Safety performance monitoring of autonomous marine systems

The marine environment is vast, harsh, and challenging. Unanticipated faults and events might lead to loss of vessels, transported goods, collected scientific data, and business reputation. Hence, systems have to be in place that monitor the safety performance of operation and indicate if it drifts...

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Veröffentlicht in:	Reliability engineering & system safety 2017-03, Vol.159, p.264-275
Hauptverfasser:	Thieme, Christoph A., Utne, Ingrid B.
Format:	Artikel
Sprache:	eng
Schlagworte:	Autonomous marine systems Autonomous underwater vehicles Case studies Data processing Decision making Dual assurance Environmental monitoring Faults Indicators Life cycle engineering Life cycles Marine engineering Marine environment Marine systems Reliability engineering Resilience Safety Safety barriers Safety indicators
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container_title	Reliability engineering & system safety
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creator	Thieme, Christoph A. Utne, Ingrid B.
description	The marine environment is vast, harsh, and challenging. Unanticipated faults and events might lead to loss of vessels, transported goods, collected scientific data, and business reputation. Hence, systems have to be in place that monitor the safety performance of operation and indicate if it drifts into an intolerable safety level. This article proposes a process for developing safety indicators for the operation of autonomous marine systems (AMS). The condition of safety barriers and resilience engineering form the basis for the development of safety indicators, synthesizing and further adjusting the dual assurance and the resilience based early warning indicator (REWI) approaches. The article locates the process for developing safety indicators in the system life cycle emphasizing a timely implementation of the safety indicators. The resulting safety indicators reflect safety in AMS operation and can assist in planning of operations, in daily operational decision-making, and identification of improvements. Operation of an autonomous underwater vehicle (AUV) exemplifies the process for developing safety indicators and their implementation. The case study shows that the proposed process leads to a comprehensive set of safety indicators. It is expected that application of the resulting safety indicators consequently will contribute to safer operation of current and future AMS. •Process for developing safety indicators for autonomous marine systems.•Safety indicators based on safety barriers and resilience thinking.•Location of the development process in the system lifecycle.•Case study on AUV demonstrating applicability of the process.
doi_str_mv	10.1016/j.ress.2016.11.024
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source	ScienceDirect Journals (5 years ago - present)
subjects	Autonomous marine systems Autonomous underwater vehicles Case studies Data processing Decision making Dual assurance Environmental monitoring Faults Indicators Life cycle engineering Life cycles Marine engineering Marine environment Marine systems Reliability engineering Resilience Safety Safety barriers Safety indicators
title	Safety performance monitoring of autonomous marine systems
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