An Immune Memory and Negative Selection Based Decision Support System to Monitor and Control Public Bus Transportation Systems

“…We design a control system where information is distributed and decisions are decentralized over a set of “intelligent buses.” Each bus is able to make its own control decisions in a reactive manner to keep as close as possible to its preestablished timetable. Our suggestions extend the works of Mnif et al by providing a detailed description of a multiagent system to control public bus transportation systems. We provide a detailed representation of immune concepts, implementation of immune mechanisms in terms of learning and decision‐making algorithms, and their implementation within a hybrid multiagent system architecture.…”

“…It is able to memorize pathogens (learning feature) and to reuse this knowledge during future encounters with similar or identical substances (adaptation feature). Our suggestions extend the works of Mnif et al 42,43 by providing a detailed description of a multiagent system to control public bus transportation systems. 26 Artificial immune systems are widely used in many domains, such as traffic control, 27,28 monitoring and control, 29-31 fault detection and anomaly recovery, 32-34 optimization, [35][36][37][38] and mobile robotics.…”

“…The authors particularly developed a proof‐of‐concept prototype implementation on a single bus line to demonstrate the validity, pertinence, and usefulness of their suggestions. Mnif et al introduced a set of models to structure knowledge related to both disturbances and control decisions, as well as monitoring and control mechanisms based on immune memory and negative selection principles. These knowledge models and immune mechanisms were implemented as a multiagent decision support system to control disturbances in public bus transportation systems …”

An immune multiagent system to monitor and control public bus transportation systems

“…We design a control system where information is distributed and decisions are decentralized over a set of “intelligent buses.” Each bus is able to make its own control decisions in a reactive manner to keep as close as possible to its preestablished timetable. Our suggestions extend the works of Mnif et al by providing a detailed description of a multiagent system to control public bus transportation systems. We provide a detailed representation of immune concepts, implementation of immune mechanisms in terms of learning and decision‐making algorithms, and their implementation within a hybrid multiagent system architecture.…”

“…It is able to memorize pathogens (learning feature) and to reuse this knowledge during future encounters with similar or identical substances (adaptation feature). Our suggestions extend the works of Mnif et al 42,43 by providing a detailed description of a multiagent system to control public bus transportation systems. 26 Artificial immune systems are widely used in many domains, such as traffic control, 27,28 monitoring and control, 29-31 fault detection and anomaly recovery, 32-34 optimization, [35][36][37][38] and mobile robotics.…”

“…The authors particularly developed a proof‐of‐concept prototype implementation on a single bus line to demonstrate the validity, pertinence, and usefulness of their suggestions. Mnif et al introduced a set of models to structure knowledge related to both disturbances and control decisions, as well as monitoring and control mechanisms based on immune memory and negative selection principles. These knowledge models and immune mechanisms were implemented as a multiagent decision support system to control disturbances in public bus transportation systems …”

An immune multiagent system to monitor and control public bus transportation systems

Integration of Immune Features into a Belief-Desire-Intention Model for Multi-agent Control of Public Transportation Systems

Simulation of Agent-Based Negative Selection Model (ABNSM) for Reservoir Water Level Monitoring