A note on the warehouse location problem with data contamination

Gao, Xuehong; Cui, Can

doi:10.1051/ro/2021036

Gao, Xuehong ; Cui, Can

RAIRO. Operations Research, Tome 55 (2021) no. 2, pp. 1113-1135

Résumé

To determine the optimal warehouse location, it is usually assumed that the collected data are uncontaminated. However, this assumption can be easily violated due to the uncertain environment and human error in disaster response, which results in the biased estimation of the optimal warehouse location. In this study, we investigate this possibility by examining these estimation effects on the warehouse location determination. Considering different distances, we propose the corresponding estimation methods for remedying the difficulties associated with data contamination to determine the warehouse location. Although data can be contaminated in the event of a disaster, the findings of the study is much broader and applicable to any situation where the outliers exist. Through the simulations and illustrative examples, we show that solving the problem with center of gravity lead to biased solutions even if only one outlier exists in the data. Compared with the center of gravity, the proposed methods are quite efficient and outperform the existing methods when the data contamination is involved.

MR

DOI : 10.1051/ro/2021036

Classification : 90B25
Keywords: Facility location problem, robust, center of gravity, weighted median

@article{RO_2021__55_2_1113_0,
     author = {Gao, Xuehong and Cui, Can},
     title = {A note on the warehouse location problem with data contamination},
     journal = {RAIRO. Operations Research},
     pages = {1113--1135},
     year = {2021},
     publisher = {EDP-Sciences},
     volume = {55},
     number = {2},
     doi = {10.1051/ro/2021036},
     mrnumber = {4253780},
     language = {en},
     url = {https://www.numdam.org/articles/10.1051/ro/2021036/}
}

TY  - JOUR
AU  - Gao, Xuehong
AU  - Cui, Can
TI  - A note on the warehouse location problem with data contamination
JO  - RAIRO. Operations Research
PY  - 2021
SP  - 1113
EP  - 1135
VL  - 55
IS  - 2
PB  - EDP-Sciences
UR  - https://www.numdam.org/articles/10.1051/ro/2021036/
DO  - 10.1051/ro/2021036
LA  - en
ID  - RO_2021__55_2_1113_0
ER  -

%0 Journal Article
%A Gao, Xuehong
%A Cui, Can
%T A note on the warehouse location problem with data contamination
%J RAIRO. Operations Research
%D 2021
%P 1113-1135
%V 55
%N 2
%I EDP-Sciences
%U https://www.numdam.org/articles/10.1051/ro/2021036/
%R 10.1051/ro/2021036
%G en
%F RO_2021__55_2_1113_0

Gao, Xuehong; Cui, Can. A note on the warehouse location problem with data contamination. RAIRO. Operations Research, Tome 55 (2021) no. 2, pp. 1113-1135. doi: 10.1051/ro/2021036

Bibliographie
Cité par

[1] M. Acar and O. Kaya, A healthcare network design model with mobile hospitals for disaster preparedness: a case study for Istanbul earthquake. Transp. Res. Part E: Logistics Transp. Rev. 130 (2019) 273–292. | DOI

[2] O. I. Alsalloum and G. K. Rand, Extensions to emergency vehicle location models. Comput. Oper. Res. 33 (2006) 2725–2743. | Zbl | DOI

[3] Y. An, B. Zeng, Y. Zhang and L. Zhao, Reliable $p$ -median facility location problem: two-stage robust models and algorithms. Transp. Res. Part B: Methodol. 64 (2014) 54–72. | DOI

[4] A. B. Arabani and R. Z. Farahani, Facility location dynamics: an overview of classifications and applications. Comput. Ind. Eng. 62 (2012) 408–420. | DOI

[5] M. G. Ashtiani, A. Makui and R. Ramezanian, A robust model for a leader–follower competitive facility location problem in a discrete space. Appl. Math. Model. 37 (2013) 62–71. | MR | DOI

[6] P. Augerat, J. M. Belenguer, E. Benavent, A. Corberán, D. Naddef and G. Rinaldi, Computational Results with a Branch and Cut Code for the Capacitated Vehicle Routing Problem (IMAG) (1995).

[7] J. Badal, M. Vázquez-Prada and Á. González, Preliminary quantitative assessment of earthquake casualties and damages. Nat. Hazards 34 (2005) 353–374. | DOI

[8] X. Bai, Two-stage multiobjective optimization for emergency supplies allocation problem under integrated uncertainty. Math. Prob. Eng. 2016 (2016) 2823835. | MR

[9] M. Baou and F. Barahona, A polyhedral study of a two level facility location model. RAIRO:OR 48 (2014) 153–165. | MR | Zbl | Numdam | DOI

[10] O. Baron, J. Milner and H. Naseraldin, Facility location: a robust optimization approach. Prod. Oper. Manage. 20 (2011) 772–785. | DOI

[11] M. Bastian and M. Volkmer, A perfect forward procedure for a single facility dynamic location/relocation problem. Oper. Res. Lett. 12 (1992) 11–16. | MR | Zbl | DOI

[12] A. Beck, Introduction to Nonlinear Optimization: Theory, Algorithms, and Applications with MATLAB. SIAM (2014). | MR | Zbl | DOI

[13] S. Boyd and L. Vandenberghe, Convex Optimization. Cambridge University Press (2004). | MR | Zbl | DOI

[14] C. G. Broyden, Quasi-Newton methods. In: Numerical Methods for Unconstrained Optimization. Academic Press, New York (1972).

[15] R. H. Byrd, P. Lu, J. Nocedal and C. Zhu, A limited memory algorithm for bound constrained optimization. SIAM J. Sci. Comput. 16 (1995) 1190–208. | MR | Zbl | DOI

[16] C. Cao, Y. Liu, O. Tang and X. Gao, A fuzzy bi-level optimization model for multi-period post-disaster relief distribution in sustainable humanitarian supply chains. Int. J. Prod. Econ. (2021) 108081. | DOI

[17] E. Cetin and L. S. Sarul, A blood bank location model: a multiobjective approach. Eur. J. Pure Appl. Math. 2 (2009) 112–124. | MR | Zbl

[18] S. Chanta, M. E. Mayorga and L. A. Mclay, Improving emergency service in rural areas: a bi-objective covering location model for EMS systems. Ann. Oper. Res. 221 (2014) 133–159. | MR | Zbl | DOI

[19] C.-H. Chen and C.-J. Ting, Combining Lagrangian heuristic and ant colony system to solve the single source capacitated facility location problem. Transp. Res. Part E: Logistics Transp. Rev. 44 (2008) 1099–1122. | DOI

[20] Y. Chen, Q. Zhao, L. Wang and M. Dessouky, The regional cooperation-based warehouse location problem for relief supplies. Comput. Ind. Eng. 102, 259–267. | DOI

[21] W.-Y. Chiu and B.-S. Chen, Mobile location estimation in urban areas using mixed Manhattan/Euclidean norm and convex optimization. IEEE Trans. Wireless Commun. 8 (2009) 414–423. | DOI

[22] R. Church and C. R. Velle, The maximal covering location problem. Papers Reg. Sci. 32 (1974) 101–118. | DOI

[23] I. A. Contreras and J. A. Daz, Scatter search for the single source capacitated facility location problem. Ann. Oper. Res. 157 (2008) 73–89. | MR | Zbl | DOI

[24] M. Csorgo, Quantile Processes with Statistical Applications. SIAM (1983). | MR | Zbl | DOI

[25] V. De Rosa, E. Hartmann, M. Gebhard and J. Wollenweber, Robust capacitated facility location model for acquisitions under uncertainty. Comput. Ind. Eng. 72 (2014) 206–216. | DOI

[26] F. Y. Edgeworth, Xxii, On a new method of reducing observations relating to several quantities. London Edinburgh Dublin Phil. Mag. J. Sci. 25 (1888) 184–191. | JFM | DOI

[27] S. Esnaf and T. Küçükdeniz, A fuzzy clustering-based hybrid method for a multi-facility location problem. J. Intell. Manuf. 20 (2009) 259–265. | DOI

[28] R. Z. Farahani, Z. Drezner and N. Asgari, Single facility location and relocation problem with time dependent weights and discrete planning horizon. Anna. Oper. Res. 167 (2009) 353–368. | MR | Zbl | DOI

[29] R. Fletcher, A new approach to variable metric algorithms. Comput. J. 13 (1970) 317–322. | Zbl | DOI

[30] R. L. Francis, J. A. White and L. F. Mcginnis, Facility Layout and Location: An Analytical Approach. Prentice-Hall Englewood Cliffs, NJ (1974).

[31] X. Gao, A bi-level stochastic optimization model for multi-commodity rebalancing under uncertainty in disaster response. Ann. Oper. Res. (2019) 1–34. | MR

[32] X. Gao, A location-driven approach for warehouse location problem. To appear in: J. Oper. Res. Soc. (2020). DOI: 10.1080/01605682.2020.1811790.

[33] X. Gao and C. Cao, Multi-commodity rebalancing and transportation planning considering traffic congestion and uncertainties in disaster response. Comput. Ind. Eng. 149 (2020) 106782. | DOI

[34] X. Gao and X. Jin, A robust multi-commodity rebalancing process in humanitarian logistics. In: Vol. 591 of Advances in Production Management System, APMS 2020. Springer, Cham (2020).

[35] X. Gao and G. M. Lee, A stochastic programming model for multi-commodity redistribution planning in disaster response. In: IFIP International Conference on Advances in Production Management Systems. Springer (2018) 67–78.

[36] X. Gao, Y. Zhou, M. I. H. Amir, F. A. Rosyidah and G. M. Lee, A hybrid genetic algorithm for multi-emergency medical service center location-allocation problem in disaster response. Int. J. Ind. Eng.: Theory App. Pract. 24 (2017) 663–679.

[37] X. Gao, M. K. Nayeem and I. M. Hezam, A robust two-stage transit-based evacuation model for large-scale disaster response. Measurement 145 (2019) 713–723. | DOI

[38] X. Gao, X. Jin, P. Zheng and C. Cui, Multi-modal transportation planning for multi-commodity rebalancing under uncertainty in humanitarian logistics. Adv. Eng. Inf. 47 (2021) 101223. | DOI

[39] F. Gayraud, N. Grangeon, L. Deroussi and S. Norre, Notation and classification for logistic network design models. RAIRO:OR 49 (2015) 195–214. | MR | Numdam | DOI

[40] D. Goldfarb, A family of variable-metric methods derived by variational means. Math. Comput. 24 (1970) 23–26. | MR | Zbl | DOI

[41] G. Guastaroba and M. G. Speranza, A heuristic for BILP problems: the single source capacitated facility location problem. Eur. J. Oper. Res. 238 (2014) 438–450. | MR | DOI

[42] N. Gülpnar, D. Pachamanova and E. Çanakoğlu, Robust strategies for facility location under uncertainty. Eur. J. Oper. Res. 225 (2013) 21–35. | MR | Zbl | DOI

[43] F. R. Hampel, E. M. Ronchetti, P. J. Rousseeuw and W. A. Stahel, Robust Statistics: The Approach Based on Influence Functions. John Wiley & Sons (2011). | MR | Zbl

[44] T. P. Hettmansperger and J. W. Mckean, Robust Nonparametric Statistical Methods. CRC Press (2010). | MR | Zbl | DOI

[45] S. C. Ho, An iterated tabu search heuristic for the single source capacitated facility location problem. Appl. Soft Comput. 27 (2015) 169–178. | DOI

[46] K. Hogan and C. Revelle, Concepts and applications of backup coverage. Manage. Sci. 32 (1986) 1434–1444. | DOI

[47] R. Ihaka and R. Gentleman, R: a language for data analysis and graphics. J. Comput. Graphical Stat. 5 (1996) 299–314. | DOI

[48] C. A. Irawan, M. Luis, S. Salhi and A. Imran, The incorporation of fixed cost and multilevel capacities into the discrete and continuous single source capacitated facility location problem. Ann. Oper. Res. 275 (2019) 367–392. | MR | DOI

[49] M. Körkel, Discrete facility location with nonlinear facility costs. RAIRO:OR 25 (1991) 31–43. | MR | Zbl | Numdam | DOI

[50] E. L. Lehmann, Elements of Large-Sample Theory. Springer Science & Business Media (2004). | MR | Zbl

[51] S. Manzour-Al-Ajdad, S. A. Torabi and S. Salhi, A hierarchical algorithm for the planar single-facility location routing problem. Comput. Oper. Res. 39 (2012) 461–470. | MR | Zbl | DOI

[52] E. Moradi and M. Bidkhori, Single facility location problem. In: Facility location. Springer (2009). | DOI

[53] J. Morris, R. Love and G. Wesolowsky, Facilities Location: Models and Methods. North-Holland, New York (1988). | MR | Zbl

[54] A. Nadizadeh, R. Sahraeian, A. S. Zadeh and S. M. Homayouni, Using greedy clustering method to solve capacitated location-routing problem. Afr. J. Bus. Manage. 5 (2011) 8470–8477. | DOI

[55] Y. Ohsawa, A geometrical solution for quadratic bicriteria location models. Eur. J. Oper. Res. 114 (1999) 380–388. | Zbl | DOI

[56] N. Onnela, Determining the optimal distribution center location. Master thesis (2015).

[57] L. Ouyang, Y. Ma, J. Wang and Y. Tu, A new loss function for multi-response optimization with model parameter uncertainty and implementation errors. Eur. J. Oper. Res. 258 (2017) 552–563. | MR | Zbl | DOI

[58] L. Ouyang, J. Chen, Y. Z. Ma, C. Park and J. Jin, Bayesian closed-loop robust process design considering model uncertainty and data quality. IIE Trans. (2020) 288–300.

[59] A. B. Owen, Empirical Likelihood. Chapman and Hall/CRC (2001). | Zbl

[60] C. Park, Determination of the joint confidence region of the optimal operating conditions in robust design by the bootstrap technique. Int. J. Prod. Res. 51 (2013) 4695–4703. | DOI

[61] C. Park and M. Leeds, A highly efficient robust design under data contamination. Comput. Ind. Eng. 93 (2016) 131–142. | DOI

[62] M. Parnas and D. Ron, Testing metric properties. Inf. Comput. 187 (2003) 155–195. | MR | Zbl | DOI

[63] P. J. Rousseeuw and C. Croux, Alternatives to the median absolute deviation. J. Am. Stat. Assoc. 88 (1993) 1273–1283. | MR | Zbl | DOI

[64] R. Serfling, Asymptotic relative efficiency in estimation. Int. Encycl. Stat. Sci. 23 (2011) 68–72. | DOI

[65] D. F. Shanno, Conditioning of quasi-Newton methods for function minimization. Math. Comput. 24 (1970) 647–656. | MR | Zbl | DOI

[66] R.C. Team, R: A language and environment for statistical computing (2019) 201.

[67] J. W. Tukey, A survey of sampling from contaminated distributions. Contrib. Prob. Stat. (1960) 448–485. | MR | Zbl

[68] I. Vazler, K. Sabo and R. Scitovski, Weighted median of the data in solving least absolute deviations problems. Commun. Stat.-Theory Methods 41 (2012) 1455–1465. | MR | Zbl | DOI

[69] L. Yajie, L. Hongtao, W. Zhiyong and Z. Dezhi, A robust model predictive control approach for post-disaster relief distribution. Comput. Ind. Eng. 135 (2019) 1253–1270. | DOI

[70] M. Zaferanieh, H. T. Kakhki, J. Brimberg and G. O. Wesolowsky, A BSSS algorithm for the single facility location problem in two regions with different norms. Eur. J. Oper. Res. 190 (2008) 79–89. | MR | Zbl | DOI

Cité par Sources :