is arranged in a two-dimensional matrix. In this work, a description of a tool for the analysis of electronic tongue signals is developed. This tool is developed in Matlab® App Designer, to process and classify the data from different substances analyzed by an electronic tongue type sensor array. The data processing is carried out through the execution of the following stages: (1) data unfolding, (2) normalization, (3) dimensionality reduction, (4) classification through a supervised machine learning model, and finally (5) a cross-validation procedure to calculate a set of classification performance measures. Some important characteristics of this tool are the possibility to tune the parameters of the dimensionality reduction and classifier algorithms, and also plot the two and three-dimensional scatter plot of the features after reduced the dimensionality. This to see the data separability between classes and compatibility in each class. This interface is successfully tested with two electronic tongue sensor array datasets with multi-frequency large amplitude pulse voltammetry (MLAPV) signals. The developed graphical user interface allows comparing different methods in each of the mentioned stages to find the best combination of methods and thus obtain the highest values of classification performance measures.

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