In this paper, distributed dynamics are deployed to solve resource allocation over time-varying multi-agent networks. The state of each agent represents the amount of resources used/produced at that agent while the total amount of resources is fixed. The idea is to optimally allocate the resources among the group of agents by reducing the total cost functions subject to fixed amount of total resources. The information of each agent is restricted to its own state and cost function and those of its immediate neighbors. This is motivated by distributed applications such as in mobile edge-computing, economic dispatch over smart grids, and multi-agent coverage control. The non-Lipschitz dynamics proposed in this work shows fast convergence as compared to the linear and some nonlinear solutions in the literature. Further, the multi-agent network connectivity is more relaxed in this paper. To be more specific, the proposed dynamics even reaches optimal solution over time-varying disconnected undirected networks as far as the union of these networks over some bounded non-overlapping time-intervals includes a spanning-tree. The proposed convergence analysis can be applied for similar 1st-order resource allocation nonlinear dynamics. We provide simulations to verify our results.
翻译:在本文中,分布式动态用于解决时间变化多试剂网络的资源分配问题。每个代理商的状况代表该代理商使用/生产的资源数量,而资源总量是固定的。想法是通过减少总成本功能,在资源总量固定的情况下,优化在代理商群体中分配资源。每个代理商的信息仅限于其自身的状态和成本功能,以及其近邻的状态和成本功能。这得益于分布式应用程序,如移动边缘计算、智能网格上的经济发送和多试剂覆盖控制。这项工作中提议的非Lipschitz动态显示与文献中的线性和非线性解决方案的快速趋同。此外,多代理商网络连接在本文中更为宽松。更具体地说,拟议的动态甚至对于时间变化的断开的无方向网络达成最佳解决方案,只要这些网络与某些不重叠的时间间隔的连接包括一条横跨线。拟议中的趋同分析可以适用于类似的一阶资源分配非线性非线性动态。我们提供模拟来核查结果。