The key highlights and insights of the content are:
The authors propose a continuous-time distributed optimization algorithm to solve a multi-agent optimization problem with coupled linear constraints.
The algorithm introduces auxiliary decision variables to decouple the original problem, and updates these variables using a subgradient-based approach. This allows the algorithm to guarantee zero constraint violation during the solution evolution.
The algorithm is shown to asymptotically converge to the optimal solution of the centralized problem under mild assumptions. It also has favorable properties in terms of memory, computation, and communication efficiency compared to existing distributed optimization methods.
The authors further consider a sparse case where the coupling constraints have a structure consistent with the communication graph. This allows for even more efficient implementation of the algorithm.
The authors apply the proposed distributed optimization algorithm to the problem of safe distributed control, where control barrier functions are used to enforce safety constraints. For this case, they develop a variant of the algorithm that achieves finite-time convergence.
Numerical results demonstrate the effectiveness and efficiency of the proposed algorithms in solving static resource allocation problems and safe coordination problems for multi-agent systems.
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