Abstract
We consider several real-world driving factors such as the time spent at traffic signs (e.g., yield signs and stop signs), speed limits, and the topology of the surface to develop realistic and accurate routing solutions. Though these factors increase the complexity of modeling, they provide the flexibility to evaluate the routing solutions from different perspectives: cost, distance, and time, to name a few. First, we develop a set of algorithms based on the Riemannian manifold surface (RMS) to factor in the Earth’s curvature to calculate distances. Second, we present a multiobjective, nonlinear, mixed-integer model (MINLP) that minimizes the distance traveled, time traveled, traveling costs, and time spent on traffic signs to design and evaluate the routes where the waiting times associated with traffic lights, stop signs, and yield signs are stochastic. Finally, we apply MINLP and RMS-based algorithms to a set of real-life and short- and long-distance transportation problems and analyze the results from computational experiments and discrete event simulations. We show that our approaches are on par with the state-of-the-art application, Google Maps, and yield realistic routing solutions that generate significant cost savings.
Highlights
Transportation is one of the essential activities in a supply chain
We formulate a mathematical programming model that considers the real-world driving factors such as the time spent at traffic signs and speed limits to evaluate routing decisions from multiple perspectives: cost, distance, and time, to name a few
We consider several real-world driving factors such as the time spent at traffic signs, speed limits, and the topology of the surface to develop realistic and accurate routing solutions. ough these factors increase the complexity of modeling, they provide the flexibility to evaluate the routing solutions from different perspectives: cost, distance, and time, to name a few
Summary
Transportation is one of the essential activities in a supply chain. For example, goods manufactured at plant locations must be distributed to customer locations through warehouses, distribution centers, or cross-docking facilities. Existing global positioning and global information systems do not provide, for example, the impact of traffic signals on travel cost and time and the flexibility to evaluate routing decisions using various criteria These systems do not consider local shortest geodesic distances. We illustrate two key concepts that are used in our methodology: (i) Riemannian manifold surface- (RMS-) based approach to calculate the distance; (ii) multiple criteria to evaluate the routes. We formulate a mathematical programming model that considers the real-world driving factors such as the time spent at traffic signs (e.g., yield signs and stop signs) and speed limits to evaluate routing decisions from multiple perspectives: cost, distance, and time, to name a few.
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