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Enhanced Accuracy Navigation Solutions Realized Through SINS/GPS Integrated Navigation System Outamazirt Fariz 1a, Muhammad Ushaq 2b,Lin Yan 3c, Fu Li 4d 1PhD Candidate School of Automation Science and Electrical Engg, Beihang University,37 Xue Yuan Lu Haidian Distric Beijing, People Republic of China 2PhD Candidate School of Instrumentation Science and Optoelectronics Engg, Beihang University,37 Xue Yuan Lu Haidian Distric Beijing, People Republic of China 3,4Professor School of Automation Science and Electrical Engg , Beihang University,37 Xue Yuan Lu Haidian Distric Beijing, People Republic of China aoutamazirt.fariz@gmail.com,bushaq71@yahoo.com,clinyanee2@yahoo.com.cn, dfuli@buaa.edu.cn Keywords: Inertial Navigation, Integrated Navigation, GPS, Kalman Filtering Abstract: Strapdown Inertial Navigation Systems (SINS) displays position errors which grow with time in an unbounded manner.
JIA, “Simulation of INS/CNS/GPS Integrated Navigation [J],” Journal of Chinese Inertial Technology, vol. 6, p. 1, 2002
Fang, “An Improved and Efficient Algorithm for SINS/GPS/Doppler Integrated Navigation Systems [J],” Applied Mechanics and Materials, vol. 245, no. 4, pp. 323–329, 2013

Effect of Wet Storage on High Yield Pulping with H2O2/CoSO4 Zhen Shang a, Bing Sun*,a, Yuxin Liub , Hong Li a, Renchao Zhu a, Li Bao a 1The Research Center of Pulp and Paper Engineering, Kunming University of Science and Technology, Kunming Yunnan province, 650500, P.R.
Experimental Material.
Acknowledgments This work was financially supported by Plan Projects of Science and Technology Department in Yunnan Province (Grant no, 2009ZC011X, 2009ZC010X).
Chemical Engineer and Advanced Material, 2012, Vol. ( 468 – 471 ) , p. 1211-1215
Journal of South China Normal University(Natural Science Edition), 2004 (4):84-88.

Manufacturing Process Design Based on Mental and Physical Workload Analysis QingGuo Ma1,a, XiaoLi Sun1,b, HuiJian Fu1,c, DaChun Zhao2,d, JunFeng Guo3,e 1 Department of Management Science and Engineering, Zhejiang University, Hangzhou, China 2 Hangzhou Zhongheng Electric Co., Ltd., Hangzhou, China 3 Hangzhou HuaLi Measuring Appliance Co.
Acknowledgement This work was supported by grant No. 70772048, 90924304 from the National Natural Science Foundation, No. 09JZD0006 from the State Education Ministry of China as a key project.
Theoretical Issues in Ergonomics Science. 4(1-2)(2003) , p. 113-131
Applied Mechanics and Materials. 220(2012), p. 193-197
Journal of Medical and Biological Engineering. 25(1)(2004), p. 15-20

Materials and Methods Earthworms Earthworms of the species Eisenia fetida were purchased from Jiang Liming Earthworm Farm Co., Ltd.
* This work is supported by China National Science Foundation (30760049) and China National Key Sciences and Technology Program for Water solutions (2009ZX07102-004).
Velikodvorskaia, et al, “Evolution of the response to heat shock in genus Drosophila,” Russian Journal of Genetics, vol.38, 2002, pp.925–936
Plytycz, “Thermal shock induced expression of HSP70 and HSP72 proteins in coelomocytes of the earthworm Eisenia fetida,” Central European Journal of Immunology, vol.26, 2001, pp.88–92
Shi etc, “both typical Chlorophenol of mantis brain tissue of fish eggs from stress-induced HSP70 of the Chinese,” Environmental Science, vol.27, 2007, pp.260 – 263

Predicting Protein Subcellular Localization Using the Algorithm of Increment Of Diversity Combined with Weighted K-Nearest Neighbor Zeyue Wu 1, a, Yuehui Chen 2,b 1Department of Information Science and Engineering, University of Jinan, Jinan, 250022, China 2Department of Information Science and Engineering, University of Jinan, Jinan, 250022, China afly1024@126.com, byhchen@ujn.edu.cn Keywords: subcellular localization; feature extraction; increment of diversity;Weighted K-Nearest Neighbor Abstract.
Materials and methods Dataset Two datasets are adopted to validate the availability of our classifier.
Acknowledgment This research was partially supported by the Natural Science Foundation of China (61070130), the Key Project of Natural Science Foundation of Shandong Province (ZR2011FZ003), the Key Subject Research Foundation of Shandong Province and the Shandong Provincial Key Laboratory of Network Based Intelligent Computing.
References [1] Deng, M., Zhang, K., Mehta, S., Chen, T., Sun, F., Prediction of Protein Function Using Protein–protein Interaction Data, Journal of computational biology,2003, pp.947–960
Shi, Prediction of Protein Subcellular Localization Based on Hilbert-Huang Transform,Wuhan university journal of natural sciences,2012, pp.048-054

It is therefore necessary to find other uses for these materials.
High-alumina materials require grogs with a high content of Al2O3, which is usually supplemented in the form of non-clay materials.
The synthetic materials typically come in the form of a fine powder.
The experiment used only two raw materials - FBC and technical Al2O3.
American Journal of Materials Science and Engineering. vol. 4, no. 1 (2016): 7-12. doi:10.12691/ajmse-4-1-2 [4] Herainová, M.

.), can be widely used in many fields and popular, from the start, become one of the hotspot in research of nano materials.
In indoor air conditioner evaporator and filtering online load containing gold and silver nano TiO2 materials, can effectively reduce the indoor formaldehyde content.
In air conditioning indoor evaporator and filter the Internet use nano TiO2 antibacterial materials, within 24 h can make real the kill 80% of the bacteria in the air in the room.
Mishing, in: Diffusion Processes in Advanced Technological Materials, edtied by D.
Journal of Institute of Chemists(India), 1993, 25:83-98

The thermal conductivity analysis of Sip/ Al base composites LI Ming1,a, HAO Hai2,b, SONG Yingde3,c, ZHANG Xingguo3,c 1,2,3 School of Materials Science and Engineering, Dalian University of Technology Dalian , China, 116024 agnimil861025@163.com, bhaohai@dlut.edu.cn, cjyayd12@163.com, zxgwj@dlut.edu.cn Keywords: Aluminum base composites; thermal conductivity; Sip / Al composites Abstract: Aluminum base composites with particles reinforced have high thermal conductivity, low thermal expansion coefficient, low density, and excellent working ability.
Introduction In recent years, with the development of aviation, aerospace, energy, marine engineering and transportation, the performance of materials have been demanded increasingly, they should have high strength, low density, high hardness and good toughness, fatigue resistance and wear resistance [1,2].But the traditional materials can’t achieve the above requirements, exploit new materials which possess excellent performance to meet the requirements is an extremely urgency.
The Sip/Al composites which developed latest, made up for the inherent defects of traditional electronic packaging materials.
Based on this, the Sip/Al composites as electronic packaging materials is a good choice [7, 8].
take use of electronic packaging, Technology of Aerospace Materials Vol.6 (2005), p.44 [9] G.H.Wu,Z.Y.Xiu,Zhang Qiang: The researches on thermophysical properties of new Sip/4032Al of composites, Technology of Aerospace Materials Vol.2 (2007), p.26 [10] Shi Feng,R.F.Qian,Z.P.Zhang: The preparation of SiCp/Al composites by pressure-less infiltration, Bulletin boa Fig.4 rd of silicate, Vol. 2 (2004), p.60 [11] M.Battabyal, O.Beffort, S.Kleiner et al: Heat transport across the metal-diamond interface, Diamond & Related Materials Vol.17 (2008), p.1438

The density and mechanical properties of sintered and sintered forged materials are shown in Table 2 which presents the difference of two kinds of materials.
The mechanical properties increase about 10% after the materials were forged.
This is consistent with the superplastic mechanism of ceramic materials.
[10] Fumihiro Wakai, Naoki Kondo and Yutaka Shinoda: Solid State & Material Science Vol. 4 (1999), pp.461
Han: Key Engineer Materials.

In this era, the material input is gradually giving way to information and knowledge sharing.
Acknowledgement This paper is supported by national natural science foundation of China (71002008), human-society science research project of education ministry (10YJC630314) and Zhejiang Provincial Natural Science Foundation of China (Y7100050).
International Journal of Production Economics, 1998, 55:281－294
British Journal of Management, 1996.7:63-80