A Multi-constraint and Multi-objective Allocation Model for Emergency Rescue in IoT Environment
This work addresses resource distribution for emergency responders in disaster scenarios, representing an incremental improvement over existing methods.
The paper tackled the problem of resource allocation in emergency rescue operations by developing the Multi-Objective Shuffled Gray-Wolf Frog Leaping Model (MSGW-FLM), which outperformed established models like NSGA-II, IBEA, and MOEA/D in tests on 28 diverse challenges.
Emergency relief operations are essential in disaster aftermaths, necessitating effective resource allocation to minimize negative impacts and maximize benefits. In prolonged crises or extensive disasters, a systematic, multi-cycle approach is key for timely and informed decision-making. Leveraging advancements in IoT and spatio-temporal data analytics, we've developed the Multi-Objective Shuffled Gray-Wolf Frog Leaping Model (MSGW-FLM). This multi-constraint, multi-objective resource allocation model has been rigorously tested against 28 diverse challenges, showing superior performance in comparison to established models such as NSGA-II, IBEA, and MOEA/D. MSGW-FLM's effectiveness is particularly notable in complex, multi-cycle emergency rescue scenarios, which involve numerous constraints and objectives. This model represents a significant step forward in optimizing resource distribution in emergency response situations.