Operating Policies in Robotic Compact Storage and Retrieval Systems

References

• Buitenhek R, Van Houtum GJ, Zijm H (2000) AMVA-based solution procedures for open queueing networks with population constraints. Ann. Oper. Res. 93(1):15–40.Crossref, Google Scholar
• Cai X, Heragu SS, Liu Y (2014) Modeling and evaluating the AVS/RS with tier-to-tier vehicles using a semi-open queueing network. IIE Trans. 46(9):905–927.Crossref, Google Scholar
• Cimcorp (2016) Cimcorp AS/RS, automated storage and retrieval sys-tem (AS/RS). https://cimcorp.com/en/logistics-automation/products-and-solutions/automated-storage-and-retrieval-system -asrs.Google Scholar
• De Koster R, Le-Duc T, Yu Y (2008) Optimal storage rack design for a 3-dimensional compact AS/RS. Internat. J. Production Res. 46(6):1495–1514.Crossref, Google Scholar
• Ekren BY, Heragu SS, Krishnamurthy A, Malmborg CJ (2013) An approximate solution for semi-open queueing network model of an autonomous vehicle storage and retrieval system. IEEE Trans. Automation Sci. Engrg. 10(1):205–215.Crossref, Google Scholar
• Ekren BY, Heragu SS, Krishnamurthy A, Malmborg CJ (2014) Matrix-geometric solution for semi-open queuing network model of autonomous vehicle storage and retrieval system. Comput. Indust. Engrg. 68:78–86.Crossref, Google Scholar
• ElementLogic (2016a) Elektroskandia, 1000 m2 of floorspace freed. http://www.elementlogic.net/reference/elektroskandia/.Google Scholar
• ElementLogic (2016b) Bergans, 80% of handling on 10% of the space. http://www.elementlogic.net/reference/bergans/.Google Scholar
• ElementLogic (2016c) XXL sport & Vildmark, the explanation behind the low XXL-prices. http://www.elementlogic.net/reference/xxl-sport-villmark-norge/.Google Scholar
• Fukunari M, Malmborg C (2008) An efficient cycle time model for autonomous vehicle storage and retrieval systems. Internat. J. Production Res. 46(12):3167–3184.Crossref, Google Scholar
• Fukunari M, Malmborg CJ (2009) A network queuing approach for evaluation of performance measures in autonomous vehicle storage and retrieval systems. Eur. J. Oper. Res. 193(1):152–167.Crossref, Google Scholar
• Gharehgozli AH, Laporte G, Yu Y, De Koster R (2015) Scheduling twin yard cranes in a container block. Transportation Sci. 49(3):686–705.Link, Google Scholar
• Gharehgozli AH, Yu Y, De Koster R, Udding JT (2014a) A decision-tree stacking heuristic minimising the expected number of reshuffles at a container terminal. Internat. J. Production Res. 52(9):2592–2611.Crossref, Google Scholar
• Gharehgozli AH, Yu Y, De Koster R, Udding JT (2014b) An exact method for scheduling a yard crane. Eur. J. Oper. Res. 235(2):431–447.Crossref, Google Scholar
• Gharehgozli AH, Yu Y, Zhang X, De Koster R (2017) Polynomial time algorithms to minimize total travel time in a two-depot automated storage/retrieval system. Transportation Sci. 51(1):19–31.Link, Google Scholar
• Graves SC, Hausman WH, Schwarz LB (1977) Storage-retrieval interleaving in automatic warehousing systems. Management Sci. 23(9):935–945.Link, Google Scholar
• Gue KR (2006) Very high density storage systems. IIE Trans. 38(1):79–90.Crossref, Google Scholar
• Gue KR, Kim BS (2007) Puzzle-based storage systems. Naval Res. Logist. 54(5):556–567.Crossref, Google Scholar
• Hao J, Yu Y, Zhang LL (2015) Optimal design of a 3D compact storage system with the I/O port at the lower mid-point of the storage rack. Internat. J. Production Res. 53(17):5153–5173.Crossref, Google Scholar
• Heragu SS, Cai X, Krishnamurthy A, Malmborg CJ (2011) Analytical models for analysis of automated warehouse material handling systems. Internat. J. Production Res. 49(22):6833–6861.Crossref, Google Scholar
• Jia J, Heragu SS (2009) Solving semi-open queuing networks. Oper. Res. 57(2):391–401.Link, Google Scholar
• Kleinrock L (1976) Queueing systems, Vol. 1 (Wiley, Toronto).Google Scholar
• Kota VR, Taylor D, Gue KR (2015) Retrieval time performance in puzzle-based storage systems. J. Manufacturing Tech. Management 26(4):582–602.Crossref, Google Scholar
• Lalesse E (2016) Autostore order pick system. https://www.youtube.com/watch?v=7DeT-Hj2DXk.Google Scholar
• Lerher T (2016) Travel time model for double-deep shuttle-based storage and retrieval systems. Internat. J. Production Res. 29(4):2519–2540.Crossref, Google Scholar
• Lerher T, Ekren BY, Dukic G, Rosi B (2015) Travel time model for shuttle-based storage and retrieval systems. Internat. J. Adv. Manufacturing Tech. 78(9–12):1705–1725.Crossref, Google Scholar
• Malmborg CJ (2002) Conceptualizing tools for autonomous vehicle storage and retrieval systems. Internat. J. Production Res. 40(8):1807–1822.Crossref, Google Scholar
• Marchet G, Melacini M, Perotti S, Tappia E (2012) Analytical model to estimate performances of autonomous vehicle storage and retrieval systems for product totes. Internat. J. Production Res. 50(24):7134–7148.Crossref, Google Scholar
• Rabobank (2016) Rabobank TV commercial: Investment active ants. https://www.youtube.com/watch?v=CxEJuXMdnaA.Google Scholar
• Roland Berger (2016) Think act of robots and men-in logistics. https://www.rolandberger.com.Google Scholar
• Roy D, Krishnamurthy A, Heragu S, Malmborg C (2015) Queuing models to analyze dwell-point and cross-aisle location in autonomous vehicle-based warehouse systems. Eur. J. Oper. Res. 242(1):72–87.Crossref, Google Scholar
• Roy D, Krishnamurthy A, Heragu SS, Malmborg CJ (2012) Performance analysis and design trade-offs in warehouses with autonomous vehicle technology. IIE Trans. 44(12):1045–1060.Crossref, Google Scholar
• Swisslog (2016a) Antalis, Switzerland: Smart intralogistics for small parts. https://www.swisslog.com/en-us/warehouse-logistics-distribution-center-automation/case-studies-and-resources/case-studies/2016/07/antalis.Google Scholar
• Swisslog (2016b) ASDA, Great Britain: Boost of distribution center efficiency. https://www.swisslog.com/en-us/warehouse-logistics-distribution-center-automation/case-studies-and-resources/case-studies/2016/07/asda.Google Scholar
• Swisslog (2016c) AutoStore: Space saving storage and order picking system for small parts. https://www.swisslog.com/en-us/warehouse-logistics-distribution-center-automation/products-systems-solutions/asrs-automated-storage-,-a-,-retrieval-systems/boxes-cartons-small-parts-items/autostore-integrator.Google Scholar
• Tappia E, Roy D, De Koster R, Melacini M (2017) Modeling, analysis, and design insights for shuttle-based compact storage systems. Transportation Sci. 51(1):269–295.Link, Google Scholar
• Vis IF, Carlo HJ (2010) Sequencing two cooperating automated stacking cranes in a container terminal. Transportation Sci. 44(2):169–182.Link, Google Scholar
• Yang P, Miao L, Xue Z, Qin L (2015) Optimal storage rack design for a multi-deep compact AS/RS considering the acceleration/deceleration of the storage and retrieval machine. Internat. J. Production Res. 53(3):929–943.Crossref, Google Scholar
• Yu Y, De Koster R (2009a) Designing an optimal turnover-based storage rack for a 3D compact automated storage and retrieval system. Internat. J. Production Res. 47(6):1551–1571.Crossref, Google Scholar
• Yu Y, De Koster R (2009b) Optimal zone boundaries for two-class-based compact three-dimensional automated storage and retrieval systems. IIE Trans. 41(3):194–208.Crossref, Google Scholar
• Yu Y, De Koster R, Guo X (2015) Class-based storage with a finite number of items: Using more classes is not always better. Production Oper. Management 24(8):1235–1247.Crossref, Google Scholar
• Zaerpour N, Yu Y, De Koster R (2015) Storing fresh produce for fast retrieval in an automated compact cross-dock system. Production Oper. Management 24(8):1266–1284.Crossref, Google Scholar
• Zaerpour N, Yu Y, De Koster R (2017) Small is beautiful: A framework for evaluating and optimizing live-cube compact storage systems. Transportation Sci. 51(1):34–51.Link, Google Scholar
• Zou B, Gong Y, Xu X, Yuan Z (2017) Assignment rules in robotic mobile fulfillment systems for online retailers. Internat. J. Production Res. 55(20):6175–6192.Crossref, Google Scholar
• Zou B, Xu X, Gong Y, De Koster R (2016) Modeling parallel movement of lifts and vehicles in tier-captive vehicle-based warehousing systems. Eur. J. Oper. Res. 254(1):51–67.Crossref, Google Scholar