Electromagnetic Theory and Plasmonics for Engineers

Nickelson, L.

doi:10.1007/978-981-13-2352-2

Cited by 18 publications

(18 citation statements)

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“…Therefore, we have positive Figure 4. But, ΔT depends also on z and should verify (8). T in the next section, we vary z, keeping b) Variation of the position z Th varies linearly as a function of z (see Figure 5) Figure 6 shows that ΔT can be modeled equation 8), as a function of z.…”

Section: Calibration Measurementsmentioning

confidence: 84%

“…Under some conditions (mainly, uniform material, without skin effect), as explained by Nickelson [8], P is given by: where, P is the power lost per unit mass (W/kg), B is the magnetic flux density (T), > REPLACE THIS LINE WITH YOUR PAPER IDENTIFICATION NUMBER (DOUBLE-CLICK HERE TO EDIT) < Another patent application, from Obbard et al [6], describes thermal gradient within living are used, each maintained emperature. Each heat ontact with a thermal conductor, the two conductors on two opposite faces of the sample.…”

Section: Manual Tgg Operationmentioning

confidence: 97%

“…OPERATION Th and Tl be the stabilized temperatures of the upper pectively. Let P be the mass sheet/pellet (induced uniform material, without ickelson [8], P is given by:…”

Section: Manual Tgg Operationmentioning

confidence: 99%

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A Steady-State Thermal Gradient Generator for Material Characterization Using an Induction Heating System

Gunes

Botquelen

Corbel

et al. 2021

IEEE Trans. Instrum. Meas.

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Mobility/Diffusion of ions can occur mainly in two situations. The first one when a potential difference is applied to electrodes of an electrochemical device as in batteries for instance (i.e., charge/discharge). In the second one, the diffusion process is driven by the thermal gradient existing within the material. This paper deals with the design of a controlled Thermal Gradient Generator (TGG) which opens the way to thoroughly study the effect of temperature difference on the chemical diffusion and mechanical resistance of shaped samples (e.g., a pellet, a rod). This TGG uses a combination of two susceptors involving the control of their respective temperatures. One is controlled by adjusting the power of a high frequency generator which supplies an induction heating coil. The other is controlled, mainly, by the displacement of the sample/susceptors set through this same coil, with a motorized stage. The operation and control parameters are defined within a dedicated user-friendly software application. During the whole experiment, the two temperatures can be varied while the inner thermal gradient of the sample is kept constant, as long as these temperatures are high enough.

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Section: Calibration Measurementsmentioning

confidence: 84%

Section: Manual Tgg Operationmentioning

confidence: 97%

See 1 more Smart Citation

A Steady-State Thermal Gradient Generator for Material Characterization Using an Induction Heating System

Gunes

Botquelen

Corbel

et al. 2021

IEEE Trans. Instrum. Meas.

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“…It provides an improved measure of the wrongly classified cases [70][71][72][73][74][75][76]. The formula for the F1 score is given in Equation (11).…”

Section: Averaged Precisionmentioning

confidence: 99%

“…Eddy currents produces losses, which manifest as heat. The magnitude of this loss can be calculated by Equation (1) [11].…”

Section: Introductionmentioning

confidence: 99%

A Multinomial DGA Classifier for Incipient Fault Detection in Oil-Impregnated Power Transformers

2021

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This study investigates the use of machine-learning approaches to interpret Dissolved Gas Analysis (DGA) data to find incipient faults early in oil-impregnated transformers. Transformers are critical pieces of equipment in transmitting and distributing electrical energy. The failure of a single unit disturbs a huge number of consumers and suppresses economic activities in the vicinity. Because of this, it is important that power utility companies accord high priority to condition monitoring of critical assets. The analysis of dissolved gases is a technique popularly used for monitoring the condition of transformers dipped in oil. The interpretation of DGA data is however inconclusive as far as the determination of incipient faults is concerned and depends largely on the expertise of technical personnel. To have a coherent, accurate, and clear interpretation of DGA, this study proposes a novel multinomial classification model christened KosaNet that is based on decision trees. Actual DGA data with 2912 entries was used to compute the performance of KosaNet against other algorithms with multiclass classification ability namely the decision tree, k-NN, Random Forest, Naïve Bayes, and Gradient Boost. Investigative results show that KosaNet demonstrated an improved DGA classification ability particularly when classifying multinomial data.

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