Minimizing delay of ships in bulk terminals by simultaneous ship scheduling, stockyard planning and train scheduling S o u d a g a r A . K . I r f a n B a b u a , S a u r a b h P r a t a p a , G e e t L a h o t i a , K i r a n J . F e r n a n d e s b , M a n o j K . T i w a r i a , M a t t h e w M o u n t c a n d Y u X i o n g d A b s t r a c t Because of an increase in population, the demand for coal has drastically risen with millions of tons of coal being imported annually through Indian ports. To accommodate with this rise in demand, there has been an increase in the concern over proper ship scheduling and effective stockyard management. This article focuses on these aspects, as well as train scheduling, in the context of coal imports in port terminals. The article employs two heuristic-based greedy construct algorithms to improve port terminal throughput capacity by minimizing the delay of ships in port terminal. Applicability and validity of the model is tested on the database of a port located along the east coast of India.
This research formulates a multi-objective problem (MOP) for supply chain network (SCN) design by incorporating the issues of social relationship, carbon emissions, and supply chain risks such as disruption and opportunism. The proposed MOP includes three conflicting objectives: maximization of total profit, minimization of supply disruption and opportunism risks, and minimization of carbon emission considering a number of supply chain constraints. Furthermore, this research analyses the effect of social relationship levels between different tiers of SCN on the profitability, risk, and emission over the time. In this regard, we focus on responding to the following questions. (1) How does the evolving social relationship affect the objectives of the supply chain (SC)? (2) How do the upstream firms' relationships affect the relationships of downstream firms, and how these relationships influence the objectives of the SC? (3) How does the supply disruption risk interact with the opportunism risk through supply chain relationships, and how these risks affect the objectives of the SC? (4) How do these three conflicting objectives trade-off? A Pareto-based multiobjective evolutionary algorithm-non-dominated sorting genetic algorithm-II (NSGA-II) has been employed to solve the presented problem. In order to improve the quality of solutions, tuning parameters of the NSGA-II are modulated using Taguchi approach. An illustrative example is presented to manifest the capability of the model and the algorithm. The results obtained evince the robust performance of the proposed MOP.
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