Sensemaking in Safety Critical and Complex Situations
Human Factors and Design
Herausgeber: Johnsen, Stig Ole; Porathe, Thomas
Sensemaking in Safety Critical and Complex Situations
Human Factors and Design
Herausgeber: Johnsen, Stig Ole; Porathe, Thomas
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This book describes how Human Factors and Sensemaking can be used as part of the concept and design of safety critical systems, in order to improve safety and resilience.
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This book describes how Human Factors and Sensemaking can be used as part of the concept and design of safety critical systems, in order to improve safety and resilience.
Produktdetails
- Produktdetails
- Verlag: Taylor and Francis
- Seitenzahl: 270
- Erscheinungstermin: 13. Oktober 2021
- Englisch
- Abmessung: 234mm x 156mm x 18mm
- Gewicht: 590g
- ISBN-13: 9780367435189
- ISBN-10: 0367435187
- Artikelnr.: 62505289
- Verlag: Taylor and Francis
- Seitenzahl: 270
- Erscheinungstermin: 13. Oktober 2021
- Englisch
- Abmessung: 234mm x 156mm x 18mm
- Gewicht: 590g
- ISBN-13: 9780367435189
- ISBN-10: 0367435187
- Artikelnr.: 62505289
Thomas Porathe Professor of Interaction Design at Norwegian University of Science and Technology; Earlier Associate professor in Human Factors at the Department of Shipping and Marin Technology at Chalmers University of Technology, Sweden Research projects: 2015-2018 ONSITE (Design Driven Field Studies for Safer Demanding Marine Operations); 2015-2017 REMOTE Development of concepts for control rooms for fish farms Book Chapters: Porathe, T et al. (2015). Supporting Situation Awareness on the bridge: testing route exchange in a practical e-Navigation study. In A. Weintrit, & T. Neumann (Eds.) Information, Communication and Environment: Marine Navigation and Safety of Sea Transportation: CRC Press Stig Ole Johnsen Senior research scientist at SINTEF, affiliated NTNU. PhD at NTNU and Master of Technology Management, degree from MiT (Massachusetts institute of Technology/ Sloan School of Management) and NTNU. Chair of Human Factors in Control network in Norway with 800 participants; arranging two Human Factors Conferences each year; ESREL Chair of Accident Investigation. Written several book chapters; Journal and Conference papers published regularly.
1. Introduction, how HMI has been evolving 2. A Guide to Human Factors in
Accident Investigation 3. What makes a task safety critical? 4. A
barrier-based and easy-to-use roadmap for determining task criticality 4.
Making sense of sensemaking in high-risk organizations 5. Prospective
Sensemaking in Complex Organizational Domains: A Case and some Reflections
6. The Challenges of Sensemaking and Human Factors in the maritime sector -
exploring the Helge Ingstad accident 7. Addressing Human Factors in Ship
Design: Shall We? 8. Sensemaking in practical design: a navigation app for
fast leisure boats 9. Unified Bridge - design concepts and results 10.
Supporting Consistent Design and Sensemaking Across Ship Bridge Equipment
Through Open Innovation 11. User Centred Agile Development to Support
Sensemaking 12. Improving safety by learning from automation in transport
systems with a focus on sensemaking and meaningful human control. 13.
Application of Sensemaking: Data/Frame Model, to UAS AIB Reports can
Increase UAS GCS Resilience to Human Factor and Ergonomics (HF/E)
Shortfalls 14. Constrained autonomy for a better human-automation interface
15. HMI measures for improved sensemaking in Dynamic Positioning operations
Accident Investigation 3. What makes a task safety critical? 4. A
barrier-based and easy-to-use roadmap for determining task criticality 4.
Making sense of sensemaking in high-risk organizations 5. Prospective
Sensemaking in Complex Organizational Domains: A Case and some Reflections
6. The Challenges of Sensemaking and Human Factors in the maritime sector -
exploring the Helge Ingstad accident 7. Addressing Human Factors in Ship
Design: Shall We? 8. Sensemaking in practical design: a navigation app for
fast leisure boats 9. Unified Bridge - design concepts and results 10.
Supporting Consistent Design and Sensemaking Across Ship Bridge Equipment
Through Open Innovation 11. User Centred Agile Development to Support
Sensemaking 12. Improving safety by learning from automation in transport
systems with a focus on sensemaking and meaningful human control. 13.
Application of Sensemaking: Data/Frame Model, to UAS AIB Reports can
Increase UAS GCS Resilience to Human Factor and Ergonomics (HF/E)
Shortfalls 14. Constrained autonomy for a better human-automation interface
15. HMI measures for improved sensemaking in Dynamic Positioning operations
1. Introduction, how HMI has been evolving 2. A Guide to Human Factors in
Accident Investigation 3. What makes a task safety critical? 4. A
barrier-based and easy-to-use roadmap for determining task criticality 4.
Making sense of sensemaking in high-risk organizations 5. Prospective
Sensemaking in Complex Organizational Domains: A Case and some Reflections
6. The Challenges of Sensemaking and Human Factors in the maritime sector -
exploring the Helge Ingstad accident 7. Addressing Human Factors in Ship
Design: Shall We? 8. Sensemaking in practical design: a navigation app for
fast leisure boats 9. Unified Bridge - design concepts and results 10.
Supporting Consistent Design and Sensemaking Across Ship Bridge Equipment
Through Open Innovation 11. User Centred Agile Development to Support
Sensemaking 12. Improving safety by learning from automation in transport
systems with a focus on sensemaking and meaningful human control. 13.
Application of Sensemaking: Data/Frame Model, to UAS AIB Reports can
Increase UAS GCS Resilience to Human Factor and Ergonomics (HF/E)
Shortfalls 14. Constrained autonomy for a better human-automation interface
15. HMI measures for improved sensemaking in Dynamic Positioning operations
Accident Investigation 3. What makes a task safety critical? 4. A
barrier-based and easy-to-use roadmap for determining task criticality 4.
Making sense of sensemaking in high-risk organizations 5. Prospective
Sensemaking in Complex Organizational Domains: A Case and some Reflections
6. The Challenges of Sensemaking and Human Factors in the maritime sector -
exploring the Helge Ingstad accident 7. Addressing Human Factors in Ship
Design: Shall We? 8. Sensemaking in practical design: a navigation app for
fast leisure boats 9. Unified Bridge - design concepts and results 10.
Supporting Consistent Design and Sensemaking Across Ship Bridge Equipment
Through Open Innovation 11. User Centred Agile Development to Support
Sensemaking 12. Improving safety by learning from automation in transport
systems with a focus on sensemaking and meaningful human control. 13.
Application of Sensemaking: Data/Frame Model, to UAS AIB Reports can
Increase UAS GCS Resilience to Human Factor and Ergonomics (HF/E)
Shortfalls 14. Constrained autonomy for a better human-automation interface
15. HMI measures for improved sensemaking in Dynamic Positioning operations