Tackling uncertainties in self-optimizing systems by strategy blending

2011 IEEE Workshop on Evolving and Adaptive Intelligent Systems (EAIS) Pub Date : 2011-04-11 DOI:10.1109/EAIS.2011.5945920

N. Rosemann, W. Brockmann, Rolf Thomas Hänel

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Abstract

Complex technical applications often show severe uncertainties, which may vary over time, e.g., situation dependent sensor inaccuracies or anomalies and faults. In order to ease the engineering process for such systems, organic computing principles, e.g., self-adaptation and self-optimization, offer a solution. Hence, machine learning paradigms are needed which work online and which can cope with such dynamically varying uncertainties, but still operate safely all the time. In this work, such a learning paradigm is developed based on the Organic Robot Control Architecture and the incremental learning scheme Directed Self-Learning. It is combined with an explicit uncertainty representation. The core idea is to use a strategy blending scheme to show a good performance and improve it by self-optimizing learning on the one hand in case of high trust, or low uncertainty, respectively. On the other hand, a robust fallback-system is used to ensure safety in situations of high uncertainty. Of course, in such situations learned knowledge has to be protected from corruption. The feasibility of this approach is demonstrated in a simulated pick-and-place scenario with unknown, but changing load masses.

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用策略混合处理自优化系统中的不确定性

复杂的技术应用往往表现出严重的不确定性，这种不确定性可能随着时间的推移而变化，例如，与情况有关的传感器不准确或异常和故障。为了简化这类系统的工程过程，有机计算原理，如自适应和自优化，提供了一种解决方案。因此，需要在线工作的机器学习范式，它可以应对这种动态变化的不确定性，但仍然可以安全运行。在这项工作中，基于有机机器人控制体系结构和增量学习方案定向自学习开发了这样一个学习范式。它与明确的不确定性表示相结合。其核心思想是在高信任和低不确定性的情况下，一方面使用策略混合方案来表现良好的性能，另一方面通过自优化学习来改进。另一方面，采用了鲁棒的后备系统，以确保在高度不确定性情况下的安全。当然，在这种情况下，必须保护学到的知识免受腐败。该方法的可行性在一个未知但不断变化的负载质量的模拟拾取场景中得到了验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2011 IEEE Workshop on Evolving and Adaptive Intelligent Systems (EAIS)

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