Енергетика і автоматика

In this paper an organic food delivery scheduling problem with time windows is presented. Described issue seems to be very important in the field of logistics in agriculture especially when organic food delivery to small shops, restaurants or customers’ houses are considered. In this kind of services the frequency and number of deliveries are significantly high and every producer and client should be visited in the defined time window, therefore there is a strong need for coordination of deliveries’ routes – every route begins with collecting goods from farms and subsequently, products are being delivered to customers. In this paper the organic food delivery scheduling problem is presented as a theoretical problem for which a mix integer programming model was developed. The model was employed for solving a small possible situation – computational experiment is described and results are reported. Moreover, directions for further research are suggested.

Akkerman R., Farahani P., Grunow M, Quality, safety and sustainability in food distribution: a review of quantitative operations management approaches and challenges, OR Spectrum 32, 2010, pp. 863 – 904.

Ambroziak, T., Jachimowski R., Wybrane aspekty zagadnienia okien czasowych w problemie trasowania pojazdów [Selected aspects of utilisation of time windows for the vehicle routing problem], Automatyka, 15(2), 2011, pp. 51–59.

Campbell M.A., Hardin J.R., Vehicle minimization for periodic deliveries, European Journal of Operational Research 165, 2005, pp. 668 – 684.

Castelli L., Pesenti R., Ukovich W., Scheduling multimodal transportation systems, European Journal of Operational Research 155, 2004, pp. 603 – 615.

Ceder A., Golany B., Tal O., Creating bus timetables with maximal synchronization, Transportation Research Part A 35, 2001, pp. 913 – 928.

Ching-Ter C., Hsiao-Ching C., A coordination system for seasonal demand problems in the supply chain, Applied Mathematical Modelling, 37, 2013, pp. 3674 – 3686.

Eranki A., A model to create bus timetables to attain maximum synchronization considering waiting times at transfer stops, master’s thesis, Department of Industrial and Management System Engineering, University of South Florida, 2004. Available at: http://scholarcommons.usf.edu/cgi/viewcontent. cgi?article=2024&context=etd (Access: September 29, 2012).

Gdowska K.Z., Książek R., Utilisation of models of timetable generation in urban public communication applied for tramway network of Krakow, Poland [in:] Zarządzanie przedsiębiorstwem – teoria i praktyka. XIV międzynarodowa konferencja naukowa: 22–23 listopada 2012, Kraków: materiały konferencyjne [Management – theory and practice. XIV international scientific conference: 22–23 November, 2012, Krakow: conference proceedings], Krakow 2012, pp. 1 – 11.

Gdowska K.Z., Książek R., Problem układania rozkładów jazdy dla sieci tramwajowej miejskiej komunikacji publicznej [Urban public transport timetabling problem for a tramway network] [in:] TLM 2012. Total Logistic Management: XVI konferencja logistyki stosowanej: Zakopane, 6–8 grudnia 2012. Materiały konferencyjne, [Total Logistic Management: XVI conference of applied logistics: Zakopane, 6–8 December, 2012. Conference Proceedings] Komitet Transportu Polskiej Akademii Nauk, Warsaw 2012, pp. 1 – 11.

Ibarra-Rojas O.J., Rios-Solis Y.A., Synchronization of bus timetabling, Transportation Research Part B 46, 2012, pp. 599 – 614.

Kazan O., Dawande M., Sriskandarajah C., Stecke K.E., Balancing Perfectly Periodic Service Schedules: An Application from Recycling and Waste Management, Naval Research Logistics (NRL), 59 (2), 2012, pp. 160 – 171.

Laporte G., The travelling salesman problem: an overview of exact and approximate algorithms, European Journal of Operational Research, 59, 1992.

Leunga J.Y.-T., Chen Z.-L., Integrated production and distribution with fixed delivery departure dates, Operations Research Letters 41, 2013, pp. 290–293.

Nidhi M.B., Anil B., A cost optimisation strategy for a single warehouse multi-distributor vehicle routing system in stochastic scenario, International Journal of Logistics Systems and Management, 10 (1), 2011, pp. 110 – 121.

Toth P., Vigo D., The vehicle routing problem, SIAM Monographs on Discrete Mathematic and Applications, Bologna 1992.

Takei R., Tsai R., Shen H., Landa Y., A practical path-planning algorithm for a simple car: A Hamilton-Jacobi approach, [in:] Proceedings of the 2010 American Control Conference, ACC, 2010, pp. 6175 – 6180.

Ullrich C.A., Integrated machine scheduling and vehicle routing with time windows, European Journal of Operational Research 227, 2013, pp. 152– 165.

Bukchin J., Dar-El E. M., Rubinovitz J., Mixed model assembly line design in a make-to-order environment, Computers & Industrial Engineering 41, 2002, pp. 405 – 421.

Muda S., Hendry L., Developing a new world class model for small and medium sized make-to-order companies, International Journal of Production Economics 78, 2002, pp. 295 – 310.

Sahin F., Robinson Jr. E. P., Information sharing and coordination in make-to-order supply chains, Journal of Operations Management 23, 2005, pp. 579 – 598.

Sawik T., A cyclic versus flexible approach to materials ordering in make-to-order assembly, Mathematical and Computer Modelling 42, 2005, pp. 279 – 290.

Sawik T., Integer programming approach to reactive scheduling in make-to-order manufacturing, Mathematical and Computer Modelling 46, 2007, pp. 1373 – 1387.

Sawik T., A lexicographic approach to bi-objective scheduling of single-period orders in make-to-order manufacturing, European Journal of Operational Research 180, 2007, pp. 1060 – 1075.

Sawik T., Multi-objective due-date setting in a make-to-order environment, International Journal of Production Research 47(22), 2009, pp. 6205 – 6231.

Sawik T., Monolithic versus hierarchical approach to integrated scheduling in a supply chain, International Journal of Production Research 47 (21), 2009, pp. 5881 – 5910.

Sawik T., Coordinated supply chain scheduling, International Journal of Production Economics 120, 2009, pp. 437 – 451.

Soman C. A., van Donk D. P., Gaalman G., Combined make-to-order and make-to-stock in a food production system, International Journal of Production Economics 90, 2004, pp. 223 – 235.

Soman C. A., van Donk D. P., Gaalman G., Capacitated planning and scheduling for combined make-to-order and make-to-stock production in the food industry: An illustrative case study, International Journal of Production Economics 108, 2007, pp. 191 – 199.

Weng Z. K., Manufacturing lead times, system utilization rates and lead-time-related demand, European Journal of Operational Researches 89, 1996, pp. 259 – 268.