Interactive Cognitive Artifacts for Enhancing Situation Awareness of Incident Commanders in Mass Casualty Incidents

In mass casualty incidents (MCIs), incident commanders are responsible for managing operations, guiding rescue forces and applying resources appropriately. Data required for situation assessment and decision making are gathered and shared by numerous face-to-face talks, radio calls and paper-based forms. These tools and means of communication support flexible modes of operation but often lead to deficient awareness of the situation. Information sharing in the field is hampered and delayed. Interactive cognitive artifacts might improve the situations compared to using established paper-based artifacts by exchanging and visualizing data in real-time. However, because of users' workload and working conditions, designing mobile computer-based tools and systems for this context of use is a usability challenge. Based on the results of a two-year user-centered system design project with Emergency Medical Services, we discuss currently used and interactive cognitive artifacts for incident commanders. Challenges and approaches to successful user interface and interaction design are described.

[1]  William G. Griswold,et al.  Wireless Internet Information System for Medical Response in Disasters (WIISARD) , 2006, AMIA.

[2]  T Mentler,et al.  Routine Mobile Applications for Emergency Medical Services in Mass Casualty Incidents , 2012, Biomedizinische Technik. Biomedical engineering.

[3]  Thomas Ludwig,et al.  Ad Hoc Participation in Situation Assessment: Supporting Mobile Collaboration in Emergencies , 2014, TCHI.

[4]  William G. Griswold,et al.  Situational Awareness During Mass-Casualty Events: Command and Control , 2006, AMIA.

[5]  Daniel J. Garland,et al.  Situation Awareness Analysis and Measurement , 2009 .

[6]  Herbert A. Simon,et al.  The Sciences of the Artificial , 1970 .

[7]  John M. Carroll,et al.  Designing Interaction: Psychology at the Human-Computer Interface , 1991 .

[8]  Endsley,et al.  A model of inter- and intrateam situation awareness: implications for design, training and measurement , 2001 .

[9]  A Beck,et al.  [Analysis of the incidence and causes of mass casualty events in a southern Germany medical rescue area]. , 2002, Der Unfallchirurg.

[10]  Michael Herczeg,et al.  Routine- und Ausnahmebetrieb im mobilen Kontext des Rettungsdienstes , 2013, MuC.

[11]  Donald A. Norman,et al.  Cognitive artifacts , 1991 .

[12]  Christoph Stasch,et al.  Improving the Communication of Spatial Information in Crisis Response by Combining Paper Maps and Mobile Devices , 2009, Mobile Response.

[13]  William G. Griswold,et al.  Data Quality for Situational Awareness during Mass-Casualty Events , 2007, AMIA.

[14]  Mica R. Endsley,et al.  Toward a Theory of Situation Awareness in Dynamic Systems , 1995, Hum. Factors.

[15]  Anders Rüter,et al.  Increased situation awareness in major incidents-radio frequency identification (RFID) technique: a promising tool. , 2012, Prehospital and disaster medicine.

[16]  Sidharth Thakur,et al.  Big Board: Teleconferencing Over Maps for Shared Situational Awareness , 2013, Computer Supported Cooperative Work (CSCW).

[17]  Michael Herczeg,et al.  Applying ISO 9241-110 dialogue principles to tablet applications in emergency medical services , 2013, ISCRAM.

[18]  Thomas Ludwig,et al.  Information and Expertise Sharing in Inter-Organizational Crisis Management , 2014, Computer Supported Cooperative Work (CSCW).

[19]  Michael Herczeg,et al.  Care & Prepare - Usability Engineering for Mass Casualty Incidents , 2011, EICS4Med.

[20]  Steven Busby,et al.  Theory development for situational awareness in multi-casualty incidents. , 2011, Journal of emergency nursing: JEN : official publication of the Emergency Department Nurses Association.

[21]  John D. Lee,et al.  The Oxford Handbook of Cognitive Engineering , 2013 .