Neural network modeling of the cellgap process for liquid crystal display fabricated on plastic substrates

Jung Hwan Lee; Dong Hun Kang; Young Don Ko; Jaejin Jang; Dae Shik Seo; Ilgu Yun

doi:10.1016/j.eswa.2007.08.027

Neural network modeling of the cellgap process for liquid crystal display fabricated on plastic substrates

Jung Hwan Lee, Dong Hun Kang, Young Don Ko, Jaejin Jang, Dae Shik Seo, Ilgu Yun

Department of Electrical and Electronic Engineering

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

In this paper, a neural network model is presented to characterize the thickness and the uniformity of the cellgap process for flexible liquid crystal display (LCD). Input factors are explored via a D-optimal design with 15 runs and used as training data in the neural network. In order to verify the fitness of the model, three more runs are added as test data. Latin hypercube sampling and error back-propagation algorithm are used to build the model. Latin hypercube sampling is used to generate initial weights and biases of the network. The thickness of cellgap is measured at five points: one at the center and four at the edges. The average thickness is used as cellgap thickness, and the uniformity is obtained by comparing the thickness at the center and edge points.

Original language	English
Pages (from-to)	1311-1315
Number of pages	5
Journal	Expert Systems with Applications
Volume	35
Issue number	3
DOIs	https://doi.org/10.1016/j.eswa.2007.08.027
Publication status	Published - 2008 Oct

All Science Journal Classification (ASJC) codes

Engineering(all)
Computer Science Applications
Artificial Intelligence

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10.1016/j.eswa.2007.08.027

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title = "Neural network modeling of the cellgap process for liquid crystal display fabricated on plastic substrates",

abstract = "In this paper, a neural network model is presented to characterize the thickness and the uniformity of the cellgap process for flexible liquid crystal display (LCD). Input factors are explored via a D-optimal design with 15 runs and used as training data in the neural network. In order to verify the fitness of the model, three more runs are added as test data. Latin hypercube sampling and error back-propagation algorithm are used to build the model. Latin hypercube sampling is used to generate initial weights and biases of the network. The thickness of cellgap is measured at five points: one at the center and four at the edges. The average thickness is used as cellgap thickness, and the uniformity is obtained by comparing the thickness at the center and edge points.",

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AU - Lee, Jung Hwan

AU - Kang, Dong Hun

AU - Ko, Young Don

AU - Jang, Jaejin

AU - Seo, Dae Shik

AU - Yun, Ilgu

PY - 2008/10

Y1 - 2008/10

N2 - In this paper, a neural network model is presented to characterize the thickness and the uniformity of the cellgap process for flexible liquid crystal display (LCD). Input factors are explored via a D-optimal design with 15 runs and used as training data in the neural network. In order to verify the fitness of the model, three more runs are added as test data. Latin hypercube sampling and error back-propagation algorithm are used to build the model. Latin hypercube sampling is used to generate initial weights and biases of the network. The thickness of cellgap is measured at five points: one at the center and four at the edges. The average thickness is used as cellgap thickness, and the uniformity is obtained by comparing the thickness at the center and edge points.

AB - In this paper, a neural network model is presented to characterize the thickness and the uniformity of the cellgap process for flexible liquid crystal display (LCD). Input factors are explored via a D-optimal design with 15 runs and used as training data in the neural network. In order to verify the fitness of the model, three more runs are added as test data. Latin hypercube sampling and error back-propagation algorithm are used to build the model. Latin hypercube sampling is used to generate initial weights and biases of the network. The thickness of cellgap is measured at five points: one at the center and four at the edges. The average thickness is used as cellgap thickness, and the uniformity is obtained by comparing the thickness at the center and edge points.

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Neural network modeling of the cellgap process for liquid crystal display fabricated on plastic substrates

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