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1. Stochastic Resource Allocation via Dual Tail Waterfilling

   https://doi.org/10.1109/CISS59072.2024.10480205  

   Yaylali, Gokberk; Kalogerias, Dionysis (March 2024, IEEE)

   Optimal resource allocation in wireless systems still stands as a rather challenging task due to the inherent statistical characteristics of channel fading. On the one hand, minimax/outage-optimal policies are often overconservative and analytically intractable, despite advertising maximally reliable system performance. On the other hand, ergodic-optimal resource allocation policies are often susceptible to the statistical dispersion of heavy-tailed fading channels, leading to relatively frequent drastic performance drops. We investigate a new risk-aware formulation of the classical stochastic resource allocation problem for point-to-point power-constrained communication networks over fading channels with no cross-interference, by leveraging the Conditional Value-at-Risk (CV@R) as a coherent measure of risk. We rigorously derive closed-form expressions for the CV@R-optimal risk-aware resource allocation policy, as well as the optimal associated quantiles of the corresponding user rate functions by capitalizing on the underlying fading distribution, parameterized by dual variables. We then develop a purely dual tail waterfilling scheme, achieving significantly more rapid and assured convergence of dual variables, as compared with the primal-dual tail waterfilling algorithm, recently proposed in the literature. The effectiveness of the proposed scheme is also readily confirmed via detailed numerical simulations. 

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2. Adaptive Risk Sensitive Path Integral for Model Predictive Control via Reinforcement Learning

   https://doi.org/10.1109/MED59994.2023.10185876  

   Yoon, Hyung-Jin; Tao, Chuyuan; Kim, Hunmin; Hovakimyan, Naira; Voulgaris, Petros (June 2023, editerranean Conference on Control and Automation (MED))

   We propose a reinforcement learning framework where an agent uses an internal nominal model for stochastic model predictive control (MPC) while compensating for a disturbance. Our work builds on the existing risk-aware optimal control with stochastic differential equations (SDEs) that aims to deal with such disturbance. However, the risk sensitivity and the noise strength of the nominal SDE in the riskaware optimal control are often heuristically chosen. In the proposed framework, the risk-taking policy determines the behavior of the MPC to be risk-seeking (exploration) or riskaverse (exploitation). Specifcally, we employ the risk-aware path integral control that can be implemented as a Monte-Carlo (MC) sampling with fast parallel simulations using a GPU. The MC sampling implementations of the MPC have been successful in robotic applications due to their real-time computation capability. The proposed framework that adapts the noise model and the risk sensitivity outperforms the standard model predictive path integ 

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3. Off-line Estimation of Controlled Markov Chains: Minimaxity and Sample Complexity

   https://doi.org/10.1287/opre.2023.0046  

   Banerjee, Imon; Honnappa, Harsha; Rao, Vinayak (February 2025, Operations Research)

   New Insights into Off-line Estimation for Controlled Markov Chains Unveiled A team of researchers from Purdue and Northwestern Universities have unveiled new findings in off-line estimation for controlled Markov chains, addressing challenges in analyzing complex data generated under arbitrary dynamics. The study introduces a nonparametric estimator for transition probabilities, showcasing its robustness even in nonstationary, non-Markovian environments. The team developed precise sample complexity bounds, revealing a delicate interplay between mixing properties of the logging policy and data set size. Their analysis highlights how achieving optimal statistical risk depends on this trade-off, broadening the scope of off-line estimation under diverse conditions. Examples include ergodic and weakly ergodic chains as well as controlled chains with episodic or greedy controls. Significantly, this research confirms that the widely used estimator, which calculates state–action transition ratios, is minimax optimal, ensuring its reliability in general scenarios. This advancement paves the way for improved evaluation of stationary Markov control policies, marking a breakthrough in understanding complex off-line systems. 

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4. Dynamic Resource Allocation in the Cloud with Near-Optimal Efficiency

   https://doi.org/10.1287/opre.2021.2138  

   Perez-Salazar, Sebastian; Menache, Ishai; Singh, Mohit; Toriello, Alejandro (October 2021, Operations Research)

   Cloud computing has motivated renewed interest in resource allocation problems with new consumption models. A common goal is to share a resource, such as CPU or I/O bandwidth, among distinct users with different demand patterns as well as different quality of service requirements. To ensure these service requirements, cloud offerings often come with a service level agreement (SLA) between the provider and the users. A SLA specifies the amount of a resource a user is entitled to utilize. In many cloud settings, providers would like to operate resources at high utilization while simultaneously respecting individual SLAs. There is typically a trade-off between these two objectives; for example, utilization can be increased by shifting away resources from idle users to “scavenger” workload, but with the risk of the former then becoming active again. We study this fundamental tradeoff by formulating a resource allocation model that captures basic properties of cloud computing systems, including SLAs, highly limited feedback about the state of the system, and variable and unpredictable input sequences. Our main result is a simple and practical algorithm that achieves near-optimal performance on the above two objectives. First, we guarantee nearly optimal utilization of the resource even if compared with the omniscient offline dynamic optimum. Second, we simultaneously satisfy all individual SLAs up to a small error. The main algorithmic tool is a multiplicative weight update algorithm and a primal-dual argument to obtain its guarantees. We also provide numerical validation on real data to demonstrate the performance of our algorithm in practical applications. 

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5. Two-stage linear decision rules for multi-stage stochastic programming

   https://doi.org/10.1007/s10107-018-1339-4  

   Bodur, Merve; Luedtke, James R. (October 2018, Mathematical Programming)

   Multi-stage stochastic linear programs (MSLPs) are notoriously hard to solve in general. Linear decision rules (LDRs) yield an approximation of an MSLP by restricting the decisions at each stage to be an affine function of the observed uncertain parameters. Finding an optimal LDR is a static optimization problem that provides an upper bound on the optimal value of the MSLP, and, under certain assumptions, can be formulated as an explicit linear program. Similarly, as proposed by Kuhn et al. (Math Program 130(1):177–209, 2011) a lower bound for an MSLP can be obtained by restricting decisions in the dual of the MSLP to follow an LDR. We propose a new approximation approach for MSLPs, two-stage LDRs. The idea is to require only the state variables in an MSLP to follow an LDR, which is sufficient to obtain an approximation of an MSLP that is a two-stage stochastic linear program (2SLP). We similarly propose to apply LDR only to a subset of the variables in the dual of the MSLP, which yields a 2SLP approximation of the dual that provides a lower bound on the optimal value of the MSLP. Although solving the corresponding 2SLP approximations exactly is intractable in general, we investigate how approximate solution approaches that have been developed for solving 2SLP can be applied to solve these approximation problems, and derive statistical upper and lower bounds on the optimal value of the MSLP. In addition to potentially yielding better policies and bounds, this approach requires many fewer assumptions than are required to obtain an explicit reformulation when using the standard static LDR approach. A computational study on two example problems demonstrates that using a two-stage LDR can yield significantly better primal policies and modestly better dual policies than using policies based on a static LDR. 

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