DAFTAR PUSTAKA 1. Basuki, H. 2008. Merancang, Merencana Lapangan Terbang. Bandung:Penerbit PT.Alumni. 2. Horonjeff, R. dan McKevey, F. 1993. Perencanaan dan Perancangan Bandar Udara. jilid ketiga, Jakarta:Penerbit Erlangga. 3. FAA, Advisory Circular AC-150-5320-6E., 2009.
Airport
Pavemnet Design And Evaluation. United State Of America. 4. FAA, Advisory Circular AC-150/5370-16., 2007. Rapid Construction Of Rigid (Portland Cement Concrete) Airfield Pavements. United State Of America. 5. FAA, Order 5300.7., 2005. Standard Naming Convention for Aircraft Landing Gear Configurations.United State Of America.
6. FAA, Advisory Circular AC-150/5300-13A., 2012. Airport Design. United State Of America 7. International Civil Aviation Organization, ICAO Annex 14., 1999, Aerodrome Design Manual, third edition, Part 3, pavement. 8. Packard, R. 1995. Design Of Concrete Airport Pavement. Engineering Bulletin, Portland Cement Association. 9. Yoder, J. Dan Witczak, W., 1975. Principle Of Pavement Design. Second Edition, London. 10. Huang, Y., 2004. Pavement Analisis And Design. Pearson Education, Upper Saddle Silver, New Jersey.
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11. Kosasih, D., 2005. Rekayasa Stuktur Dan Bahan Perkerasan. Catatan Kuliah Teknik Sipil Dan Lingkungan, Bandung: Penerbit ITB 12. Kosasih, D., 2005. Perancangan Perkerasaan Dan Bahan. Catatan Kuliah DepartemenTeknik Sipil, Bandung: Penerbit ITB 13. Kosasih, D., 2007. Analisis Desain Struktur Perkerasan Kaku Landasan Pesawat Udara Dengan Menggunakan Program Airfield. Jurnal Infrastruktur Dan Lingkungan, Volume 3, Nomor 1, Halaman 36-44. 14. Kawa, I. et al., 2002. Implementation Of Rigid Pavement Thickness Design For New Pavements. Federal Aviation Administration Airport Technology Transfer Confrence, United State Of America. 15. Tipnis, M. Dan Patil, M., 2014. Design Program Based PCN Evaluation Of Aircraft Pavements. FAA Worldwide Airport Technology Transfer Conference, New Jersey, United State Of America 16. Roesler, J. et al., 2007. Effect Of Gear Positions On Airfield Rigid Pavement Critical Stress Locations. FAA Worldwide Airport Technology Transfer Conference, Atlantic City, New Jersey, United State Of America
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17. Shafabakhsh, G. Dan Khasi, E., 2014. Effect of aircraft wheel load and configuration on runway damages. Perodica Polytechnica Civil Engineering, Halaman 85-94. 18. Prihatiningsih, A. Dan Itang, F., 2001. Desain Tebal Perkerasan Kaku Lapangan Terbang Dengan Metode Portland Cement
Association.
Jurnal
teknik
sipil
universitas
tarumanegara, No.2:227-237, Mei 2001. 19. Barman, M. Dan Pandey, B.B., 2008. Backcalculation Of Layer Moduli Of Concrete Pavement By Falling Weight Deflectometer. Paper No.545, Desember 2008. 20. Daggubati, S. et al. 2014. Runway design and structural design of an airfield pavement. e-ISSN: 2278-1684. Volume 11, halaman 10-27. 21. Cojocaru, R., 2011. The Design Of The Airport Rigid Pavement Stucture. Gheorghe Asachi Technical Univrsity Of Lasi, April 2011. 22. Covatariu, G. et al. 2011. Design Of Airport Rigid Runway Structure With Neural Network. Gheorghe Asachi Technical University Of Lasi, September 2011. 23. Shafabakhsh. dan Kashi., 2015 Effect of Aircraft Wheel Load and
Configuration
on
Runway
Damages.
Periodica
Polytechnica Civil Engineering, November 2014. 24. Horonjeff, R., et al . 2010. Planning And Design Of Airport. Fifth Edition, McGraw-Hill Companies, Inc.
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25. Jodi, W., 2015. Airport Of the World. Online, tersedia : http://worldairports.de/index_en.php. 7 maret 2015. 26. http://www.airliners.net , “Characteristic and History Aircraft “ 27. FAA., 2012. Aviation Maintenance Technician Handbook. Volume I, the United States Department of Transportation, Federal Aviation Administration, Oklahoma City.
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