Sadeghi, Alireza2021-10-132021-10-132021-08https://hdl.handle.net/11299/225028University of Minnesota Ph.D. dissertation. 2021. Major: Electrical Engineering. Advisor: Georgios Giannakis. 1 computer file (PDF); xii, 176 pages.Data-driven machine learning advances have effectively handled a wide spectrum of ap- plication domains. However, formidable challenges remain, especially for managing and opti- mizing the next-generation complex cyber-physical systems, autonomously-driving cars, and self-surgical systems, which welcome ground-breaking control, monitoring, and decision mak- ing that can guarantee robustness, scalability, and situational awareness. In this context, the present thesis first develops principled methods to robustify learning models against distributional uncertainties and adversarial data. The developed framework is particularly attractive when training and testing data are drawn from mismatched distributions. By leveraging the Wasserstein distance, the novel approaches minimize the worst-case expected loss over a prescribed family of data distributions. Building on this robust framework, the thesis next introduces a robust semi-supervised learning approach over networked data whose interdependencies are captured by graphs. Subsequently, the thesis contributes machine learning tools for next-generation wired and wireless networks, through the design of intelligent caching modules using deep reinforcement learning. These modules are equipped with storage devices, and can thus prefetch popular contents (reusable information) during off-peak traffic hours, and service them to the network edge at peak traffic instances. Finally, the thesis contributes to the management and control of power networks, and specifically distribution grids with high penetration of renewable sources and demand response programs. Reactive power is optimally allocated to both utility-owned control devices (e.g., capacitor banks), as well as smart inverters of distributed generation units with cyber-capabilities. The resultant novel dynamic control algorithms are scalable and adaptive to real-time changes of renewable generation and load consumption. To further enhance the situational awareness in power networks, the thesis further contributes robust power system state estimation solvers.enRobust, Deep, and Reinforcement Learning for Management of Communication and Power NetworksThesis or Dissertation