Towards priority-awareness in autonomous intelligent systems

Samin, Huma; Paucar, Luis Hernán García; Bencomo, Nelly; Sawyer, Pete

doi:10.1145/3412841.3442007

Cited by 8 publications

(6 citation statements)

References 27 publications

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“…Consider the case in which all states belongs to (2 R−1 − 1) regions. In this case, (1) there are M states, (2) the region removal will happen at most (2 R−1 − 1) times in a state (lines 12-17), and (3) it needs to check the state's destination transition times after each removal (lines [20][21][22]. Therefore, the worst computational complexity of the former part is O(N a (2 R−1 − 1)).…”

Section: Theoretical Discussionmentioning

confidence: 99%

Efficient Difference Analysis of Guaranteeable Requirements for Fault-tolerant Self-adaptation

Tei

2023

Journal of Information Processing

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Modern systems suffer system faults in both hardware and software. Requirement degradation is a widely applied redundant-design approach to deal with system fault by degrading or disabling (non-critical) requirements. However, due to the environment's unpredictability, it is unrealistic for engineers to prepare such redundant designs for unforeseen and unknown faults in advance. Requirement-aware self-adaptive systems have been investigated to address this challenge. Specifically, such a system can autonomously analyze which requirements are guaranteeable so that the requirement degradation can be determined automatically to satisfy the maximal requirements. The previous work has proposed an algorithm to recognize the guaranteeable requirements by analyzing a two-player game between the environment and the system. However, such an algorithm is not designed for the system fault, and the entire game must be re-analyzed from scratch, making it inefficient for runtime adaptation. In this paper, we propose an efficient difference analysis algorithm that reuses the previous analysis result to reduce the runtime computational overhead. Specifically, it carefully specifies which part of the result is reusable and only re-analyzes the part that may be affected. We evaluated the algorithm's effectiveness with four case studies, and the results indicate that an average of 46.5% computational time is reduced.

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Section: Theoretical Discussionmentioning

confidence: 99%

Efficient Difference Analysis of Guaranteeable Requirements for Fault-tolerant Self-adaptation

Tei

2023

Journal of Information Processing

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“…To the best of our knowledge, RDMSim is the first simulator to be implemented for this domain. Using RDMSim, researchers can compare their self-adaptive decision-making solutions with other techniques, including ours [21]. We have executed experiments for each scenario presented here, using our own decision-making technique, called MR-POMDP++ [21].…”

Section: Discussionmentioning

confidence: 99%

“…Using RDMSim, researchers can compare their self-adaptive decision-making solutions with other techniques, including ours [21]. We have executed experiments for each scenario presented here, using our own decision-making technique, called MR-POMDP++ [21]. The results are provided in the RDMSimExemplar repository, ready to be used for comparison purposes.…”

Section: Discussionmentioning

confidence: 99%

“…For further validation purposes, we have applied reinforcement learning based decision-making to the RDMSim. We provide our initial evaluation results for the RDMSim using MR-POMDP++ [7], [21] as part of the RDMSimExemplar repository. MR-POMDP++ is based on Multi-Reward Partially Observable Markov Decision Process (MR-POMDP).…”

Section: Example: To Demonstrate Rdmsim Working Under Default and Det...mentioning

confidence: 99%

“…A Python version is also publicly available. Researchers can use these scenarios to test their specific decision-making techniques based on Reinforcement Learning [21], Multi-Criteria Decision Analysis [22] and Evolutionary Computation [3] among others. Researchers can also design their own scenarios by modifying the different parameter ranges.…”

Section: Introductionmentioning

confidence: 99%

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RDMSim: An Exemplar for Evaluation and Comparison of Decision-Making Techniques for Self-Adaptation

Samin¹,

Paucar²,

Bencomo³

et al. 2021

Preprint

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Decision-making for self-adaptation approaches need to address different challenges, including the quantification of the uncertainty of events that cannot be foreseen in advance and their effects, and dealing with conflicting objectives that inherently involve multi-objective decision making (e.g., avoiding costs vs. providing reliable service). To enable researchers to evaluate and compare decision-making techniques for selfadaptation, we present the RDMSim exemplar. RDMSim enables researchers to evaluate and compare techniques for decisionmaking under environmental uncertainty that support selfadaptation. The focus of the exemplar is on the domain problem related to Remote Data Mirroring, which gives opportunity to face the challenges described above. RDMSim provides probe and effector components for easy integration with external adaptation managers, which are associated with decision-making techniques and based on the MAPE-K loop. Specifically, the paper presents (i) RDMSim, a simulator for real-world experimentation, (ii) a set of realistic simulation scenarios that can be used for experimentation and comparison purposes, (iii) data for the sake of comparison.

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Decision-making under uncertainty: be aware of your priorities

2022

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Self-adaptive systems (SASs) are increasingly leveraging autonomy in their decision-making to manage uncertainty in their operating environments. A key problem with SASs is ensuring their requirements remain satisfied as they adapt. The trade-off analysis of the non-functional requirements (NFRs) is key to establish balance among them. Further, when performing the trade-offs it is necessary to know the importance of each NFR to be able to resolve conflicts among them. Such trade-off analyses are often built upon optimisation methods, including decision analysis and utility theory. A problem with these techniques is that they use a single-scalar utility value to represent the overall combined priority for all the NFRs. However, this combined scalar priority value may hide information about the impacts of the environmental contexts on the individual NFRs’ priorities, which may change over time. Hence, there is a need for support for runtime, autonomous reasoning about the separate priority values for each NFR, while using the knowledge acquired based on evidence collected. In this paper, we propose Pri-AwaRE, a self-adaptive architecture that makes use of Multi-Reward Partially Observable Markov Decision Process (MR-POMDP) to perform decision-making for SASs while offering awareness of NFRs’ priorities. MR-POMDP is used as a priority-aware runtime specification model to support runtime reasoning and autonomous tuning of the distinct priority values of NFRs using a vector-valued reward function. We also evaluate the usefulness of our Pri-AwaRE approach by applying it to two substantial example applications from the networking and IoT domains.

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Towards priority-awareness in autonomous intelligent systems

Cited by 8 publications

References 27 publications

Efficient Difference Analysis of Guaranteeable Requirements for Fault-tolerant Self-adaptation

Efficient Difference Analysis of Guaranteeable Requirements for Fault-tolerant Self-adaptation

RDMSim: An Exemplar for Evaluation and Comparison of Decision-Making Techniques for Self-Adaptation

Decision-making under uncertainty: be aware of your priorities

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