Walk the Line: Optimizing the Layout Design of Moving Walkways

References

• Airport Council International (2019) Preliminary world airport traffic rankings released. Accessed August 1, 2019, www.aci.aero/news/2019/03/13/preliminary-world-airport-traffic-rankings-released/.Google Scholar
• Airport Council International-Europe (2019) Top 30 European airports 2018. Accessed August 1, 2019, www.aci-europe.org.Google Scholar
• Ahn HK, Alt H, Asano T, Bae SW, Brass P, Cheong O, Knauer C, Na H-S, Shin C-S, Wolff A (2009) Constructing optimal highways. Internat. J. Foundations Comput. Sci. 20(1):3–23.Crossref, Google Scholar
• Asimov I (1954) Caves of Steel (Random House Publishing Group, New York).Google Scholar
• Atallah MJ, Kosaraju SR (1988) Efficient solutions to some transportation problems with applications to minimizing robot arm travel. SIAM J. Comput. 17:849–869.Crossref, Google Scholar
• Boysen N, Briskorn D, Emde S (2018) Scheduling electric vehicles and locating charging stations on a path. J. Scheduling 21:111–126.Crossref, Google Scholar
• Boysen N, Briskorn D, Schwerdfeger S, Stephan K (2021) Carpool formation along high-occupancy vehicle lanes. Eur. J. Oper. Res. 293(3):1097–1112.Google Scholar
• Bureau of Public Roads (1964) Traffic assignment manual for application with a large, high speed computer. Report, Bureau of Public Roads, U.S. Department of Commerce, Urban Planning Division, Washington, DC.Google Scholar
• Cardinal J, Collette S, Hurtado F, Langerman S, Palop B (2008) Optimal location of transportation devices. Comput. Geometry 41(3):219–229.Crossref, Google Scholar
• Chiang PN, Taaffe K (2011) Analysis of conveyance system use in airport concourses. J. Transportation Engrg. 138:485–493.Crossref, Google Scholar
• Cote A, Gempp A (1997) The high-speed passenger conveyor-reflections on comfort. Proc. Sixth Internat. Conf. Automated People Movers, Las Vegas, Nevada, 634–643.Google Scholar
• Cullinane S (2002) The relationship between car ownership and public transport provision: A case study of Hong Kong. Transportation Policy 9:29–39.Crossref, Google Scholar
• Díaz-Báñez JM, Korman M, Pérez-Lantero P, Ventura I (2013) The 1-median and 1-highway problem. Eur. J. Oper. Res. 225:552–557.Crossref, Google Scholar
• Díaz-Báñez JM, Korman M, Pérez-Lantero P, Ventura I (2014) Locating a single facility and a high-speed line. Eur. J. Oper. Res. 236:69–77.Crossref, Google Scholar
• Díaz-Báñez JM, Korman M, Pérez-Lantero P, Ventura I (2016) The 1-center and 1-highway problem revisited. Ann. Oper. Res. 246:167–179.Crossref, Google Scholar
• Dorndorf U, Drexl A, Nikulin Y, Pesch E (2007) Flight gate scheduling: State-of-the-art and recent developments. Omega 35:326–334.Crossref, Google Scholar
• Espejo I, Rodríguez-Chía AM (2011) Simultaneous location of a service facility and a rapid transit line. Comput. Oper. Res. 38:525–538.Crossref, Google Scholar
• Florian M, Hearn D (1995) Network equilibrium models and algorithms. Ball MO, Magnanti TL, Monma CL, Nemhauser GL, eds. Network Routing, Handbooks in Operations Research and Management Science, vol. 8 (Elsevier, Amsterdam), 485–550.Google Scholar
• Gilmore PC, Gomory RE (1964) Sequencing a one state-variable machine: A solvable case of the traveling salesman problem. Oper. Res. 12(5):655–679.Link, Google Scholar
• Gonzalez Alemany M, Soffritti M, Behrend M, Eisele T (2007) TurboTrack: Making long distances shorter. ThyssenKrupp Techforum 1(1):68–75.Google Scholar
• Guan DJ (1998) Routing a vehicle of capacity greater than one. Discrete Appl. Math. 81:41–57.Crossref, Google Scholar
• Heinlein RA (1940) The roads must roll. Robert S, ed. The Science Fiction Hall of Fame, vol. 1 (Tom Doherty Associates), 1929-1964.Google Scholar
• Jeanbart C, Molyneaux N, Scarinci R, Bierlaire M (2018) Multi-objective optimization of moving walkway networks in transportation hubs. Working paper, École Polytechnique Fédérale de Lausanne, Lausanne, Switzerland.Google Scholar
• Kone (2016) Planning guide for Kone escalators & autowalks. Accessed June 1, 2019, https://www.kone.us/Images/KONE-Escalator-AutoWalk-Planning-Guide_tcm25-18783.pdf.Google Scholar
• Korman M, Tokuyama T (2008) Optimal insertion of a segment highway in a city metric. Internat. Comput. Combinatorics Conf. (Springer, Berlin), 611-620.Google Scholar
• Körner MC, Mesa JA, Perea F, Schöbel A, Scholz D (2014) A maximum trip covering location problem with an alternative mode of transportation on tree networks and segments. TOP 22:227–253.Crossref, Google Scholar
• Kusumaningtyas I (2009) Mind your step: Exploring aspects in the application of long accelerating moving walkways. PhD thesis, Delft University of Technology, Delft, Netherlands.Google Scholar
• Kusumaningtyas I, Lodewijks G (2008) Accelerating moving walkway: A review of the characteristics and potential application. Transportation Res. Part A: Policy Practice 42:591–609.Crossref, Google Scholar
• Kusumaningtyas I, Lodewijks G (2013) On the application of accelerating moving walkways to support passenger processes in Amsterdam Airport Schiphol. Transportation Planning Tech. 36:617–635.Crossref, Google Scholar
• Lam WH, Lee JY, Cheung CY (2002) A study of the bi-directional pedestrian flow characteristics at Hong Kong signalized crosswalk facilities. Transportation 29:169–192.Crossref, Google Scholar
• Loder J (1998) The in-line accelerating moving walkway. Elevator World (September):94–97.Google Scholar
• Lorimer H (2016) Walking: New forms and spaces for studies of pedestrianism. Geographies of Mobilities: Practices, Spaces, Subjects (Routledge, Oxfordshire, UK), 31–46.Google Scholar
• Nikolić M, Bierlaire M, de Lapparent M, Scarinci R (2019) Multiclass speed-density relationship for pedestrian traffic. Transportation Sci. 53(3):642–664.Abstract, Google Scholar
• Psaraftis H, Solomon M, Magnanti T, Kim T-U (1990) Routing and scheduling on a shoreline with release times. Management Sci. 36(2):212–223.Link, Google Scholar
• Scarinci R, Markov I, Bierlaire M (2017) Network design of a transport system based on accelerating moving walkways. Transportation Res. Part C: Emerging Tech. 80:310–328.Crossref, Google Scholar
• Scarinci R, Bahrami F, Ourednik A, Bierlaire M (2017) An exploration of moving walkways as a transport system in urban centers. Eur. J. Transportation Infrastructure Res. 17:191–206.Google Scholar
• Schiphol (2019) Airport maps. Accessed August 1, 2019, www.schiphol.nl/en/airport-maps.Google Scholar
• Shirakihara T (1997) Speedwalk: An accelerating moving walkway. Proc. Sixth Internat. Conf. Automated People Movers, Las Vegas, Nevada, 624–633.Google Scholar
• Simchi-Levi D, Berman O (1992) Minimizing the total flow time of n jobs on a network. IIE Trans. 23(3):236–244.Crossref, Google Scholar
• Thelle MH, Sonne MLC (2018) Airport competition in Europe. J. Air Transportation Management 67:232–240.Crossref, Google Scholar
• ThyssenKrupp (2018) Accel: Fostering urban mobility. Accessed June 1, 2019, http://accel.thyssenkrupp-elevator.com/.Google Scholar
• Tough JM, O’Flaherty CA (1971) Passenger Conveyors: An Innovatory Form of Communal Transport (Ian Allan, London).Google Scholar
• Tsitsiklis JN (1992) Special cases of traveling salesman and repairman problems with time windows. Networks 22:263–282.Crossref, Google Scholar
• Wells HG (1897) A Story of the Days to Come (Horizon Publishing Group, Hammond, IN).Google Scholar
• Young S (1995) Analysis of moving walkway use in airport terminal corridors. Transportation Res. Rec. (1506):44–51.Google Scholar
• Young S (1999) Evaluation of pedestrian walking speeds in airport terminals. Transportation Res. Rec. (1674):20–26.Crossref, Google Scholar
• Yu W, Liu Z (2009) Vehicle routing problems on a line-shaped network with release time constraints. Oper. Res. Lett. 37:85–88.Crossref, Google Scholar
• Yang H, Bell MGH (1998) Models and algorithms for road network design: A review and some new developments. Transportation Rev. 18:257–278.Crossref, Google Scholar