Farmers, suppliers, processors, distributors, other consumers, and other stakeholders are all part of a typical agricultural supply chain. The Supply Chain optimization in Agriculture becomes increasingly complex and risky as a result of the numerous entities involved. The impact of external factors on agricultural productivity, such as weather, pests, and diseases, which are difficult to anticipate and control, makes meeting the established targets even more difficult.
The lack of traceability in the agricultural supply chain, as well as delayed financial transactions, extensive manual labor, and other issues, create concerns about the agricultural supply chain’s efficacy. Counterfeits may also surface at any point along the supply chain, posing a threat to all business stakeholders, governments, and consumers.
The structure and optimization of essential agricultural supply chains are becoming increasingly important as global food security becomes a major policy problem. In turn, while several supply chain optimization working models have been constructed to ensure analytic tractability, others are developing more detailed characterizations of a supply chain as a complex system that may not be accessible to analytic solution.
This study looks at a Supply Chain optimization in Agriculture in order to find efficient answers to challenging internal optimization concerns that could have an impact on food security. To this purpose, the Canadian wheat handling system is a complicated export-oriented Supply Chain optimization in Agriculture that is undergoing significant quality control adjustments at the moment.
With the ultimate goal of identifying successful wheat quality testing procedures in a complex operational and regulatory context, we construct both analytic and simulation models of this supply chain.
While the analytic model is built on a set of assumptions about person behavior, agent-based simulation allows us to model farmers and handlers as rational, learning individuals who make decisions based on their own and others’ experiences. The answers and policies obtained using the simulation approach are then compared to those generated using the analytically tractable model of the wheat supply chain.
For a proper assessment of the environmental performance of logistic activities, the design and planning of more sustainable supply chains should take into account many consequences. Unfortunately, minimizing many environmental objectives at the same time leads to difficult optimization issues. This research proposes a rigorous computational methodology for solving complicated multi-objective optimization (MOO) issues in logistic task optimization under economic and environmental constraints.
The use of an objective reduction technique is a critical component of our strategy, as it allows us to discover duplicate objectives that may be eliminated while keeping the issue structure as intact as possible.
A major problem for the agriculture industry is lowering shipping costs.
Supply Chain optimization in Agriculture efficiency and cost optimization, which accounts for up to 70% of total expenses in the cereals market, is a critical issue for the industry and hence a crucial lever for increasing net income.
The supply chain is becoming increasingly complex.
The complexity of this supply chain, as well as its set of restrictions, is immense, with various parties and infrastructures involved from harvest to distribution to end customers.