Lorentzian-geometry-based analysis of airplane boarding policies highlights "slow passengers first" as better

We study airplane boarding in the limit of a large number of passengers using geometric optics in a Lorentzian metric. The airplane boarding problem is naturally embedded in a (1+1)-dimensional space-time with a flat Lorentzian metric. The duration of the boarding process can be calculated based on...

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Published in	Physical review. E Vol. 100; no. 6-1; p. 062313
Main Authors	Erland, Sveinung, Kaupužs, Jevgenijs, Frette, Vidar, Pugatch, Rami, Bachmat, Eitan
Format	Journal Article
Language	English
Published	United States 01.12.2019
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Abstract	We study airplane boarding in the limit of a large number of passengers using geometric optics in a Lorentzian metric. The airplane boarding problem is naturally embedded in a (1+1)-dimensional space-time with a flat Lorentzian metric. The duration of the boarding process can be calculated based on a representation of the one-dimensional queue of passengers attempting to reach their seats in a two-dimensional space-time diagram. The ability of a passenger to delay other passengers depends on their queue positions and row designations. This is equivalent to the causal relationship between two events in space-time, whereas two passengers are timelike separated if one is blocking the other and spacelike if both can be seated simultaneously. Geodesics in this geometry can be utilized to compute the asymptotic boarding time, since space-time geometry is the many-particle (passengers) limit of airplane boarding. Our approach naturally leads to the introduction of an effective refractive index that enables an analytical calculation of the average boarding time for groups of passengers with different aisle-clearing time distribution. In the past, airline companies attempted to shorten the boarding times by trying boarding policies that allow either slow or fast passengers to board first. Our analytical calculations, backed by discrete-event simulations, support the counterintuitive result that the total boarding time is shorter with the slow passengers boarding before the fast passengers. This is a universal result, valid for any combination of the parameters that characterize the problem: the percentage of slow passengers, the ratio between aisle-clearing times of the fast and the slow group, and the density of passengers along the aisle. We find an improvement of up to 28% compared with the fast-first boarding policy. Our approach opens up the possibility to unify numerous simulation-based case studies under one framework.
AbstractList	We study airplane boarding in the limit of a large number of passengers using geometric optics in a Lorentzian metric. The airplane boarding problem is naturally embedded in a (1+1)-dimensional space-time with a flat Lorentzian metric. The duration of the boarding process can be calculated based on a representation of the one-dimensional queue of passengers attempting to reach their seats in a two-dimensional space-time diagram. The ability of a passenger to delay other passengers depends on their queue positions and row designations. This is equivalent to the causal relationship between two events in space-time, whereas two passengers are timelike separated if one is blocking the other and spacelike if both can be seated simultaneously. Geodesics in this geometry can be utilized to compute the asymptotic boarding time, since space-time geometry is the many-particle (passengers) limit of airplane boarding. Our approach naturally leads to the introduction of an effective refractive index that enables an analytical calculation of the average boarding time for groups of passengers with different aisle-clearing time distribution. In the past, airline companies attempted to shorten the boarding times by trying boarding policies that allow either slow or fast passengers to board first. Our analytical calculations, backed by discrete-event simulations, support the counterintuitive result that the total boarding time is shorter with the slow passengers boarding before the fast passengers. This is a universal result, valid for any combination of the parameters that characterize the problem: the percentage of slow passengers, the ratio between aisle-clearing times of the fast and the slow group, and the density of passengers along the aisle. We find an improvement of up to 28% compared with the fast-first boarding policy. Our approach opens up the possibility to unify numerous simulation-based case studies under one framework.
Author	Bachmat, Eitan Pugatch, Rami Erland, Sveinung Kaupužs, Jevgenijs Frette, Vidar
Author_xml	– sequence: 1 givenname: Sveinung surname: Erland fullname: Erland, Sveinung organization: Department of Maritime Studies, Western Norway University of Applied Sciences, 5528 Haugesund, Norway – sequence: 2 givenname: Jevgenijs surname: Kaupužs fullname: Kaupužs, Jevgenijs organization: Faculty of Materials Science and Applied Chemistry, Institute of Technical Physics, Riga Technical University, 1048 Riga, Latvia and Institute of Mathematical Sciences and Information Technologies, University of Liepaja, 3401 Liepaja, Latvia – sequence: 3 givenname: Vidar surname: Frette fullname: Frette, Vidar organization: Department of Fire Safety and HSE Engineering, Western Norway University of Applied Sciences, 5528 Haugesund, Norway – sequence: 4 givenname: Rami surname: Pugatch fullname: Pugatch, Rami organization: Department of Industrial Engineering and Management, Ben-Gurion University, Beer-Sheva 84105, Israel – sequence: 5 givenname: Eitan surname: Bachmat fullname: Bachmat, Eitan organization: Department of Computer Science, Ben-Gurion University, Beer-Sheva 84105, Israel
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