Scalable Gamma-Driven Multilayer Network for Brain Workload Detection Through Functional Near-Infrared Spectroscopy
Article 2021 en
Authors
EW
Edmond Q. Wu
ZT
Zhi‐Ri Tang
YY
Yuxuan Yao
Abstract
1 min read
This work proposes a scalable gamma non-negative matrix network (SGNMN), which uses a Poisson randomized Gamma factor analysis to obtain the neurons of the first layer of a network. These neurons obey Gamma distribution whose shape parameter infers the neurons of the next layer of the network and their related weights. Upsampling the connection weights follows a Dirichlet distribution. Downsampling hidden units obey Gamma distribution. This work performs up-down sampling on each layer to learn the parameters of SGNMN. Experimental results indicate that the width and depth of SGNMN are closely related, and a reasonable network structure for accurately detecting brain fatigue through functional near-infrared spectroscopy can be obtained by considering network width, depth, and parameters.
Lucas C. Breedt, Giuseppe Pontillo, Fernando AN Santos, Chris Vriend, Ferrán Prados, Alle Meije Wink, Alvino Bisecco, Alessandro Cagol, Massimiliano Calabrese, Marco Castellaro, Sara Collorone, Rosa Cortese, Nicola De Stefano, Christian Enzinger, Massimo Filippi, Michael A. Foster, Antonio Gallo, Gabriel González‐Escamilla, Cristina Granziera, Sergiu Groppa, Einar August Høgestøl, Sara Llufriú, Eloy Martínez‐Heras, ,
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