Event-Triggered Distributed Stochastic Mirror Descent for Convex Optimization
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Summary
This study introduces an event-triggered distributed stochastic mirror descent (ET-DSMD) algorithm for multiagent optimization under network constraints. The algorithm optimizes resource usage by reducing communication costs, ensuring convergence for distributed systems.
Area of Science:
- Optimization Theory
- Networked Systems
- Distributed Computing
Background:
- Distributed optimization problems in multiagent networks face challenges with bandwidth limitations and communication costs.
- Existing methods often require frequent information exchange, straining network resources.
Purpose of the Study:
- To develop an efficient distributed optimization algorithm for time-varying multiagent networks considering non-Euclidean settings and bandwidth constraints.
- To reduce communication overhead through an event-triggered strategy.
Main Methods:
- An event-triggered strategy (ETS) was applied to manage information interaction between agents.
- A novel event-triggered distributed stochastic mirror descent (ET-DSMD) algorithm was proposed, using Bregman divergence.
- Convergence analysis of the ET-DSMD algorithm was performed.
Main Results:
- The ET-DSMD algorithm effectively addresses distributed convex constrained optimization problems.
- An upper bound on the convergence rate for each agent was established, dependent on the trigger threshold.
- Sublinear convergence is guaranteed if the trigger threshold approaches zero over time.
Conclusions:
- The developed ET-DSMD algorithm is feasible and efficient for resource-constrained multiagent optimization.
- The event-triggered approach significantly reduces communication costs while maintaining convergence properties.
- The study provides a theoretical framework and practical validation through a logistic regression example.