Al Transmittance Estimator for Multi-Layer Coating TP Film

Yu Ju Chen; Jui Chen Chien; Chuo Yean Chang; Shu Ming T. Wang; Yu Chen Chiang; Rey Chue Hwang

doi:10.4028/www.scientific.net/AMM.312.996

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 312Al Transmittance Estimator for Multi-Layer Coating...

Al Transmittance Estimator for Multi-Layer Coating TP Film

Abstract:

This research aims to develop an artificial intelligence (AI) estimator for the coating touch panel (TP) film. The AI estimator could estimate the transmittance of touch panel (TP) with different layers coating. It also could be used for helping the technician precisely set the relevant control parameters of evaporator in advance so that the optical quality of TP film could fit the customers request. In order to catch the unknown relationship between the films transmittance and its all possible influencing factors, the neural network (NN) is taken as the AI tool. In other words, a fast and precise intelligent manufacturing mechanism for TP evaporation process is expected to be developed and this intelligent mechanism could be practically used in the real industrial applications.

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Periodical:

Applied Mechanics and Materials (Volume 312)

Pages:

996-1000

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.312.996

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Online since:

February 2013

Authors:

Yu Ju Chen, Jui Chen Chien, Chuo Yean Chang, Shu Ming T. Wang, Yu Chen Chiang, Rey Chue Hwang

Keywords:

Artificial Intelligence (AI), Coating, Estimator, Neural Network (NN), Touch Panel

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References

[1] Dmitruk N.L., Korovin A.V. (2005) Generalized analytical model for the calculation of light transmittance through a thin conducting film. Thin Solid Films 484(1-2):382-388

DOI: 10.1016/j.tsf.2005.01.088

Google Scholar

[2] Wu Y.T., Weng X.L., Deng L.J. (2006) Transmittance and electromagnetic shielding of ITO films deposited at low temperature. Zhenkong Kexue Yu Jishu Xuebao/Journal of Vacuum Science and Technology 26(5):372-376

Google Scholar

[3] Wang K., Jia H.Z., Xia G.Z. (2008) Determination of optical parameters in thin films by transmittance spectra. Spectroscopy and Spectral Analysis 28(11):2713-2716

Google Scholar

[4] Kim D.H., Yoon H.K., Shih D.H., Murakami R.I. (2007) Electromagnetic wave shielding properties of ITO/PET thin film by film thickness. In The Proceedings of 10th International Conference on the Mechanical Behaviour of Materials 345-346 (II):1585-1588

DOI: 10.4028/www.scientific.net/kem.345-346.1585

Google Scholar

[5] Gupta R.K., Ghosh K., Mishra S.R., Kahol P.K. (2008) Electrical and optical properties of high mobility W-doped In2O3 thin films. In 2008 Materials Research Society Symposium, Large-Area Processing and Patterning for Active Optical and Electronic Devices 1030:34-39

DOI: 10.1557/proc-1030-g03-19

Google Scholar

[6] Feng C., Liu K., Wu J.S., Liu L., Cheng J.S., Zhang Y.Y., Sun Y.H., Li Q.Q., Fan S.S., Jiang K. (2010) Flexible, stretchable, transparent conducting films made from superaligned carbon nanotubes. Advanced Functional Materials 20(6):885-891

DOI: 10.1002/adfm.200901960

Google Scholar

[7] Chen S., Billings S., Grant P. (1990) Non-linear system identification using neural networks. International Journal of Control 51:1191-1214

DOI: 10.1080/00207179008934126

Google Scholar

[8] Khotanzad A., Hwang R.C., Abaye A., Maratukulam D. (1995) An adaptive modular artificial neural network: Hourly load forecaster and its implementation at electric utilities. IEEE Transactions on Power Systems 10:1716-1722

DOI: 10.1109/59.466468

Google Scholar

[9] Hwang R.C., Chen Y.J., Huang H.C. (2010) Artificial intelligent analyzer for mechanical properties of rolled steel bar by using neural networks. Expert Systems With Applications, 37(4):3136-3139

DOI: 10.1016/j.eswa.2009.09.069

Google Scholar

[10] Chen H.C., Chen Y.J., Chang C.Y., Hsu P.T., Wang S.M.T., Hwang R. C. (2012) The QNN transmittance estimator of TP film with two layers coating for electronic appliance. Lecture Notes in Electrical Engineering, Advances in Mechanical and Electronic Engineering 177: 215–220

DOI: 10.1007/978-3-642-31516-9_36

Google Scholar

[11] Wang S.M.T., Huang D.J., Yang J.P., Chen Y.J., Huang H.C., Hwang R. C. (2011) The transmittance estimations of TP Film with Cr and Cr2O3 Coating. 2011 IEEE International Conference on Signal Processing, Communications and Computing. 1080-1083

DOI: 10.1109/icspcc.2011.6061566

Google Scholar

[12] Huang D.J., Yang J.P., Chen Y.J., Liu F.T., Chang C.Y., Hwang R.C. (2010) Transmittance estimation of TP decoration film by QNN. The Fourth International Conference on Genetic and Evolutionary Computing 122-125

DOI: 10.1109/icgec.2010.38

Google Scholar