Along with the development of the construction world, formwork has also progressed from being assembled on site to being assembled first at the factory. In Indonesia, many types of formwork have been used, which each have their own advantages and disadvantages. In selecting the type of formwork used, many factors or criteria need to be considered. The purpose of this study is to determine the type of formwork that is relatively best for use in the Holiday Inn Bukit Randu Hotel Project by calculating the weight of the criteria, sub criteria, and also the alternatives used using the Fuzzy AHP Method. Based on the criteria and alternatives that have been compiled by the researcher, as well as the analysis carried out using the Fuzzy AHP method, it is known that metal (system) formwork is the relatively best formwork with the largest final weight of 43.6%, while semi-system formwork with a final weight of 24, 6% and conventional formwork by 31.8%. However, after being reviewed based on the cost aspect, the semi-system formwork is the relatively best formwork to be used in the Holiday Inn Bukit Randu Hotel Project.

Setiyaningsih, W., & Prasetyo, AY (2018). Application of Fuzzy AHP to Improve the Accuracy and Effectiveness of Employee Performance Assessment. Journal of Technology, Information, and Industry, Vol. I, No. 1, 21-33.

Basu, R., & Jha, KN (2016). An AHP Based Model for the Selection of Horizontal Formwork Systems in Indian Residential Construction. International Journal of Structural and Civil Engineering Research Vol. 5, No. 2, 80-86.

Hansen, S., Siregar, PH, & Jevica. (2020). Analytic Hierarchy Process-Based Decision-Making Framework for Formwork System Selection by Contractors. Journal of Construction in Developing Countries, 25(2), 237-255.

Jin, Z., & Gambatese, J. (2020). A Fuzzy Multi-criteria Decision Approach to Technology Selection for Concrete Formwork Monitoring. Construction Research Congress (pp. 76-84). Tempe: ASCE.

Ouchi, F. (2004). A Literature Review on the Use of Expert Opinion in Probabilistic Risk Analysis. World Bank Policy Research Working Paper 3201.

Griffis, FH, Farr, JV, & Morton and Morris. (1999). Construction Planning for Engineers. McGraw-Hill.

Emrouznejad, A., & Ho, W. (2018). Fuzzy Analytic Hierarchy Process. Boca Raton: CRC Press.

Mardhikawarih, DA (2012). Selection of Industrial Lubricant Drum Suppliers Using Fuzzy Analytic Hierarchy Process (Case Study: PT. Pertamina Pusat (Oil Center) and Gresik Production Unit). Surakarta: Eleven March University.

Buckley, J. (1985). Fuzzy Hierarchical Analysis. Fuzzy Sets and Systems 17, 233-247.

Chang, D.-Y. (1996). Applications of the Extent Analysis Method on Fuzzy AHP. European Journal of Operational Research 95 , 649-655. .

Goh, KC, Goh, HH, & Chong, H.-Y. (2019). Integration Model of Fuzzy AHP and Life-Cycle Cost Analysis for Evaluating Highway Infrastructure Investments. Journal of Infrastructure Systems, Volume 25 Issue 1 , 1-12.