Light & Engineering 26 (2)

Volume 26
Date of publication 07/01/2018
Pages 167-173

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LED Industrial Spatial Structure and its Evolution Trend in Hangzhou Bay Area, China . L&E 26 (2) 2018

Articles authors:

Haiwei Fu

Doctor of Engineering, Associate Professor. Graduated from the Shanghai Maritime University. Fellow of the Ningbo University of Technology of China

Abstract

The numbers of spatial scale structural dimensions and associated structural dimensions in the light emitting diode (LED) industry in Hangzhou Bay Area, China since 2002 were estimated through the fractal method for the prediction of the future evolution trend of the industry. We found that the spatial structure of the LED industry in that area is of strong monopoly but tends to be generally optimal and stable. The morphology in which the main enterprises concentrate in a linear space contributes to the interactions among the enterprises; future spatial structure of LED industry in Hangzhou Bay Area will be a stable state. Changes in external environments and the interaction between internal industrial factors constitute the basic dynamic mechanism for the formation and evolution of LED industrial spatial structure in the Hangzhou Bay Area.

References

1. Ciriminna, R., Albanese, L., Meneguzzo, F., Pagliaro, M. LED street lighting: a looking ahead perspective. Green, 2015. V5, #1–6, pp.83–94.
2. Gayral, B. LEDs for lighting: Basic physics and prospects for energy savings. Comptes Rendus Physique, 2017. V18, #7–8, pp.453–461.
3. Khorasanizadeh, H., Parkkinen, J., Parthiban, R., Moore, J D. Energy and economic benefits of LED adoption in Malaysia. Renewable & Sustainable Energy Reviews, 2015. V49, pp.629–637.
4. Duee, D. LED lighting industry: Opportunity or health hazard? Light & Engineering, 2012. V20, #3, pp.23–24.
5. Rammohan, A., Kumar Ramesh, C. A review on effect of thermal factors on performance of high power light emitting diode (HPLED). Journal of Engineering Science and Technology Review, 2016. V9, #4, pp.165–176.
6. Ma, D., Hung, S W. An Integrated Framework for the Selection and Acquisition of Core Technologies: The Case of Taiwan’s LED Industry. Long Range Planning, 2015. V48, #6, pp.381–397.
7. Yushan, C., Biyu, C. Utilizing patent analysis to explore the cooperative competition relationship of the two LED companies: Nichia and Osram. Technological Forecasting and Social Change, 2011. V78, #2, pp.294–302.
8. Kaa, G V D., Greeven, M. LED standardization in China and South East Asia: Stakeholders, infrastructure and institutional regimes. Renewable and Sustainable Energy Reviews, 2017. V72, pp.863–870.
9. Mason, D M. The Hurst phenomenon and the rescaled range statistic. Stochastic Processes and their Applications, 2016. V126, #12, pp.3790–3807.
10. Diez, O., LarrodePellicer, E., MuerzaMarin, V. Improving competitiveness in companies of the automotive supply industry: Twinequipment strategy. DYNA, 2017. V92, #4, pp.380–381.
11. Jing, W., Yixi, C., Xiaohua, L., Yunfei, S., Yachao, B., Jun, W., Yunxi S. Experimental study on optical-thermal associated characteristics of LED car lamps under the action of ionic wind. Microelectronics Reliability, 2018. V82, pp.113–123.
12. Wei, W. The role of the government in the development of the LED industry. Light & Engineering, 2016. V24, #3, pp.128–131.
13. Jurene, S., Jureniene, V. Creative cities and clusters. Transformations in Business & Economics, 2017. V16, #2, pp.214–234.
14. Ikeda, K., Akamatsu, T., Kono, T. Spatial period-doubling agglomeration of a core–periphery model with a system of cities. Journal of Economic Dynamics and Control, 2012. V36, #5, pp.754–778.

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