Present focuses and future directions of decision-making in construction supply chain management: a systematic review

References

• Abune’meh M, El-Meouche R, Hijaze I, Mebarki A, Shahrour I. 2016. Optimal construction site layout based on risk spatial variability. Autom Construct. 70:167–177.
   Web of Science ®Google Scholar
• Ahiaga-Dagbui DD, Smith, SD. 2014. Dealing with construction cost overruns using data mining. Construct Manag Econ. 32(7–8):682–694.
   Google Scholar
• Ahmadian FA, Akbarnezhad A, Rashidi TH, Waller ST. 2016. Accounting for transport times in planning off-site shipment of construction materials. J Construct Eng Manag. 142(1):04015050.
   Web of Science ®Google Scholar
• Ahmadian FF, Rashidi TH, Akbarnezhad A, Waller ST. 2017. BIM-enabled sustainability assessment of material supply decisions. Eng Construct Architect Manag. 24(4):668–695.
   Web of Science ®Google Scholar
• Ahuja R, Sawhney A, Arif M. 2017. Driving lean and green project outcomes using BIM: a qualitative comparative analysis. Int J Sustain Built Environ. 6(1):69–80.
   Google Scholar
• Akanmu A, Olatunji O, Love PE, Nguyen D, Matthews J. 2016. Auto-generated site layout: an integrated approach to real-time sensing of temporary facilities in infrastructure projects. Struct Infrastruct Eng. 12(10):1243–1255.
   Web of Science ®Google Scholar
• Akintoye A, McIntosh G, Fitzgerald E. 2000. A survey of supply chain collaboration and management in the UK construction industry. Eur J Purch Supply Manag. 6(3):159–168.
   Google Scholar
• Ala-Risku T, Kärkkäinen M. 2006. Material delivery problems in construction projects: a possible solution. Int J Prod Econ. 104(1):19–29.
   Web of Science ®Google Scholar
• Alanjari P, Razavialavi S, AbouRizk S. 2014. A simulation-based approach for material yard laydown planning. Autom Construct. 40:1–8.
   Web of Science ®Google Scholar
• Albaloushi H, Skitmore M. 2008. Supply chain management in the UAE construction industry. Int J Construct Manag. 8(1):53–71.
   Google Scholar
• Aloini, D, Dulmin, R, Mininno, V, Ponticelli, S. 2012. Supply chain management: a review of implementation risks in the construction industry. Bus Process Manag J. 18(5):735–761.
   Google Scholar
• Amornsawadwatana S. 2011. Effective design of the construction supply chain: a case of small buildings in Thailand. Paper presented at: IEEM 2011 IEEE International Conference. Proceedings of the Industrial Engineering and Engineering Management (IEEM); Dec 6–9; Singapore.
   Google Scholar
• Aram S, Eastman C, Sacks R. 2013. Requirements for BIM platforms in the concrete reinforcement supply chain. Autom Construct. 35:1–17.
   Web of Science ®Google Scholar
• Azambuja M, O’Brien W. 2009. Construction supply chain modeling: issues and perspectives. Construction Supply Chain Management Handbook. Boca Raton (FL): CRC Press.
   Google Scholar
• Bankvall L, Bygballe LE, Dubois A, Jahre M. 2010. Interdependence in supply chains and projects in construction. Supply Chain Manag: Int J. 15(5):385–393.
   Web of Science ®Google Scholar
• Barker R, Hong-Minh S, Naim MM. 2000. The terrain scanning methodology, assessing and improving construction supply chains. Eur J Purch Supply Manag. 6(3):179–193.
   Google Scholar
• Barlow J, Childerhouse P, Gann D, Hong-Minh S, Naim M, Ozaki R. 2003. Choice and delivery in housebuilding: lessons from Japan for UK housebuilders. Build Res Inform 31(2):134–145.
   Web of Science ®Google Scholar
• Beach R, Webster M, Campbell KM. 2005. An evaluation of partnership development in the construction industry. Int J Proj Manag. 23(8):611–621.
   Google Scholar
• Behera P, Mohanty R, Prakash A. 2015. Understanding construction supply chain management. Prod Plann Contr. 26(16):1332–1350.
   Web of Science ®Google Scholar
• Briscoe G, Dainty A. (2005). Construction supply chain integration: an elusive goal? Supply Chain Manag Int J. 10(4):319–326.
   Web of Science ®Google Scholar
• Briscoe G, Dainty AR, Millett S. 2001. Construction supply chain partnerships: skills, knowledge and attitudinal requirements. Eur J Purch Supply Manag. 7(4):243–255.
   Google Scholar
• Briscoe GH, Dainty AR, Millett SJ, Neale RH. 2004. Client‐led strategies for construction supply chain improvement. Construct Manag Econ. 22(2):193–201.
   Google Scholar
• Bryde D, Broquetas M, Volm JM. 2013. The project benefits of building information modelling (BIM). Int J Proj Manag. 31(7):971–980.
   Web of Science ®Google Scholar
• Bryman A, Bell E. 2015. Business research methods. Oxford (UK): Oxford University Press.
   Google Scholar
• Bygballe LE, Jahre M, Swärd A. 2010. Partnering relationships in construction: a literature review. J Purch Supply Manag. 16(4):239–253.
   Web of Science ®Google Scholar
• Castro-Lacouture D, Medaglia AL, Skibniewski M. 2007. Supply chain optimization tool for purchasing decisions in B2B construction marketplaces. Autom Construct. 16(5):569–575.
   Web of Science ®Google Scholar
• Chan WH, Lu M. 2008. Materials handling system simulation in precast viaduct construction: modeling, analysis, and implementation. J Construct Eng Manag. 134(4):300–310.
   Web of Science ®Google Scholar
• Chen JH, Lin JZ. 2010. Developing an SVM based risk hedging prediction model for construction material suppliers. Autom Construct. 19(6):702–708.
   Web of Science ®Google Scholar
• Chen, JH, Ma SH. 2008. A dynamic reputation incentive model in construction supply chain. Paper presented at: ICMSE 2008. Proceeding of the 15th International Construction Management Science and Engineering; Sep 10–12; Long Beach, USA.
   Google Scholar
• Chen LF, Wu G, Zhang YB. 2011. Construction enterprise supply chain design research. Adv Mater Res.
   PubMedGoogle Scholar
• Cheng JC, Kumar S. 2015. A BIM-based framework for material logistics planning. Proceeding of the 23rd International Group for Lean Construction; July 28–31; Perth: IGLC.
   Google Scholar
• Cheng JC, Law KH, Bjornsson H, Jones A, Sriram R. 2010. A service oriented framework for construction supply chain integration. Autom Construct. 19(2):245–260.
   Web of Science ®Google Scholar
• Childerhouse P, Lewis J, Naim M, Towill DR. 2003. Re-engineering a construction supply chain: a material flow control approach. Supply Chain Manag: Int J. 8(4):395–406.
   Web of Science ®Google Scholar
• Choudhari S, Tindwani A. 2017. Logistics optimisation in road construction project. Construct Innovat. 17(2):158–179.
   Web of Science ®Google Scholar
• Cutting-Decelle AF, Young BI, Das BP, Case K, Rahimifard S, Anumba CJ, Bouchlaghe DM. 2007. A review of approaches to supply chain communications: from manufacturing to construction. J Inform Tech Construct. 12(5):73–102.
   Google Scholar
• Dainty AR, Brooke RJ. 2004. Towards improved construction waste minimisation: a need for improved supply chain integration? Struct Surv. 22(1):20–29.
   Google Scholar
• Dainty AR, Millett SJ, Briscoe GH. 2001. New perspectives on construction supply chain integration. Supply Chain Manag: Int J. 6(4): 163–173.
   Google Scholar
• Dave B, Kubler S, Främling K, Koskela L. 2016. Opportunities for enhanced lean construction management using Internet of Things standards. Autom Construct. 61:86–97.
   Web of Science ®Google Scholar
• Dave B, Kubler S, Pikas E, Holmström J, Singh V, Främling K, Koskela L. 2015. Intelligent Products: Shifting the Production Control Logic in Construction (with Lean and BIM). Proceeding of the 23rd Annual Conference of the International Group for Lean Construction, July 29–31; Perth: IGLC.
   Google Scholar
• Doran D, Giannakis M. 2011. An examination of a modular supply chain: a construction sector perspective. Supply Chain Manag: Int J. 16(4):260–270.
   Web of Science ®Google Scholar
• El-Ghazali Y, Lefebvre E, Lefebvre LA. 2011. RFID-enabled materials management in the industrial construction supply chain. Proceedings of the 5th International Conference on Communications and Information Technology; Jul 14–17; Greece.
   Google Scholar
• Emuze F, Smallwood J. 2013. Lean supply chain decisions implications for construction in a developing economy. Proceeding of the 21th Annual Conference of the International Group for Lean Construction; July 21; Fortaleza.
   Google Scholar
• Eriksson, PE. 2010. Improving construction supply chain collaboration and performance: a lean construction pilot project. Supply Chain Manag: Int J. 15(5):394–403.
   Web of Science ®Google Scholar
• Eriksson, PE. 2015. Partnering in engineering projects: four dimensions of supply chain integration. J Purch Supply Manag. 21(1):38–50.
   Web of Science ®Google Scholar
• Errasti A, Beach R, Oyarbide A, Santos J. 2007. A process for developing partnerships with subcontractors in the construction industry: an empirical study. Int J Proj Manag. 25(3):250–256.
   Google Scholar
• Fearne A, Fowler N. 2006. Efficiency versus effectiveness in construction supply chains: the dangers of “lean” thinking in isolation. Supply Chain Manag: Int J. 11(4):283–287.
   Web of Science ®Google Scholar
• Gan VJ, Cheng JC. 2015. Formulation and analysis of dynamic supply chain of backfill in construction waste management using agent-based modeling. Adv Eng Informat. 29(4):878–888.
   Web of Science ®Google Scholar
• Govindan K, Azevedo S, Carvalho H, Cruz-Machado V. 2015. Lean, green and resilient practices influence on supply chain performance: interpretive structural modeling approach. Int J Environ Sci Tech. 12(1):15–34.
   Web of Science ®Google Scholar
• Hall M, Holt R, Graves A. 2000. Private finance, public roads: configuring the supply chain in PFI highway construction. Eur J Purch Supply Manag. 6(3):227–235.
   Google Scholar
• Hammad A, Akbarnezhad A, Rey D. 2016. A multi-objective mixed integer nonlinear programming model for construction site layout planning to minimise noise pollution and transport costs. Autom Construct. 61:73–85.
   Web of Science ®Google Scholar
• Hammad A, Rey D, Akbarnezhad A. 2017. A cutting plane algorithm for the site layout planning problem with travel barriers. Comput Oper Res. 82:36–51.
   Web of Science ®Google Scholar
• Han KK, Golparvar-Fard M. 2017. Potential of big visual data and building information modeling for construction performance analytics: an exploratory study. Autom Construct. 73:184–198.
   Web of Science ®Google Scholar
• Hinkka V, Tätilä J. 2013. RFID tracking implementation model for the technical trade and construction supply chains. Autom Construct. 35:405–414.
   Web of Science ®Google Scholar
• Irizarry J, Karan EP, Jalaei F. 2013. Integrating BIM and GIS to improve the visual monitoring of construction supply chain management. Autom Construct. 31: 241–254.
   Web of Science ®Google Scholar
• Jian-hua C, Wan T. 2010. Time-cost trade-off problem in construction supply chain: a bi-level programming decision model. Procceding of the International Conference Management Science and Engineering (ICMSE); Nov 24–26; P.R. China.
   Google Scholar
• Khalfan M, Khan H, Maqsood T. 2015. Building information model and supply chain integration: a review. J Econ Bus Manag. 3(9):912–916.
   Google Scholar
• Khalfan MM, Anumba CJ, Siemieniuch CE, Sinclair, MA. 2001. Readiness assessment of the construction supply chain for concurrent engineering. Eur J Purch Supply Manag. 7(2):141–153.
   Google Scholar
• Khalfan MM, McDermott P, Swan W. 2007. Building trust in construction projects. Supply Chain Manag: Int J. 12(6):385–391.
   Web of Science ®Google Scholar
• Kumar SS, Cheng JC. 2015. A BIM-based automated site layout planning framework for congested construction sites. Autom Construct. 59:24–37.
   Web of Science ®Google Scholar
• Lee WJ, Song JH, Kwon SW, Chin S, Choi C, Kim YS. 2008. A gate sensor for construction logistics. Proceedings of the 25th International Symposium on Automation and Robotics in Construction, Jun 26–29; Vilnius, Lithuania.
   Google Scholar
• Leiras A, de Brito JrI, Queiroz-Peres E, Rejane-Bertazzo T, Yoshizaki TYH. 2014. Literature review of humanitarian logistics research: trends and challenges. Human Logis Supply Chain Manage. 4(1):95–130.
   Google Scholar
• Lin Y, Tserng H. 2001. A model of supply chain management for construction using information technology. Proceedings of the XVIII Symposium of Automation and Robotics in Construction; Sep 10–12; Krakow, Poland.
   Google Scholar
• Liu A. 2014. Study on a construction supply chain partner selection model based on the integration of multi-suppliers. Proceeding of the International Conference on Construction and Real Estate Management; Sep 27–28; Kunming.
   Google Scholar
• Liu Q, Tao Z. 2015. A multi-objective optimization model for the purchasing and inventory in a three-echelon construction supply chain. Proceedings of the 9th International Conference on Management Science and Engineering Management; Jul 21–23; Karlsruhe, Germany.
   Google Scholar
• Lin X., Ho CM, Shen GQ. 2017. Research on corporate social responsibility in the construction context: a critical review and future directions. Int J Construct Manag. 1:11.
   Google Scholar
• Lönngren HM, Rosenkranz C, Kolbe H. 2010. Aggregated construction supply chains: success factors in implementation of strategic partnerships. Supply Chain Manag: Int J. 15(5):404–411.
   Web of Science ®Google Scholar
• Love PE, Irani Z, Edwards DJ. 2004. A seamless supply chain management model for construction. Supply Chain Manag: Int J. 9(1):43–56.
   Web of Science ®Google Scholar
• Matthews J, Pellew L, Phua F, Rowlinson S. 2000. Quality relationships: partnering in the construction supply chain. Int J Qual Reliab Manag. 17(4/5):493–510.
   Google Scholar
• McDermotti P, Khalfan M. 2012. Achieving supply chain integration within construction industry. Construct Econ Buil. 6(2):44–54.
   Google Scholar
• Meng X. 2010. Assessment framework for construction supply chain relationships: development and evaluation. Int J Proj Manag. 28(7):695–707.
   Web of Science ®Google Scholar
• Mohammaddust F, Rezapour S, Farahani RZ, Mofidfar M, Hill A. 2015. Developing lean and responsive supply chains: a robust model for alternative risk mitigation strategies in supply chain designs. Int J Prod Econ.
   Web of Science ®Google Scholar
• Ng ST, Li W. 2006. A parallel bargaining protocol for automated sourcing of construction suppliers. Autom Construct. 15(3):365–373.
   Web of Science ®Google Scholar
• Ning X, Ding L, Luo H, Qi S. 2016. A multi-attribute model for construction site layout using intuitionistic fuzzy logic. Autom Construct. 72:380–387.
   Web of Science ®Google Scholar
• O’Brien WJ, London K, Vrijhoef R. 2004. Construction supply chain modeling: a research review and interdisciplinary research agenda. J Oper Manag. 3(3):64–84.
   Google Scholar
• Palaneeswaran E, Kumaraswamy MM, Zhang XQ. 2001. Reforging construction supply chains: a source selection perspective. Eur J Purch Supply Manag. 7(3):165–178.
   Google Scholar
• Papadonikolaki E, Vrijhoef R, Wamelink H. 2015. Supply chain integration with BIM: a graph-based model. Struct Surv. 33(3):257–277.
   Google Scholar
• Papadopoulos GA, Zamer N, Gayialis SP, Tatsiopoulos IP. 2016. Supply chain improvement in construction industry. Univers J Manag. 4(10):528–534.
   Google Scholar
• Pinho T, Telhada J, Carvalho MS. 2007. Definition of a supply chain management model in construction – case study. Proceeding of the 15th Annual Conference of the International Group for Lean Construction, Jul 18–20; MI.
   Google Scholar
• Polat G, Arditi D, Mungen U. 2007. Simulation-based decision support system for economical supply chain management of rebar. J Construct Eng Manag. 133(1):29–39.
   Web of Science ®Google Scholar
• Qu T, Nie D, Chen X, Chen X, Dai Q, Huang GQ. 2015. Optimal configuration of cluster supply chains with augmented Lagrange coordination. Comput Ind Eng. 84:43–55.
   Web of Science ®Google Scholar
• RazaviAlavi S, AbouRizk S. 2015. A hybrid simulation approach for quantitatively analyzing the impact of facility size on construction projects. Autom Construct. 60:39–48.
   Web of Science ®Google Scholar
• RazaviAlavi S, AbouRizk S. 2017. Site layout and construction plan optimization using an integrated genetic algorithm simulation framework. J Comput Civ Eng. 31(4):04017011.
   Web of Science ®Google Scholar
• Saad M, Jones M, James P. 2002. A review of the progress towards the adoption of supply chain management (SCM) relationships in construction. Eur J Purch Supply Manag. 8(3):173–183.
   Google Scholar
• Sacks R, Koskela L, Dave BA, Owen, R. 2010. Interaction of lean and building information modeling in construction. J Construct Eng Manag. 136(9):968–980.
   Web of Science ®Google Scholar
• Said H, El-Rayes K. 2010a. Optimizing material procurement and storage on construction sites. J Construct Eng Manag. 137(6):421–431.
   Web of Science ®Google Scholar
• Said H, El-Rayes K. 2010b. Optimizing the planning of construction site security for critical infrastructure projects. Autom Construct. 19(2):221–234.
   Web of Science ®Google Scholar
• Said H, El-Rayes K. 2013. Optimal utilization of interior building spaces for material procurement and storage in congested construction sites. Autom Construct. 31:292–306.
   Web of Science ®Google Scholar
• Said H, El-Rayes, K. 2014. Automated multi-objective construction logistics optimization system. Autom Construct. 43:110–122.
   Web of Science ®Google Scholar
• Sarker BR, Egbelu PJ, Liao TW, Yu J. 2012. Planning and design models for construction industry: a critical survey. Autom Construct. 22:123–134.
   Web of Science ®Google Scholar
• Serpell A, Heredia B. 2004. Supply chain management in construction: diagnosis and application issues. International Symposium on Globalisation and Construction Conference Centre; Nov 17–19; Bangkok.
   Google Scholar
• Seuring S, Gold S. 2012. Conducting content-analysis based literature reviews in supply chain management. Supply Chain Manag: Int J. 17(5):544–555.
   Web of Science ®Google Scholar
• Shi Q, Ding X, Zuo J, Zillante G. 2016. Mobile Internet based construction supply chain management: a critical review. Autom Construct. 72:143–154.
   Web of Science ®Google Scholar
• Simatupang, T. M, Sridharan, R. 2016. A critical analysis of supply chain issues in construction heavy equipment. Int J Construct Manag. 16(4):326–338.
   Web of Science ®Google Scholar
• Sobotka A, Czarnigowska A. 2005. Analysis of supply system models for planning construction project logistics. J Civ Eng Manag, 11(1):73–82.
   Google Scholar
• Soibelman L, Caldas C. 2000. Information logistics for construction design team collaboration. Procceding of the 8th International Conference on Computing in Civil and Building Engineering; Aug 14–16; Standford, USA.
   Google Scholar
• Soltani A, Fernando T. 2004. A fuzzy based multi-objective path planning of construction sites. Autom Construct. 13(6):717–734.
   Web of Science ®Google Scholar
• Song JH, Lee NS, Yoon SW, Kwon SW, Chin S, Kim YS. 2007. Material tracker for construction logistics. Proceedings of the 24th international symposium on automation and robotics in construction, ISARC; Sep 19–21; Madras, India.
   Google Scholar
• Song X, Xu J, Shen C, Peña-Mora F, Zeng Z. 2017. A decision making system for construction temporary facilities layout planning in large-scale construction projects. Int J Civ Eng. 15(2):333–353.
   Google Scholar
• Soroor J, Tarokh MJ, Abedzadeh, M. 2012. Automated bid ranking for decentralized coordination of construction logistics. Autom Construct. 24:111–119.
   Web of Science ®Google Scholar
• Srivastava SK. 2007. Green supply‐chain management: a state‐of‐the‐art literature review. Int J Manag Rev. 9(1):53–80.
   Web of Science ®Google Scholar
• Stadtler H. 2015 Supply chain management: an overview. In: Stadtler H, Kilger C, Meyr H, editors. Supply chain management and advanced planning. Springer Texts in Business and Economics. Berlin, Germany: Springer.
   Google Scholar
• Stevens GC, Johnson M. 2015. Integrating the supply chain… 25 years on. Int J Phys Distrib Logist Manag. 46(1):19–42.
   Web of Science ®Google Scholar
• Tah J, Carr V. 2001. Towards a framework for project risk knowledge management in the construction supply chain. Adv Eng Software. 32(10):835–846.
   Web of Science ®Google Scholar
• Tah, JH. 2005. Towards an agent-based construction supply network modelling and simulation platform. Autom Construct. 14(3):353–359.
   Web of Science ®Google Scholar
• Tennant S, Fernie S. 2014. Theory to practice: a typology of supply chain management in construction. Int J Construct Manag. 14(1):56–66.
   Google Scholar
• Thunberg M, Persson F. 2014. Using the SCOR model’s performance measurements to improve construction logistics. Prod Plann Contr. 25(13–14):1065–1078.
   Web of Science ®Google Scholar
• Tillmann P, Viana D, Sargent Z, Tommelein I, Formoso, C. 2015. BIM and lean in the design-production interface of ETO components in complex projects. Proceeding of the 23rd Annual Conference of the International Group for Lean Construction; Jul 28–31; Perth.
   Google Scholar
• Tiwari R, Shepherd H, Pandey R. 2014. Supply chain management in construction: a literature survey. Int J Manag Res Bus Strat. 3(1):7–28.
   Google Scholar
• Tserng HP, Dzeng RJ, Lin YC, Lin ST. 2005. Mobile construction supply chain management using PDA and bar codes. Comput Aided Civ Infrastruct Eng. 20(4):242–264.
   Web of Science ®Google Scholar
• Tserng HP, Lin PH. 2002. An accelerated subcontracting and procuring model for construction projects. Autom Construct. 11(1):105–125.
   Web of Science ®Google Scholar
• Vaidyanathan K. 2009. Overview of IT applications in the construction supply chain. Construction supply chain management handbook. Boca Raton (FL): CRC Press.
   Google Scholar
• Vaidyanathan K, Howell G. 2007 . Construction supply chain maturity model–conceptual framework. Proceeding of the 15th Annual Conference of the International Group for Lean Construction; Jul 18–20; MI.
   Google Scholar
• Vidalakis C, Tookey JE, Sommerville J. 2011. The logistics of construction supply chains: the builders’ merchant perspective. Eng Construct Architect Manag. 18(1):66–81.
   Google Scholar
• Voigtmann J, Bargstädt HJ. 2010 . Construction logistics planning by simulation. Proceedings of the 2010 Winter Simulation Conference; Dec 5–10; Baltimore, MD.
   Google Scholar
• Vrijhoef R, Koskela L. 2000. The four roles of supply chain management in construction. Eur J Purch Supply Manag. 6(3):169–178.
   Google Scholar
• Vrijhoef R, Koskela L, Howell G. 2001 . Understanding construction supply chains: an alternative interpretation. Proceedings of 9th International Group for Lean Construction Conference; Aug 6–8; Singapore.
   Google Scholar
• Vrijhoef R, Ridder H. 2007. Supply chain systems engineering in construction. Proceeding of Conference of the CIB World Building Congress; May 14–17; Cape Town.
   Google Scholar
• Wang LC, Lin YC, Lin PH. 2007. Dynamic mobile RFID-based supply chain control and management system in construction. Adv Eng Informat. 21(4):377–390.
   Web of Science ®Google Scholar
• Wegelius-Lehtonen T. 2001. Performance measurement in construction logistics. Int J Prod Econ, 69(1):107–116.
   Web of Science ®Google Scholar
• Wei B, Ying DF. 2013. Selecting service suppliers in construction supply chains with a critical chain model. Appl Mech Mater. 411–414: 2645–2650.
   Google Scholar
• Xiang D, Qian L. 2012. Study on partner selection method for construction supply chain using tabu-search algorithm. Proceeding of the International Conference on Information Management, Innovation Management and Industrial Engineering; Oct 20–21; Sanya, China.
   Google Scholar
• Xue X, Li X, Shen Q, Wang Y. 2005. An agent-based framework for supply chain coordination in construction. Autom Construct. 14(3):413–430.
   Web of Science ®Google Scholar
• Xue X, Wang Y, Shen Q, Yu X. 2007. Coordination mechanisms for construction supply chain management in the Internet environment. Int J Proj Manag. 25(2):150–157.
   Google Scholar
• Yeo KT, Ning J. 2006. Managing uncertainty in major equipment procurement in engineering projects. Eur J Oper Res. 171(1):123–134.
   Web of Science ®Google Scholar
• Ying F, Tookey J, Roberti J. 2014. Addressing effective construction logistics through the lens of vehicle movements. Eng Construct Architect Manag. 21(3):261–275.
   Google Scholar
• Zeng Y, Xiao R. 2014. Modelling of cluster supply network with cascading failure spread and its vulnerability analysis. Int J Prod Res. 52(23):6938–6953.
   Web of Science ®Google Scholar
• Zhang H, Fan X. 2010. Research on improved multi-objective optimized model of profit allocation in construction supply chain. Proceeding of the International Conference of service operation and logistics; Oct 12–15; Beijing.
   Google Scholar
• Zhou J. 2008. The optimization mode for construction supply chain management based on information techniques. Proceeding of the International Conference on Information Management, Innovation Management and Industrial Engineering; Oct 20–21; Taipei, Taiwan.
   Google Scholar