An integrated model using the Taguchi method and artificial neural network to improve artificial kidney solidification parameters

Shie, An-Jin; Lo, Kuei-Hsing; Lin, Wen-Tsann; Juan, Chi-Wen; Jou, Yung‐Tsan

doi:10.1186/s12938-019-0696-4

Cited by 4 publications

(3 citation statements)

References 28 publications

(34 reference statements)

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“…An important process to execute the Taguchi method is the selection and design of an Orthogonal Array (OA). The Taguchi OA is written in the form L b A c ( ) where A is the number of experiments, b is the number of level and c is the level of each factor [24]. By using full factorial design, the OA can have 3 27 3 = experimental runs.…”

Section: Orthogonal Arraymentioning

confidence: 99%

Optimized design of carbon nanotube field-effect transistor using Taguchi method for enhanced current ratio performance

Abdul Hadi,

Hussin,

Muhamad

et al. 2024

Phys. Scr.

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Presently, the integrated circuit (IC) industry grapples with obstacles in downsizing MOSFET technology further, hindered by its inherent physical constraints. Therefore, the substitution of silicon with carbon nanotubes (CNTs) holds promise for paving a novel path in semiconductor industries, driven by their diminutive dimensions and superior electrical properties. Hence, this project employed SILVACO ATLAS software in conjunction with the Taguchi method to refine a CNTFET design for optimal performance. In this work, response variables consists of on-current (Ion), current ratio (Ion/Ioff) and threshold voltage (Vth) are extracted. In this particular design, the Taguchi method was employed to ascertain the most effective combination of design parameters and materials to achieve optimal CNTFET performance, as assessed by the three key response variables. The design parameter and material that had been chosen were the diameter of carbon nanotube (Dcnt), dielectric material (K) and oxide thickness (tox). Each of the design parameters and material had three different values. For K, the values are 3.9 (SiO2), 25 (ZrO2) and 80 (TiO2). While for Dcnt and tox, the values are 4.0 nm, 6.0 nm, 8.0 nm and 2.0 nm, 4.0 nm, 6.0 nm respectively. According to the Taguchi optimization findings, the ideal combination of parameters comprises a CNT diameter of 4.0 nm, an oxide thickness of 2.0 nm, and the use of TiO2 (80) as the dielectric material. The ANOVA analysis underscores the significance of prioritizing optimization efforts towards the CNT diameter parameter. This is attributed to its substantial contribution, accounting for 93.55% of the variation in the Ion/Ioff value, surpassing the influence of dielectric materials and oxide thickness.

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Section: Orthogonal Arraymentioning

confidence: 99%

Optimized design of carbon nanotube field-effect transistor using Taguchi method for enhanced current ratio performance

Abdul Hadi,

Hussin,

Muhamad

et al. 2024

Phys. Scr.

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“…The number of combinations to be considered can be reduced if we design the analyses using the experimental design method established by R. A. Fisher [31] or, even better, the Taguchi method [32], which is a robust design method originally developed to improve the quality of a product. This method has been recently applied to problems in engineering, biotechnology [33][34][35][36][37][38], and biomedicine [39][40][41][42]. The aim of this study is to investigate an optimum setting for robust TTF therapy.…”

Section: Introductionmentioning

confidence: 99%

Application of the Taguchi method to explore a robust condition of tumor-treating field treatment

2022

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Tumor-treating fields have potential as minimally invasive cancer treatment. This study aimed to explore the optimum tumor-treating field conditions that minimize unpredicted variations in therapeutic outcomes resulting from differences in cell size and electrical properties. The electric field concentration that induces a dielectrophoretic force near the division plane of a mitotic cell was calculated by finite element analysis for 144 cases, based on different combinations of six noise factors associated with cells and four controllable factors including frequency, as determined by the Taguchi method. Changing the frequency from 200 to 400 kHz strongly increased robustness in producing a dielectrophoretic force, irrespective of noise factors. However, this frequency change reduced the force magnitude, which can be increased by simply applying a higher voltage. Based on additional simulations that considered this trade-off effect, a frequency of 300 kHz is recommended for a robust TTF treatment with allowable variations. The dielectrophoretic force was almost independent of the angle of applied electric field deviated from the most effective direction by ±20 degrees. Furthermore, increased robustness was observed for extracellular fluid with higher conductivity and permittivity. The Taguchi method was useful for identifying robust tumor-treating field therapy conditions from a considerably small number of replicated simulations.

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“…[25,26] Taguchi is a well-known process optimization method based on multistep planning, execution, and evaluation of experimental matrix results to determine the optimized control factors. [27] The Taguchi method orthogonal arrays are a set of experiments, variables, and levels with unique orthogonal array architecture. Using such arrays can determine the number of tests required for a set of factors without losing credibility.…”

Section: Introductionmentioning

confidence: 99%

Optimization of Process‐Control Parameters for the Diameter of Electrospun Hydrophilic Polymeric Composite Nanofibers

Güler

Alenezi

Çam

et al. 2021

Macro Materials & Eng

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A composite nanofiber composed of three polymers, namely polyvinyl alcohol/polyvinyl pyrrolidone/polyethylene oxide, is produced. The experiments are constructed using three design of experiment techniques, Taguchi L 9 , Taguchi L 27 , and Screening method. The experiments are verified using the analysis of variance (ANOVA) method and later a mathematical model is developed using the regression method. The impact of electrospun processing parameters, namely applied voltage, flow rate, and working distance, on nanofibers' diameter is measured. The working distance is a significant factor in controlling the size of the fiber diameter, while the applied voltage has the lowest effect on it. As a result of the regression equation, a Genetic algorithm is used to find the optimum variables for the required fiber diameter, which is 156 nm for flow rate = 0.001 mL h −1 , voltage = 30 kV, and distance = 200 mm with a 3% difference from the experimental fiber diameter.

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An integrated model using the Taguchi method and artificial neural network to improve artificial kidney solidification parameters

Cited by 4 publications

References 28 publications

Optimized design of carbon nanotube field-effect transistor using Taguchi method for enhanced current ratio performance

Optimized design of carbon nanotube field-effect transistor using Taguchi method for enhanced current ratio performance

Application of the Taguchi method to explore a robust condition of tumor-treating field treatment

Optimization of Process‐Control Parameters for the Diameter of Electrospun Hydrophilic Polymeric Composite Nanofibers

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