Production and energy mode control of a production-inventory system

Dynamic programming; Flexible manufacturing systems control; Markov processes; OR in energy; Control policy; Energy modes; Exponentials; Flexible manufacturing system control; Joint production; Manufacturing systems control; Production inventory system; Production modes; Warm-up time; Computer Science (all); Modeling and Simulation; Management Science and Operations Research; Information Systems and Management

Abstract :

[en] Energy efficiency in manufacturing can be improved by controlling energy modes and production dynamically. We examine a production-inventory system that can operate in Working, Idle, and Off energy modes with mode-dependent energy costs. There can be a warm-up delay to switch between one mode to another. With random inter-arrival, production and warm-up times, we formulate the problem of determining in which mode the production resource should operate at a given time depending on the state of the system as a stochastic control problem under the long-run average profit criterion considering the sales revenue together with energy, inventory holding and backlog costs. The optimal solution of the problem for the exponential inter-arrival, production and warm-up times is determined by solving the Markov Decision Process with a linear programming approach. The structure of the optimal policy for the exponential case uses two thresholds to switch between the Working and Idle or Working and Off modes. We use the two-threshold policy as an approximate policy to control a system with correlated inter-event times with general distributions. This system is modelled as a Quasi Birth and Death Process and analyzed by using a matrix-geometric method. Our numerical experiments show that the joint production and energy control policy performs better compared to the pure production and energy control policies depending on the system parameters. In summary, we propose a joint energy and production control policy that improves energy efficiency by controlling the energy modes depending on the state of the system.

Disciplines :

Production, distribution & supply chain management

Author, co-author :

Tan, Barış ; College of Administrative Sciences and Economics, College of Engineering, Koç University, İstanbul, Turkey

Karabağ, Oktay ; Erasmus School of Economics, Erasmus University Rotterdam, Rotterdam, Netherlands ; Department of Industrial Engineering, Yaşar University, Izmir, Turkey

Khayyati, Siamak ; Université de Liège - ULiège > HEC Liège Research > HEC Liège Research: Business Analytics & Supply Chain Mgmt ; Mannheim Business School, University of Mannheim, Mannheim, Germany

Language :

English

Title :

Production and energy mode control of a production-inventory system

Publication date :

August 2023

Journal title :

European Journal of Operational Research

ISSN :

0377-2217

eISSN :

1872-6860

Publisher :

Elsevier B.V.

Volume :

308

Issue :

Pages :

1176 - 1187

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://api.elsevier.com/content/article/PII:S0377221722009699?httpAccept=text/xml

Funders :

EU - European Union

Funding text :

This work was supported by TUBITAK (Grant number 221M393) and European Union's Horizon 2020 Research and Innovation Programme [IN4ACT project under grant agreement no. 810318].This work was supported by TUBITAK (Grant number 221M393) and European Union’s Horizon 2020 Research and Innovation Programme [IN4ACT project under grant agreement no. 810318 ].

Available on ORBi :

since 13 January 2026

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Bibliography

Anghinolfi, D., Paolucci, M., Ronco, R., A bi-objective heuristic approach for green identical parallel machine scheduling. European Journal of Operational Research 289:2 (2021), 416–434.
Bänsch, K., Busse, J., Meisel, F., Rieck, J., Scholz, S., Volling, T., Wichmann, M.G., Energy-aware decision support models in production environments: A systematic literature review. Computers and Industrial Engineering, 159, 2021, 107456.
Bertsekas, D.P., Dynamic programming and optimal control 4th edition, volume II. 2015.
Biel, K., Glock, C.H., Systematic literature review of decision support models for energy-efficient production planning. Computers and Industrial Engineering 101 (2016), 243–259.
Brundage, M.P., Chang, Q., Li, Y., Xiao, G., Arinez, J., Energy efficiency management of an integrated serial production line and HVAC system. IEEE Transactions on Automation Science and Engineering 11:3 (2013), 789–797.
Chang, Q., Xiao, G., Biller, S., Li, L., Energy saving opportunity analysis of automotive serial production systems. IEEE Transactions on Automation Science and Engineering 10:2 (2012), 334–342.
Cronrath, C., Lennartson, B., Lemessi, M., Energy reduction in paint shops through energy-sensitive on-off control. 2016 IEEE international conference on automation science and engineering (CASE), 2016, IEEE, 1282–1288.
Dai, M., Tang, D., Giret, A., Salido, M.A., Li, W.D., Energy-efficient scheduling for a flexible flow shop using an improved genetic-simulated annealing algorithm. Robotics and Computer-Integrated Manufacturing 29:5 (2013), 418–429.
Dallery, Y., Gershwin, S.B., Manufacturing flow line systems: A review of models and analytical results. Queueing Systems 12:1 (1992), 3–94.
Dizbin, N.M., Tan, B., Modelling and analysis of the impact of correlated inter-event data on production control using Markovian arrival processes. Flexible Services and Manufacturing Journal 31:4 (2019), 1042–1076.
Frigerio, N., Cornaggia, C.F., Matta, A., An adaptive policy for on-line energy-efficient control of machine tools under throughput constraint. Journal of Cleaner Production, 287, 2021, 125367.
Frigerio, N., Marzano, L., Matta, A., An online policy for energy-efficient state control of manufacturing equipment. IEEE Transactions on Automation Science and Engineering 18:2 (2020), 705–716.
Frigerio, N., Matta, A., Energy-efficient control strategies for machine tools with stochastic arrivals. IEEE Transactions on Automation Science and Engineering 12:1 (2014), 50–61.
Frigerio, N., Matta, A., Analysis on energy efficient switching of machine tool with stochastic arrivals and buffer information. IEEE Transactions on Automation Science and Engineering 13:1 (2015), 238–246.
Gahm, C., Denz, F., Dirr, M., Tuma, A., Energy-efficient scheduling in manufacturing companies: A review and research framework. European Journal of Operational Research 248:3 (2016), 744–757.
Gavish, B., Graves, S.C., A one-product production/inventory problem under continuous review policy. Operations Research 28:5 (1980), 1228–1236.
Heydar, M., Mardaneh, E., Loxton, R., Approximate dynamic programming for an energy-efficient parallel machine scheduling problem. European Journal of Operational Research 302:1 (2021), 363–380.
Hosseini, B., Tan, B., Modelling and analysis of a cooperative production network. International Journal of Production Research 57:21 (2019), 6665–6686.
Karabağ, O., Tan, B., Purchasing, production, and sales strategies for a production system with limited capacity, fluctuating sales and purchasing prices. IISE Transactions 51:9 (2019), 921–942.
Katchasuwanmanee, K., Bateman, R., Cheng, K., An integrated approach to energy efficiency in automotive manufacturing systems: Quantitative analysis and optimisation. Production and Manufacturing Research 5:1 (2017), 90–98.
Khayyati, S., Tan, B., Data-driven control of a production system by using marking-dependent threshold policy. International Journal of Production Economics, 226, 2020, 107607.
Li, J., Blumenfeld, D.E., Huang, N., Alden, J.M., Throughput analysis of production systems: Recent advances and future topics. International Journal of Production Research 47:14 (2009), 3823–3851.
Li, Y., Chang, Q., Ni, J., Brundage, M.P., Event-based supervisory control for energy efficient manufacturing systems. IEEE Transactions on Automation Science and Engineering 15:1 (2016), 92–103.
Loffredo, A., Frigerio, N., Lanzarone, E., Matta, A., Energy-efficient control policy for parallel and identical machines with availability constraint. IEEE Robotics and Automation Letters 6:3 (2021), 5713–5719.
Mashaei, M., Lennartson, B., Energy reduction in a pallet-constrained flow shop through on–off control of idle machines. IEEE Transactions on Automation Science and Engineering 10:1 (2012), 45–56.
Mashaei, M., Lennartson, B., Energy reduction in cyclic flow shop plants through on-off control of robots. 2014 IEEE international conference on automation science and engineering (CASE), 2014, IEEE, 492–497.
Mouzon, G., Yıldırım, M.B., A framework to minimise total energy consumption and total tardiness on a single machine. International Journal of Sustainable Engineering 1:2 (2008), 105–116.
Mouzon, G., Yıldırım, M.B., Twomey, J., Operational methods for minimization of energy consumption of manufacturing equipment. International Journal of Production Research 45:18-19 (2007), 4247–4271.
Neuts, M.F., A versatile Markovian point process. Journal of Applied Probability 16:4 (1979), 764–779.
Ost, A., Performance of communication systems: A model-based approach with matrix-geometric methods. 2013, Springer Science & Business Media.
Papadopoulos, C.T., Li, J., O'Kelly, M.E., A classification and review of timed Markov models of manufacturing systems. Computers & Industrial Engineering 128 (2019), 219–244.
Puterman, M.L., Markov decision processes: discrete stochastic dynamic programming. 2014, John Wiley & Sons.
Renna, P., Energy saving by switch-off policy in a pull-controlled production line. Sustainable Production and Consumption 16 (2018), 25–32.
Sobel, M.J., The optimality of full service policies. Operations Research 30:4 (1982), 636–649.
Squeo, M., Frigerio, N., Matta, A., Multiple sleeping states for energy saving in CNC machining centers. Procedia CIRP 80 (2019), 144–149.
Su, W., Xie, X., Li, J., Zheng, L., Feng, S.C., Reducing energy consumption in serial production lines with Bernoulli reliability machines. International Journal of Production Research 55:24 (2017), 7356–7379.
Sun, Z., Li, L., Opportunity estimation for real-time energy control of sustainable manufacturing systems. IEEE Transactions on Automation Science and Engineering 10:1 (2012), 38–44.
Suzanne, E., Absi, N., Borodin, V., Towards circular economy in production planning: Challenges and opportunities. European Journal of Operational Research 287:1 (2020), 168–190.
Uit het Broek, M.A., Van der Heide, G., Van Foreest, N.D., Energy-saving policies for temperature-controlled production systems with state-dependent setup times and costs. European Journal of Operational Research 287:3 (2020), 916–928.
Wang, J., Feng, Y., Fei, Z., Li, S., Chang, Q., Markov chain based idle status control of stochastic machines for energy saving operation. 2017 13th IEEE conference on automation science and engineering (CASE), 2017, IEEE, 1019–1023.
Yan, C.-B., Zheng, Z., Problem formulation and solution methodology for energy consumption optimization in Bernoulli serial lines. IEEE Transactions on Automation Science and Engineering 18:2 (2020), 776–790.