TY - JOUR
T1 - A queueing-inventory system with a repeated-orbit policy during the service
AU - Hanukov, Gabi
N1 - Publisher Copyright:
© 2023, The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.
PY - 2023
Y1 - 2023
N2 - We consider a service system in which customers who arrive at a service station and place an order, are not involved in the processing of their order, which can therefore be executed in their absence. Consequently, customers may leave the service station for some period of time during the processing of their order (i.e., go to orbit), and then return. While the customers are in orbit, they can utilize their time efficiently. If the service is completed before the customer's return from orbit, the ready service (RS) is stored in a designated storage facility until the customer returns and retrieves the RS from the inventory. If, however, the service is not yet completed when the customer returns, the customer can leave to orbit again. Accordingly, the policy is called "repeated orbit" (during the service). We formulate and analyze the queueing-inventory-repeated-orbit (QIRO) system using the matrix geometric method. The optimal orbiting time is calculated by maximizing the customer's expected utility. In addition, the optimal RS storage capacity and the optimal investment in preservation technologies (to store the RSs) are derived, both of which serve to increase demand and thus maximize the system's expected profit.
AB - We consider a service system in which customers who arrive at a service station and place an order, are not involved in the processing of their order, which can therefore be executed in their absence. Consequently, customers may leave the service station for some period of time during the processing of their order (i.e., go to orbit), and then return. While the customers are in orbit, they can utilize their time efficiently. If the service is completed before the customer's return from orbit, the ready service (RS) is stored in a designated storage facility until the customer returns and retrieves the RS from the inventory. If, however, the service is not yet completed when the customer returns, the customer can leave to orbit again. Accordingly, the policy is called "repeated orbit" (during the service). We formulate and analyze the queueing-inventory-repeated-orbit (QIRO) system using the matrix geometric method. The optimal orbiting time is calculated by maximizing the customer's expected utility. In addition, the optimal RS storage capacity and the optimal investment in preservation technologies (to store the RSs) are derived, both of which serve to increase demand and thus maximize the system's expected profit.
KW - Inventory-dependent demand
KW - Perishable inventory
KW - Queueing-inventory
KW - Repeated-orbit while in service
UR - http://www.scopus.com/inward/record.url?scp=85174541133&partnerID=8YFLogxK
U2 - 10.1007/s10479-023-05648-0
DO - 10.1007/s10479-023-05648-0
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AN - SCOPUS:85174541133
SN - 0254-5330
JO - Annals of Operations Research
JF - Annals of Operations Research
ER -