Machine Learning Generalization of Lumped Parameter Models for the Optimal Cooling of Embedded Systems

AbstractThe predictive performance of a machine learning model highly depends on the corresponding hyper-parameter setting. Hence, hyper-parameter tuning is often indispensable. Normally such tuning requires the dedicated machine learning model to be trained and evaluated on centralized data to obtain a performance estimate. However, in a distributed machine learning scenario, it is not always possible to collect all the data from all nodes due to privacy concerns or storage limitations. Moreover, if data has to be transferred through low bandwidth connections it reduces the time available for tuning. Model-Based Optimization (MBO) is one state-of-the-art method for tuning hyper-parameters but the application on distributed machine learning models or federated learning lacks research. This work proposes a framework $$\textit{MODES}$$ MODES that allows to deploy MBO on resource-constrained distributed embedded systems. Each node trains an individual model based on its local data. The goal is to optimize the combined prediction accuracy. The presented framework offers two optimization modes: (1) $$\textit{MODES}$$ MODES -B considers the whole ensemble as a single black box and optimizes the hyper-parameters of each individual model jointly, and (2) $$\textit{MODES}$$ MODES -I considers all models as clones of the same black box which allows it to efficiently parallelize the optimization in a distributed setting. We evaluate $$\textit{MODES}$$ MODES by conducting experiments on the optimization for the hyper-parameters of a random forest and a multi-layer perceptron. The experimental results demonstrate that, with an improvement in terms of mean accuracy ($$\textit{MODES}$$ MODES -B), run-time efficiency ($$\textit{MODES}$$ MODES -I), and statistical stability for both modes, $$\textit{MODES}$$ MODES outperforms the baseline, i.e., carry out tuning with MBO on each node individually with its local sub-data set.

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Online Machine Learning for Energy-Aware Multicore Real-Time Embedded Systems

IEEE Transactions on Computers ◽

10.1109/tc.2021.3056070 ◽

2021 ◽

pp. 1-1

Author(s):

Jose Luis Conradihoffmann ◽

Antonio Augusto Frohlich

Keyword(s):

Machine Learning ◽

Embedded Systems ◽

Real Time ◽

Energy Aware

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Inferring transit time distributions from atmospheric tracer data: Assessment of the predictive capacities of Lumped Parameter Models on a 3D crystalline aquifer model

Journal of Hydrology ◽

10.1016/j.jhydrol.2015.03.055 ◽

2015 ◽

Vol 525 ◽

pp. 619-631 ◽

Cited By ~ 17

Author(s):

J. Marçais ◽

J.-R. de Dreuzy ◽

T.R. Ginn ◽

P. Rousseau-Gueutin ◽

S. Leray

Keyword(s):

Transit Time ◽

Lumped Parameter ◽

Lumped Parameter Models ◽

Crystalline Aquifer ◽

Data Assessment ◽

Atmospheric Tracer

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Lumped parameter models for two-ventricle and healthy and failing extracardiac Fontan circulations

Mathematical Medicine and Biology A Journal of the IMA ◽

10.1093/imammb/dqab012 ◽

2021 ◽

Author(s):

Matthew G Doyle ◽

Marina Chugunova ◽

S Lucy Roche ◽

James P Keener

Keyword(s):

Single Ventricle ◽

Left Ventricular ◽

Sensitivity Analyses ◽

Surgical Strategies ◽

Lumped Parameter ◽

Lumped Parameter Models ◽

Fontan Failure ◽

Existence Of Periodic Solutions ◽

Mathematical Definitions ◽

Extracardiac Fontan

Abstract Fontan circulations are surgical strategies to treat infants born with single ventricle physiology. Clinical and mathematical definitions of Fontan failure are lacking, and understanding is needed of parameters indicative of declining physiologies. Our objective is to develop lumped parameter models of two-ventricle and single-ventricle circulations. These models, their mathematical formulations and a proof of existence of periodic solutions are presented. Sensitivity analyses are performed to identify key parameters. Systemic venous and systolic left ventricular compliances and systemic capillary and pulmonary venous resistances are identified as key parameters. Our models serve as a framework to study the differences between two-ventricle and single-ventricle physiologies and healthy and failing Fontan circulations.

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