Artificial Intelligence Applications in Project Scheduling: A Systematic Review, Bibliometric Analysis, and Prospects for Future Research

[1] S. Christodoulou, “Scheduling resource-constrained projects with ant colony optimization artificial agents,” Journal of computing in civil engineering, vol. 24, pp. 45-55, 2010.Search in Google Scholar

[2] J. Blazewicz, J.K. Lenstra, and A.H.G.R. Kan, “Scheduling subject to resource constraints: classification and complexity,” Discrete Applied Mathematics, vol. 5, pp. 11-24, 1983.Search in Google Scholar

[3] M. Ranjbar, “A path-relinking metaheuristic for the resource levelling problem,” Journal of the Operational Research Society, vol. 64, pp. 1071-1078, 2013.Search in Google Scholar

[4] L. Balyen and T. Peto, “Promising Artificial Intelligence-Machine Learning-Deep Learning Algorithms in Ophthalmology,” The Asia-Pacific Journal of Ophthalmology, vol. 8, 2019.Search in Google Scholar

[5] P. Ongsulee, “Artificial intelligence, machine learning and deep learning,” in 2017 15th International Conference on ICT and Knowledge Engineering (ICT&KE), 2017, pp. 1-6.Search in Google Scholar

[6] Z. Ghahramani, “Probabilistic machine learning and artificial intelligence,” Nature, vol. 521, pp. 452-459, 2015.Search in Google Scholar

[7] D. Patel, Y. Shah, N. Thakkar, K. Shah, and M. Shah, “Implementation of artificial intelligence techniques for cancer detection,” Augmented Human Research, vol. 5, pp. 1-10, 2020.Search in Google Scholar

[8] D. Luckey, H. Fritz, D. Legatiuk, K. Dragos, and K. Smarsly, “Artificial intelligence techniques for smart city applications,” in International Conference on Computing in Civil and Building Engineering, 2020, pp. 3-15.Search in Google Scholar

[9] Z. Ullah, F. Al-Turjman, L. Mostarda, and R. Gagliardi, “Applications of artificial intelligence and machine learning in smart cities,” Computer Communications, vol. 154, pp. 313-323, 2020.Search in Google Scholar

[10] S. Shakya, “Analysis of artificial intelligence based image classification techniques,” Journal of Innovative Image Processing (JIIP), vol. 2, pp. 44-54, 2020.Search in Google Scholar

[11] G. Gutierrez, “Artificial intelligence in the intensive care unit,” Critical Care, vol. 24, pp. 1-9, 2020.Search in Google Scholar

[12] T. Gościniak and K. Wodarski, “Effectiveness of Using the Method of Artificial Intelligence in Maintenance of Ict Systems,” Management Systems in Production Engineering, vol. 27, pp. 40-45, 2019.Search in Google Scholar

[13] A. Lozhkin, K. Maiorov, and P. Bozek, “Convolutional Neural Networks Training for Autonomous Robotics,” Management Systems in Production Engineering, vol. 29, pp. 75-79, 2021.Search in Google Scholar

[14] H. Aytug, S. Bhattacharyya, G.J. Koehler, and J.L. Snowdon, “A review of machine learning in scheduling,” IEEE Transactions on Engineering Management, vol. 41, pp. 165-171, 1994.Search in Google Scholar

[15] P.I. a. A.O.T. Adamu, “Machine Learning Priority Rule (MLPR) for solving resource-constrained project scheduling problems,” presented at the Lecture Notes in Engineering and Computer Science, 2018.Search in Google Scholar

[16] M. Awada, F.J. Srour, and M. Srour Issam, “Data-Driven Machine Learning Approach to Integrate Field Submittals in Project Scheduling,” Journal of Management in Engineering, vol. 37, p. 04020104, 2021/07/31 2021.Search in Google Scholar

[17] N. Kartam and T. Tongthong, “Potential of artificial neural networks for resource scheduling,” Artificial Intelligence for Engineering Design, Analysis and Manufacturing, vol. 11, pp. 171-185, 1997.Search in Google Scholar

[18] N. Simeunovic, I. Kamenko, V. Bugarski, M. Jovanovic, and B. Lalic, “Improving workforce scheduling using artificial neural networks model,” Advances in Production Engineering & Management, vol. 12, pp. 337-352, 2017.Search in Google Scholar

[19] M. Koopialipoor, H. Tootoonchi, D. Jahed Armaghani, E. Tonnizam Mohamad, and A. Hedayat, “Application of deep neural networks in predicting the penetration rate of tunnel boring machines,” Bulletin of Engineering Geology and the Environment, vol. 78, pp. 6347-6360, 2019.Search in Google Scholar

[20] D. Mishra, A. Gunasekaran, T. Papadopoulos, and S.J. Childe, “Big Data and supply chain management: a review and bibliometric analysis,” Annals of Operations Research, vol. 270, pp. 313-336, 2018.Search in Google Scholar

[21] B. Fahimnia, J. Sarkis, and H. Davarzani, “Green supply chain management: A review and bibliometric analysis,” International Journal of Production Economics, vol. 162, pp. 101-114, 2015.Search in Google Scholar

[22] A. Darko, A.P.C. Chan, M.A. Adabre, D.J. Edwards, M.R. Hosseini, and E.E. Ameyaw, “Artificial intelligence in the AEC industry: Scientometric analysis and visualization of research activities,” Automation in Construction, vol. 112, p. 103081, 2020.Search in Google Scholar

[23] M. Bilal, L.O. Oyedele, J. Qadir, K. Munir, S.O. Ajayi, O.O. Akinade, et al., “Big Data in the construction industry: A review of present status, opportunities, and future trends,” Advanced engineering informatics, vol. 30, pp. 500-521, 2016.Search in Google Scholar

[24] A.J.L. Rodrigues, “Structure and logic in knowledge-based representations of systems simulation models,” European Journal of Operational Research, vol. 37, pp. 120-126, 1988.Search in Google Scholar

[25] T.C. Chang and C. William Ibbs, “Priority ranking – a fuzzy expert system for priority decision making in building construction resource scheduling,” Building and Environment, vol. 25, pp. 253-267, 1990.Search in Google Scholar

[26] J. Nabrzyski and J. Weglarz, “A knowledge – based multiobjective project scheduling system,” Journal of Decision Systems, vol. 3, pp. 185-200, 1994.Search in Google Scholar

[27] J. Conlin and A. Retik, “The applicability of project management software and advanced IT techniques in construction delays mitigation,” International Journal of Project Management, vol. 15, pp. 107-120, 1997.Search in Google Scholar

[28] V. Yannibelli and A. Amandi, “A knowledge-based evolutionary assistant to software development project scheduling,” Expert Systems with Applications, vol. 38, pp. 8403-8413, 2011.Search in Google Scholar

[29] V. S. Dave and K. Dutta, “Neural network based models for software effort estimation: A review,” Artificial Intelligence Review, vol. 42, pp. 295-307, 2014.Search in Google Scholar

[30] IBM. (2020, February 18, 2022.). Neural Networks. Available: https://www.ibm.com/cloud/learn/neural-networksSearch in Google Scholar

[31] S. Colak, A. Agarwal, and S.S. Erenguc, “Resource Constrained Project Scheduling: a Hybrid Neural Approach,” in Perspectives in Modern Project Scheduling, ed Boston, MA: Springer US, 2006, pp. 297-318.Search in Google Scholar

[32] A. Agarwal, S. Colak, and S. Erenguc, “A Neurogenetic approach for the resource-constrained project scheduling problem,” Computers & Operations Research, vol. 38, pp. 44-50, 2011.Search in Google Scholar

[33] C.T. Dimitrios, K.S. Ilias, and M.T. Kechadi, “Phased Method for Solving Multi-Objective MPM Job Shop Scheduling Problem,” International Journal of Monitoring and Surveillance Technologies Research (IJMSTR), vol. 4, pp. 42-61, 2016.Search in Google Scholar

[34] J.H. Rosłon and J.E. Kulejewski, “A hybrid approach for solving multi-mode resource-constrained project scheduling problem in construction,” Open Engineering, vol. 9, pp. 7-13, 2019.Search in Google Scholar

[35] J.M. Alostad, “Dynamic software management practices using genetically augmented neural networks,” International Journal of Internet Technology and Secured Transactions, vol. 10, pp. 322-336, 2022/02/12 2020.Search in Google Scholar

[36] W. Huang and L. Gao, “A Time Wave Neural Network Framework for Solving Time-Dependent Project Scheduling Problems,” IEEE Transactions on Neural Networks and Learning Systems, vol. 31, pp. 274-283, 2020.Search in Google Scholar

[37] S. Liu and W. Hao, “Forecasting the scheduling issues in engineering project management: Applications of deep learning models,” Future Generation Computer Systems, vol. 123, pp. 85-93, 2021.Search in Google Scholar

[38] P. Pagani and F. Pfann, “Deep Neural Networks for the Scheduling of Resource-Constrained Activity Sequences: A Preliminary Investigation,” Logistics Journal: Proceedings, vol. 2020, 2020.Search in Google Scholar

[39] G. Ma and M. Wu, “A Big Data and FMEA-based construction quality risk evaluation model considering project schedule for Shanghai apartment projects,” International Journal of Quality and Reliability Management, vol. 37, pp. 18-33, 2020.Search in Google Scholar

[40] X.-S. Yang, “2 - Mathematical foundations,” in Introduction to Algorithms for Data Mining and Machine Learning, ed: Academic Press, 2019, pp. 19-43.Search in Google Scholar

[41] P. Rezakhani, “Project scheduling and performance prediction: a fuzzy-Bayesian network approach,” Engineering, Construction and Architectural Management, vol. ahead-of-print, 2022/02/12 2021.Search in Google Scholar

[42] J.R. van Dorp, “A dependent project evaluation and review technique: A Bayesian network approach,” European Journal of Operational Research, vol. 280, pp. 689-706, 2020.Search in Google Scholar

[43] M.-Y. Cheng, Y.-F. Wu, Y.-W. Wu, and S. Ndure, “Fuzzy Bayesian schedule risk network for offshore wind turbine installation,” Ocean Engineering, vol. 188, p. 106238, 2019.Search in Google Scholar

[44] K.T. Knudsen and M. Blackburn, “A Knowledge and Analytics-Based Framework and Model for Forecasting Program Schedule Performance,” Procedia Computer Science, vol. 95, pp. 319-326, 2016.Search in Google Scholar

[45] T. Fatima, F. Azam, M.W. Anwar, and Y. Rasheed, “A Systematic Review on Software Project Scheduling and Task Assignment Approaches,” presented at the Proceedings of the 2020 6th International Conference on Computing and Artificial Intelligence, Tianjin, China, 2020.Search in Google Scholar

[46] K. a. H.B. Gersmann, “Improving iterative repair strategies for scheduling with the SVM,” Neurocomputing, vol. 63, pp. 271-292, 2005.Search in Google Scholar

[47] X.-S. Yang, S. Deb, and S. Fong, “Accelerated Particle Swarm Optimization and Support Vector Machine for Business Optimization and Applications,” Berlin, Heidelberg, 2011, pp. 53-66.Search in Google Scholar

[48] M. Dumić and D. Jakobović, “Ensembles of priority rules for resource constrained project scheduling problem,” Applied Soft Computing, vol. 110, p. 107606, 2021.Search in Google Scholar

[49] P.I. Adamu, H.I. Okagbue, and P.E. Oguntunde, “A New Priority Rule for Solving Project Scheduling Problems,” Wireless Personal Communications, vol. 106, pp. 681-699, 2019.Search in Google Scholar

[50] W. a. V.M. a. C.J. a. L.J. Guo, “Automatic detection of the best performing priority rule for the resource-constrained project scheduling problem,” Expert Systems with Applications, vol. 167, 2021.Search in Google Scholar

[51] P. a. R.-R.E. Jedrzejowicz, “Reinforcement Learning strategies for A-Team solving the Resource-Constrained Project Scheduling Problem,” Neurocomputing, vol. 146, pp. 301-307, 2014.Search in Google Scholar

[52] P. a. R.-R.E. Jędrzejowicz, “Reinforcement learning strategy for solving the MRCPSP by a team of agents,” Smart Innovation, Systems and Technologies, vol. 39, pp. 537-548, 2015.Search in Google Scholar

[53] X.-l. Zheng and L. Wang, “A multi-agent optimization algorithm for resource constrained project scheduling problem,” Expert Systems with Applications, vol. 42, pp. 6039-6049, 2015.Search in Google Scholar

[54] E. Ratajczak-Ropel, “Experimental Evaluation of Agentbased Approaches to Solving Multi-mode Resource-Constrained Project Scheduling Problem,” Cybernetics and Systems, vol. 49, pp. 296-316, 2018.Search in Google Scholar

[55] K.M. Sallam, R.K. Chakrabortty, and M.J. Ryan, “A reinforcement learning based multi-method approach for stochastic resource constrained project scheduling problems,” Expert Systems with Applications, vol. 169, p. 114479, 2021.Search in Google Scholar

[56] H. Zhang, G. Jiang, and T. Huang, “An Agent-based Optimization Approach for Distributed Project Scheduling in Supply Chain with Partial Information Sharing,” in ICAART (1), 2010, pp. 603-606.Search in Google Scholar

[57] F. Padberg and D. Weiss, “Model-Based Scheduling Analysis for Software Projects,” in 2011 IEEE 35th Annual Computer Software and Applications Conference Workshops, 2011, pp. 304-309.Search in Google Scholar

[58] F. Padberg and D. Weiss, “Optimal Scheduling of Software Projects Using Reinforcement Learning,” in 2011 18^th Asia-Pacific Software Engineering Conference, 2011, pp. 9-16.Search in Google Scholar

[59] S. Chen, S. Fang, and R. Tang, “A reinforcement learning based approach for multi-projects scheduling in cloud manufacturing,” International Journal of Production Research, vol. 57, pp. 3080-3098, 2019.Search in Google Scholar

[60] I. Sung, B. Choi, and P. Nielsen, “Reinforcement Learning for Resource Constrained Project Scheduling Problem with Activity Iterations and Crashing,” IFAC-PapersOnLine, vol. 53, pp. 10493-10497, 2020.Search in Google Scholar

[61] J. Borregan-Alvarado, I. Alvarez-Meaza, E. Cilleruelo-Carrasco, and G. Garechana-Anacabe, “A Bibliometric Analysis in Industry 4.0 and Advanced Manufacturing: What about the Sustainable Supply Chain?,” Sustainability, vol. 12, p. 7840, 2020.Search in Google Scholar

[62] M. Saunders, P. Lewis, and A. Thornhill, Research methods for business students: Pearson education, 2009.Search in Google Scholar

[63] A. Saihi, M. Ben-Daya, and R.A. As’ad, “Maintenance and sustainability: a systematic review of modeling-based literature,” Journal of Quality in Maintenance Engineering, vol. ahead-of-print, 2022/02/25 2022.Search in Google Scholar

[64] L.M. Kipper, L.B. Furstenau, D. Hoppe, R. Frozza, and S. Iepsen, “Scopus scientific mapping production in industry 4.0 (2011-2018): a bibliometric analysis,” International Journal of Production Research, vol. 58, pp. 1605-1627, 2020.Search in Google Scholar

[65] A.W. Harzing, “Publish or Perish,” ed, 2007.Search in Google Scholar

[66] O. Persson, “BibExcel,” ed, 2017.Search in Google Scholar

[67] O. Persson, R. Danell, and J. Schneider, “How to use Bibexcel for various types of bibliometric analysis,” Celebrating Scholarly Communication Studies: A Festschrift for Olle Persson at His 60^th Birthday, vol. 5, pp. 9-24, 2009.Search in Google Scholar

[68] N.J. van Eck and L. Waltman, “VOSviewer,” ed, 2010.Search in Google Scholar

[69] M. Bastian, S. Heymann, and M. Jacomy, “Gephi: an open source software for exploring and manipulating networks,” in Third international AAAI conference on weblogs and social media, 2009.Search in Google Scholar

[70] E.C.F. p. d. N. Garfield, “Citation Analysis as a Tool in Journal Evaluation,” Science, vol. 178, pp. 471-479, 2021/07/04/ 1972.Search in Google Scholar

[71] A.D. Sharplin and R.H. Mabry, “The Relative Importance of Journals Used in Management Research: An Alternative Ranking,” Human Relations, vol. 38, pp. 139-149, 2021/07/04 1985.Search in Google Scholar

[72] M.J. Culnan, “The Intellectual Development of Management Information Systems, 19721982: A CoCitation Analysis,” Management Science, vol. 32, p. 156, 1986.Search in Google Scholar

[73] A. a. C. S. a. E.S. Agarwal, “A Neurogenetic approach for the resource-constrained project scheduling problem,” Computers and Operations Research, vol. 38, pp. 44-50, 2011.Search in Google Scholar

[74] T. a. V.K. a. B.G.V. a. D.C.P. Wauters, “Learning agents for the multi-mode project scheduling problem,” Journal of the Operational Research Society, vol. 62, pp. 281-290, 2011.Search in Google Scholar

[75] A. Schirmer, “Case-Based Reasoning and Improved Adaptive Search for Project Scheduling,” Naval Research Logistics, vol. 47, pp. 201-222, 2000.Search in Google Scholar

[76] P. a. R.-R.E. Jedrzejowicz, “Team of a-teams for solving the resource-constrained project scheduling problem,” Frontiers in Artificial Intelligence and Applications, vol. 243, pp. 1201-1210, 2012.Search in Google Scholar

[77] Y. Ding and B. Cronin, “Popular and/or prestigious? Measures of scholarly esteem,” Information Processing & Management, vol. 47, pp. 80-96, 2011.Search in Google Scholar

[78] Y. Ding, E. Yan, A. Frazho, and J. Caverlee, “PageRank for ranking authors in co-citation networks,” Journal of the American Society for Information Science and Technology, vol. 60, pp. 2229-2243, 2021/07/10 2009.Search in Google Scholar

[79] S. Brin and L. Page, “The anatomy of a large-scale hypertextual Web search engine,” Computer Networks and ISDN Systems, vol. 30, pp. 107-117, 1998.Search in Google Scholar

[80] P. Chen, H. Xie, S. Maslov, and S. Redner, “Finding scientific gems with Google’s PageRank algorithm,” Journal of Informetrics, vol. 1, pp. 8-15, 2007.Search in Google Scholar

[81] B.K. Pathak, S. Srivastava, and K. Srivastava, “Neural network embedded multiobjective genetic algorithm to solve non-linear time-cost tradeoff problems of project scheduling,” Journal of Scientific and Industrial Research, vol. 67, pp. 124-131, 2008.Search in Google Scholar

[82] H. Small, “Co-Citation in the Scientific Literature: A New Measure of the Relationship Between Two Documents,” Journal of the American Society for Information Science, vol. 24, pp. 265-269, 1973.Search in Google Scholar

[83] A. Pilkington and C. Liston-Heyes, “Is production and operations management a discipline? A citation/cocitation study,” International Journal of Operations & Production Management, vol. 19, pp. 7-20, 2021/07/14 1999.Search in Google Scholar

[84] C. Chen, F. Ibekwe-Sanjuan, and J. Hou, “The Structure and Dynamics of Co-Citation Clusters: A Multiple-Perspective Co-Citation Analysis,” Journal of the American Society for Information Science and Technology, vol. 61, pp. 1386-1409, 2010.Search in Google Scholar

[85] A. Pilkington and J. Meredith, “The evolution of the intellectual structure of operations management – 1980-2006: A citation/co-citation analysis,” Journal of Operations Management, vol. 27, pp. 185-202, 2009.Search in Google Scholar

[86] L. Leydesdorff, “Bibliometrics/Citation networks,” arXiv pre-print server, 2015.Search in Google Scholar

[87] B. Hjørland, “Citation analysis: A social and dynamic approach to knowledge organization,” Information Processing & Management, vol. 49, pp. 1313-1325, 2013.Search in Google Scholar

[88] F. Radicchi, C. Castellano, F. Cecconi, V. Loreto, and D. Parisi, “Defining and identifying communities in networks,” Proceedings of the national academy of sciences, vol. 101, pp. 2658-2663, 2004.Search in Google Scholar

[89] A. Clauset, M.E.J. Newman, and C. Moore, “Finding community structure in very large networks,” Physical Review E, vol. 70, p. 066111, 2004.Search in Google Scholar

[90] L. Leydesdorff, “Bibliometrics/citation networks,” arXiv preprint arXiv:1502.06378, 2015.Search in Google Scholar

[91] V.D. Blondel, J.-L. Guillaume, R. Lambiotte, and E. Lefebvre, “Fast unfolding of communities in large networks,” Journal of Statistical Mechanics: Theory and Experiment, vol. 2008, p. P10008, 2008.Search in Google Scholar

[92] R. Kolisch and S. Hartmann, “Experimental investigation of heuristics for resource-constrained project scheduling: An update,” European Journal of Operational Research, vol. 174, pp. 23-37, 2006.Search in Google Scholar

[93] I. Kurtulus and E.W. Davis, “Multi-Project Scheduling: Categorization of Heuristic Rules Performance,” Management Science, vol. 28, pp. 161-172, 2021/07/10 1982.Search in Google Scholar

[94] R. Kolisch and A. Drexl, “Local search for nonpreemptive multi-mode resource-constrained project scheduling,” IIE Transactions, vol. 29, pp. 987-999, 1997.Search in Google Scholar

[95] R. Kolisch and A. Drexl, “Adaptive search for solving hard project scheduling problems,” Naval Research Logistics (NRL), vol. 43, pp. 23-40, 2021/11/12 1996.Search in Google Scholar

[96] G. Confessore, S. Giordani, and S. Rismondo, “A market-based multi-agent system model for decentralized multi-project scheduling,” Annals of Operations Research, vol. 150, pp. 115-135, 2007.Search in Google Scholar

[97] R.E. Korf, “Real-time heuristic search,” Artificial Intelligence, vol. 42, pp. 189-211, 1990.Search in Google Scholar

[98] R. Kolisch and R. Padman, “An integrated survey of deterministic project scheduling,” Omega, vol. 29, pp. 249-272, 2001.Search in Google Scholar

[99] L.P. Kaelbling, M.L. Littman, and A.W. Moore, “Reinforcement Learning: A Survey,” Journal of Artificial Intelligence Research, vol. 4, pp. 237-285, 1996.Search in Google Scholar

[100] F.B. Talbot and J.H. Patterson, “An Efficient Integer Programming Algorithm with Network Cuts for Solving Resource-Constrained Scheduling Problems,” Management Science, vol. 24, pp. 1163-1174, 2021/07/10 1978.Search in Google Scholar

[101] D. Debels and M. Vanhoucke, “A Decomposition-Based Genetic Algorithm for the Resource-Constrained Project-Scheduling Problem,” Operations Research, vol. 55, pp. 457-469, 2021/07/10 2007.Search in Google Scholar

[102] A. Nareyek, “Choosing Search Heuristics by Non-Stationary Reinforcement Learning,” vol. 86, 2001.Search in Google Scholar

[103] J.-K. Lee and Y.-D. Kim, “Search Heuristics for Resource Constrained Project Scheduling,” Journal of the Operational Research Society, vol. 47, pp. 678-689, 1996.Search in Google Scholar

[104] P. Brucker, A. Drexl, R. Möhring, K. Neumann, and E. Pesch, “Resource-constrained project scheduling: Notation, classification, models, and methods,” European Journal of Operational Research, vol. 112, pp. 3-41, 1999.Search in Google Scholar

[105] J.P. Cohoon, S.U. Hegde, W.N. Martin, and D. Richards, “Punctuated equilibria: a parallel genetic algorithm,” presented at the Proceedings of the Second International Conference on Genetic Algorithms on Genetic algorithms and their application, Cambridge, Massachusetts, USA, 1987.Search in Google Scholar

[106] J. Liu and K. Sycara, “Multiagent Coordination in Tightly Coupled Task Scheduling,” 1996.Search in Google Scholar

[107] V. Valls, F. Ballestín, and S. Quintanilla, “Justification and RCPSP: A technique that pays,” European Journal of Operational Research, vol. 165, pp. 375-386, 2005.Search in Google Scholar

[108] R. Kolisch, “Serial and parallel resource-constrained project scheduling methods revisited: Theory and computation,” European Journal of Operational Research, vol. 90, pp. 320-333, 1996.Search in Google Scholar

[109] H.S.N. a. D.T. Ndumu, “An introduction to agent technology,” Software Agents and Soft Computing Towards Enhancing Machine Intelligence, p. 1, 1997.Search in Google Scholar

[110] A. Drexl, “Scheduling of Project Networks by Job Assignment,” Management Science, vol. 37, pp. 1590-1602, 2021/07/04 1991.Search in Google Scholar

[111] L. Özdamar and G. Ulusoy, “A Survey on the Resource-Constrained Project Scheduling Problem,” Iie Transactions, vol. 27, pp. 574-586, 1995.Search in Google Scholar

[112] A. Agarwal, H. Pirkul, and V.S. Jacob, “Augmented neural networks for task scheduling,” European Journal of Operational Research, vol. 151, pp. 481-502, 2003.Search in Google Scholar

[113] H.V.D. Parunak, “Applications of distributed artificial intelligence in industry,” Foundations of distributed artificial intelligence, vol. 2, pp. 1-18, 1996.Search in Google Scholar

[114] J. Alcaraz, C. Maroto, and R. Ruiz, “Improving the performance of genetic algorithms for the RCPS problem,” Proceedings of the Ninth International Workshop on Project Management and Scheduling, pp. 40-43, 2004.Search in Google Scholar

[115] R. Kolisch and A. Sprecher, “PSPLIB – a project scheduling problem library,” Christian-Albrechts-Universität zu Kiel, Institut für Betriebswirtschaftslehre1996.Search in Google Scholar

[116] B.E. Pulk, “Improving software project management,” Journal of Systems and Software, vol. 13, pp. 231-235, 1990.Search in Google Scholar

[117] K. Bouleimen and H. Lecocq, “A new efficient simulated annealing algorithm for the resource-constrained project scheduling problem and its multiple mode version,” European Journal of Operational Research, vol. 149, pp. 268-281, 2003.Search in Google Scholar

[118] J.K. Lenstra and A. H. G. R. Kan, “Complexity of Scheduling under Precedence Constraints,” Operations Research, vol. 26, pp. 22-35, 1978.Search in Google Scholar

[119] S. Rostami, S. Creemers, and R. Leus, “New strategies for stochastic resource-constrained project scheduling,” Journal of Scheduling, vol. 21, pp. 349-365, 2018.Search in Google Scholar

[120] M. Wooldridge and N.R. Jennings, “Intelligent agents: theory and practice,” The Knowledge Engineering Review, vol. 10, pp. 115-152, 1995.Search in Google Scholar

[121] E.W. Davis and J.H. Patterson, “A Comparison of Heuristic and Optimum Solutions in Resource-Constrained Project Scheduling,” Management Science, vol. 21, pp. 944-955, 2021/08/02 1975.Search in Google Scholar

[122] S. Kirkpatrick, C.D. Gelatt, and M.P. Vecchi, “Optimization by Simulated Annealing,” Science, vol. 220, pp. 671-680, 2021/07/04/ 1983.Search in Google Scholar

[123] T. Hegazy, “Optimization of Resource Allocation and Leveling Using Genetic Algorithms,” Journal of Construction Engineering and Management-asce – J CONSTR ENG MANAGE-ASCE, vol. 125, 1999.Search in Google Scholar

[124] T.R. Browning and A.A. Yassine, “Resource-constrained multi-project scheduling: Priority rule performance revisited,” International Journal of Production Economics, vol. 126, pp. 212-228, 2010.Search in Google Scholar

[125] L. Liu, A. Burns Scott, and C.-W. Feng, “Construction Time-Cost Trade-Off Analysis Using LP/IP Hybrid Method,” Journal of Construction Engineering and Management, vol. 121, pp. 446-454, 2021/11/12 1995.Search in Google Scholar

[126] S.-S. Leu, C.-H. Yang, and J.-C. Huang, “Resource leveling in construction by genetic algorithm-based optimization and its decision support system application,” Automation in Construction, vol. 10, pp. 27-41, 2000.Search in Google Scholar

[127] J.F. Gonçalves, J.J.M. Mendes, and M.G.C. Resende, “A genetic algorithm for the resource constrained multi-project scheduling problem,” European Journal of Operational Research, vol. 189, pp. 1171-1190, 2008.Search in Google Scholar

[128] S.T. Ng and Y. Zhang, “Optimizing Construction Time and Cost Using Ant Colony Optimization Approach,” Journal of Construction Engineering and Management, vol. 134, pp. 721-728, 2021/11/12 2008.Search in Google Scholar

[129] H. Li and P. Love, “Using Improved Genetic Algorithms to Facilitate Time-Cost Optimization,” Journal of Construction Engineering and Management, vol. 123, pp. 233-237, 2021/11/12 1997.Search in Google Scholar

[130] D.F. Cooper, “Heuristics for Scheduling Resource-Constrained Projects: An Experimental Investigation,” Management Science, vol. 22, pp. 1186-1194, 2021/08/02 1976.Search in Google Scholar

[131] P. Bhupendra, “Project Scheduling using Meta Heuristics,” ed, 2007.Search in Google Scholar

[132] T. Neligwa, “An HMS Operational Model,” Agent-Based Manufacturing, p. 163, 2003.Search in Google Scholar

[133] Y. Laili, F. Tao, L. Zhang, Y. Cheng, Y. Luo, and B.R. Sarker, “A Ranking Chaos Algorithm for dual scheduling of cloud service and computing resource in private cloud,” Computers in Industry, vol. 64, pp. 448-463, 2013.Search in Google Scholar

[134] P. Bhupendra Kumar, S. Harish Kumar, and S. Sanjay, “Multi-resource-constrained discrete time-cost tradeoff with MOGA based hybrid method,” in 2007 IEEE Congress on Evolutionary Computation, 2007, pp. 4425-4432.Search in Google Scholar

[135] N.J. Nilsson, “Copyright,” in Artificial Intelligence: A New Synthesis, ed Oxford: Morgan Kaufmann, 1998, p. iv.Search in Google Scholar

[136] G. Lee and R.H. Katz, “Heterogeneity-Aware Resource Allocation and Scheduling in the Cloud,” HotCloud, vol. 11, pp. 4-8, 2011.Search in Google Scholar

[137] B. Pathak and S. Srivastava, “An intelligent approach for resource-constrained nonlinear multi-objective time-cost tradeoff,” vol. 14, ed. DEI Journal of Science and Engineering Research, 2008, pp. 153-163.Search in Google Scholar

[138] L. Li, “China’s manufacturing locus in 2025: With a comparison of “Made-in-China 2025” and “Industry 4.0”,” Technological Forecasting and Social Change, vol. 135, pp. 66-74, 2018.Search in Google Scholar

[139] B.K. Pathak and S. Srivastava, “MOGA-based time-cost tradeoffs: Responsiveness for project uncertainties,” in 2007 IEEE Congress on Evolutionary Computation, 2007, pp. 3085-3092.Search in Google Scholar

[140] F. Peña-Mora and C.-Y. Wang, “Computer-Supported Collaborative Negotiation Methodology,” Journal of Computing in Civil Engineering, vol. 12, pp. 64-81, 2021/11/12 1998.Search in Google Scholar

[141] A. Naber and R. Kolisch, “MIP models for resource-constrained project scheduling with flexible resource profiles,” European Journal of Operational Research, vol. 239, pp. 335-348, 2014.Search in Google Scholar

[142] C. Que Bryan, “Incorporating Practicability into Genetic Algorithm-Based Time-Cost Optimization,” Journal of Construction Engineering and Management, vol. 128, pp. 139-143, 2021/11/12 2002.Search in Google Scholar

[143] S. Oh, D. Lee, and S.R.T. Kumara, “Effective Web Service Composition in Diverse and Large-Scale Service Networks,” IEEE Transactions on Services Computing, vol. 1, pp. 15-32, 2008.Search in Google Scholar

[144] K. Hans Raj, R. S. Sharma, S. Srivastava, and C. Patvardhan, “Modeling of manufacturing processes with ANNs for intelligent manufacturing,” International Journal of Machine Tools and Manufacture, vol. 40, pp. 851-868, 2000.Search in Google Scholar

[145] C. Ramos, “A holonic approach for task scheduling in manufacturing systems,” in Proceedings of IEEE International Conference on Robotics and Automation, 1996, pp. 2511-2516 vol.3.Search in Google Scholar

[146] A.A.B. Pritsker, L.J. Watters, and P.M. Wolfe, “Multiproject Scheduling with Limited Resources: A Zero-One Programming Approach,” Management Science, vol. 16, pp. 93-108, 2021/11/12/ 1969.Search in Google Scholar

[147] S. Lin and B.W. Kernighan, “An Effective Heuristic Algorithm for the Traveling-Salesman Problem,” Operations Research, vol. 21, pp. 498-516, 2021/11/12 1973. Search in Google Scholar