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., Tianjin Polytechnic University, Tianjin 300160,China 2Institute of Physics, Chinese Academy of Sciences, Beijing 100080,China a Niupingjuan@tjpu.edu.cn, b Hu_hairong2002@yahoo.com.cn , cWerfriend@126.com, d Wxwang@aphy.iphy.ac.cn, e Shangxunzhong@yahoo.com.cn Keywords：Resonant Tunnelling Diode (RTD); Heterojunction Phototransistor Transistor (HPT); Monolithic Integration; Negative resistance device Abstract：We designed the monolithic opto-electronic integrated circuit composed by Resonant Tunnelling Diodes (RTD) and Heterojunction Phototransistor (HPT).
The material structure and technological process of the device is introduced in detail.
[4] S.Noda, Y.Kobayashi, T.Takayama, K.Shibata and A.Sasaki:IEEE Journal of Quantum Electronics, Vol.28(1992), p.2714

Smith, NanoTest On-line Help File Version 1.0 and NanoTest Manual Version 3.0, Micro Materials Ltd, 2006
Erkens, International Journal of Materials Research and Advanced Techniques, Vol. 93 (2002), p. 862
Erkens, Materials Characterization, Vol. 49 (2003), p. 149
Cremer, Advanced Engineering Materials, Vol. 10 No.7 (2008), p. 634
Etzkorn, Surface and Coatings Technology, Volumes 163-164 (2003), p. 75 [11] Helmut Mehrer, Diffusion in solids, Fundamentals, Methods, Materials, DiffusionControlled Processes, Springer Series in Solid-State Science, 155, Springer-Verlag Berlin Heidelberg, 2007

According to the characteristics of group enterprises, manufacturing resources were analyzed and classified into human, equipment, materials, cooperation resources and so on.
According to enterprise hierarchical structure, there are five levels including enterprise, factories, work shops, work teams and facilities; According to the use purpose, manufacturing resources are divided into seven types’ resources including collaboration, service, human resource, material, facilities, application software and data.
The virtual resources of cloud manufacturing include not only software, simulation tools and information, but also facilities, materials and other hardware resources.
Acknowledgements This research is sponsored by Ministry of Education, Humanities and Social Sciences of China (No. 12YJCZH209, 12YJAZH151) References [1] B.h.
Journal of System Simulation,2009,21(17):5292-5299

An Application of Fuzzy Fault Tree Analysis for Large and Medium-sized Pumping Stations Qiulin Cao1, a, Xinghua Wang1, b 1 Hydraulic Science and Engineering College of Yangzhou University, Yangzhou, Jiangsu, China a cqlshy@163.com, b wangxinghua_85sh@163.com Keywords: Fault tree method; Minimal cut sets; Structural importance; Risk analysis.
The risk is quantified in order to facilitate the analysis and comparison and provide a reliable basis for scientific decision-making of the pumping stations management, then limited human, materials and financial resources can be utilized by a reasonable manner, and the most appropriate measures will be adopted to achieve the ultimate goal of complete elimination of risks.
Heilongjiang Science and Technology of Water Conservancy (2010,38(1):135-136).
Journal of Data Acquisition & Processing (2002,17(3):342).
Journal of Jilin University(Engineering and Technology Edition) (2010,40(4):978).

Field Synergy Analysis for Inclusion Removal in the Continuous Casting Tundish Zhang Meijie1,a, Lin Xiaolong1,b, Gu Huazhi1,c, Zhu Hongxi1,d , Deng Chengji1,eand Xin Zhanwu2,f 1Wuhan University of Science and Technology, the Hubei Province Key Laboratory of Refractories and Ceramics,Wuhan 430081, China 2Shanxi Taigang Staianless Steel CO. , LTD. , Iron works,Taiyuan 030003,China amajor6886@126.com, bst6540@163.com, cguhuazhi@163.com, dzhuhongxi@wust.edu.cn, ecjdeng@wust.edu.cn, fxin22597@163.com Keywords: Continuous tundish; Inclusion removal; Field synergy Abstract.
Flow control equipments should be established in order to improve the small size inclusions removal. 5 Acknowledgment This work is supported by the State Key Development Program for Basic Research of China ( 2009CB62600 ) and Natural Science Foundation of Hubei Province of China ( 2009CDZ010 ). 6 References [1] Asish Kumar Sinha and Yogeshwar Sahai: ISIJ Intern.
THOMAS: Metallurgical and Materials Transactions B Vol. 30B (1999), p. 639 [4] Anil KUMAR, Satish C.
KORIA and Dipak MAZUMDAR: ISIJ Intern., Vol. 44 (2004), p.1334 [5] ZHENG Shu-guo and ZHU Miao-yong: The Chinese Journal of Process Engineering Vol. 41 (2006), p. 522 [6] Z.Y.
Heat Mass Transfer, Vol. 41 (1998), p. 2221 [7] Guo Z.Y., Li D.Y. and Wang B.X.: International Journal of Heat and Mass Transfer Vol. 41 (1998), p. 2221 [8] W.Q.

Acknowledgements This work was supported by the China Postdoctoral Science Foundation funded project (20100481095; 2012T50437), and by the funded project of Jiangsu Water Conservancy (2012086), and by the funded project of key Laboratory of Modern Agricultural Equipment and Technology (NZ201010), The authors would like to thank the financial support.
Journal of Hazardous Materials, Vol. 174(2010), p. 45-462
Journal of Environmental Sciences, Vol. 18(2006), p. 1216-1220

Correlation Analysis between Single Nucleotide Polymorphism of Fatty Acid Synthase and Fatness Traits in Chickens Yuxiang Wang College of Animal Science and Technology, Northeast Agricultural University, Harbin 150030, China wyx405@163.com Keywords: fatty acid synthase gene, single nucleotide polymorphism, abdominal fat, chicken Abstract.
Materials and methods Experimental chickens and trait determination The experimental chickens are the hybrid F2 population from star broilers and silky blackbone chickens in China Agricultural University.
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Three-Dimensional Crack Propagation Analysis based on VCCM (Virtual Crack Closure-Integral Method) for Tetrahedral Finite Element Hiroshi Okada1, a, Hiroshi Kawai2,b, Kousuke Araki1,c and Tsubasa Miyazaki1,d 1 Department of Nano-structure and Advanced Materials, Kagoshima University, Korimoto 1-21-40, Kagoshima 890-0065, Japan 2 Department of System Design Engineering, Keio University, 3-14-1 Hiyoshi, Kohokuku, Yokohama 233-0051, Japan a okada@mech.kagoshima-u.ac.jp, bkawai@noguchi.sd.keio.ac.jp, ckousuke@po3.synapse.ne.jp, d m788027@mech.kagoshima-u.ac.jp Keywords: Fracture mechanics, Crack propagation analysis, Stress intensity factor, Finite element method, Virtual crack closure-integral method Abstract.
(Japan Society of Computational Engineering and Science) Vol. 12 (2007), p. 411
[9] Okada, H. and Kamibeppu, T.: CMES: Computer Modeling in Engineering & Sciences, Vol. 10 (2005), p. 229
[13] Erdogan, F. and Sih, G.C.: Journal of Basic Engineering Vol. 85 (1963), p.519
[14] dell'Erba, D.N. and Aliabadi, M.H.: International Journal of Fatigue Vol. 22 (2001), p. 261

In recent years, the international academic community and the engineering community are very optimistic about the application prospects and market potential of the PCMM[3], and have invested human and material resources to conduct research and development.
And the distance parameter settings consist of pre-contact distance which is the distance between the edge of probe and contact point of the part surface measured, search range which sets the maximum distance along the internal parts material when the probe gets into the pre-contact distance, safe distance which is the distance between the position point and safe surface, rollback distance which is the distance that the probe withdrawed when the first contact finished, and the rollback distance must be large enough to ensure the probe can safely reach the next one pre-contact point or position point
This research is supported by the Natural Science Foundation of Shandong Education Department of china(Grant No.
[7] Dengqing Kong, Jun Wu, et al: Journal of mechanical engineering Vol 45(2009), p. 152
[8] Guoqin GAO, Xiaoqin YIN, Lvzhong MA, et al:Chinese Journal of Scientific Instrument Vol 27(2006), p. 49.

Pisano1, 2 1Department of Electrical Engineering & Computer Sciences, University of California, Berkeley, California 94720, USA 2Berkeley Sensor & Actuator Center, University of California, Berkeley, California 94720, USA anuozhang@eecs.berkeley.edu Keywords: Silicon Carbide (SiC), 4H-SiC, Bipolar Junction Transistor (BJT), High Temperature Characterization Abstract.
Pisano, “Harsh Environment Silicon Carbide Sensors for Health and Performance Monitoring of Aerospace Systems: a Review,” IEEE Sensors Journal, vol. 9, no. 11, pp. 1472-1478, 2009
Neudeck, “Progress in Silicon Carbide Semiconductor Electronics Technology,” Journal of Electron Material, vol. 24, no. 4, pp. 283-288, 1995
Agarwal, “Low and High Temperature Performance of 600V 4H-SiC Epitaxial Emitter BJTs,” Material Science Forum, vols. 483-485, pp. 909-912, 2005