Competitive Online Optimization under Inventory Constraints

Lin, Qiulin; Yi, Hanling; Pang, John Z. F.; Chen, Minghua; Wierman, Adam; Honig, Michael L.; Xiao, Yuanzhang

doi:10.1145/3376930.3376953

Cited by 3 publications

(13 citation statements)

References 4 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…• We design an algorithm for the general FOMKP problem with rate constraints that has a competitive ratio within an additive factor of one from the optimal competitive ratio. The algorithm also matches or improves upon best-known results in specific cases covered by recent papers, e.g., [25,44,45,48]. • We illustrate the performance of the algorithm in the context of EV charging using a tracebased case study, showing a decrease in the worst case by up to 44% and of the average case by around 20% as compared to fixed threshold policies, the most common approach in prior work on online knapsack problems.…”

Section: Introductionsupporting

confidence: 57%

“…For example, versions of online 0/1 knapsack [45], online multiple knapsacks, where items can be assigned across multiple knapsacks [48], and online fractional knapsack, where each item can be partially admitted [31]. Similarly, a wide set of variants of one-way trading have emerged, e.g., with [15] or without [44] leftover assets, and concave returns [25]. The disconnected nature of these literatures begs the question: Is it possible for a unified algorithmic approach to be developed or does each variant truly require a carefully crafted approach?…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Competitive Algorithms for the Online Multiple Knapsack Problem with Application to Electric Vehicle Charging

Sun

Zeynali

et al. 2021

Abstract Proceedings of the 2021 ACM SIGMETRICS / International Conference on Measurement and Modeling of Computer Systems

Self Cite

View full text Add to dashboard Cite

We introduce and study a general version of the fractional online knapsack problem with multiple knapsacks, heterogeneous constraints on which items can be assigned to which knapsack, and rate-limiting constraints on the assignment of items to knapsacks. This problem generalizes variations of the knapsack problem and of the one-way trading problem that have previously been treated separately, and additionally finds application to the real-time control of electric vehicle (EV) charging. We introduce a new algorithm that achieves a competitive ratio within an additive factor of one of the best achievable competitive ratios for the general problem and matches or improves upon the best-known competitive ratio for special cases in the knapsack and one-way trading literatures. Moreover, our analysis provides a novel approach to online algorithm design based on an instance-dependent primal-dual analysis that connects the identification of worst-case instances to the design of algorithms. Finally, we illustrate the proposed algorithm via trace-based experiments of EV charging. CCS Concepts: • Theory of computation → Online algorithms; • Applied computing → Decision analysis; • Networks → Network economics.

show abstract

Section: Introductionsupporting

confidence: 57%

Section: Introductionmentioning

confidence: 99%

Competitive Algorithms for the Online Multiple Knapsack Problem with Application to Electric Vehicle Charging

Sun

Zeynali

et al. 2021

Abstract Proceedings of the 2021 ACM SIGMETRICS / International Conference on Measurement and Modeling of Computer Systems

Self Cite

View full text Add to dashboard Cite

show abstract

“…In the remainder of the paper, we sometimes write Regret( ), in replacement of Regret(u) defined in (3), with = (c : + −1 , : + −1 (•|u < )). It is worth mentioning that, to the best of our knowledge, there is no existing bound on the dynamic regret defined in (3) in the current setting, nor are there existing results for a similar worst-case metric called competitive ratio [11,[34][35][36]43].…”

Section: Dynamic Regretmentioning

confidence: 99%

“…Example 1 (Inventory constraints). Consider the following set of inventory constraints, which is a common form of constraints in energy storage and demand response problems [30,35,45]. The summation of the squares of the ℓ 2 norms of the actions is bounded from above by > 0, representing the limited resources of the system: =1 || || 2 2 ≤ where ∈ R .…”

Section: Causally Invariant Safety Constraintsmentioning

confidence: 99%

“…Designing controllers for the general constrained dynamics in ( 1) is challenging and, as a result, traditional online optimization models often adopt simplified versions of (1), such as unconstrained optimization [11,22,38] or time-invariant constraints [26,27] that are known a priori. More specifically, previous studies in online control and online optimization mostly focus on specific forms of constraints or costs depending on different applications, such as switching costs [17,33,35,43], ramping constraints [4,43], polytopic constraints [16], time-varying memoryless cumulative constraints [9,46,[48][49][50], convex loss functions with memory [1][2][3]42] or inventory constraints [30,35]. Within this literature, the goal is to derive policies with either small regret [9,15,33,35,49,51] or competitive ratio [4,17,34,42,43].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Information Aggregation for Constrained Online Control

Chen

Sun

et al. 2021

Proc. ACM Meas. Anal. Comput. Syst.

Self Cite

View full text Add to dashboard Cite

This paper considers an online control problem involving two controllers. A central controller chooses an action from a feasible set that is determined by time-varying and coupling constraints, which depend on all past actions and states. The central controller's goal is to minimize the cumulative cost; however, the controller has access to neither the feasible set nor the dynamics directly, which are determined by a remote local controller. Instead, the central controller receives only an aggregate summary of the feasibility information from the local controller, which does not know the system costs. We show that it is possible for an online algorithm using feasibility information to nearly match the dynamic regret of an online algorithm using perfect information whenever the feasible sets satisfy a causal invariance criterion and there is a sufficiently large prediction window size. To do so, we use a form of feasibility aggregation based on entropic maximization in combination with a novel online algorithm, named Penalized Predictive Control (PPC) and demonstrate that aggregated information can be efficiently learned using reinforcement learning algorithms. The effectiveness of our approach for closed-loop coordination between central and local controllers is validated via an electric vehicle charging application in power systems.

show abstract