Abstract: This paper examines inter-organizational governance within the context of a County wide Emergency Medical Services (EMS) system. Through a case study approach that included an action research methodology, this paper reports research findings on how one multi-organizational EMS system in California designed a process to establish an inter-organizational IT governance structure. The process resulted in EMS stakeholders defining architectural qualities that could be used to drive the EMS enterprise to a higher level of architecture maturity. That is, away from inherent business silos and towards greater levels of standardization and integration of information and technology across all stakeholder groups. The San Mateo County, CA Emergency Medical Services (EMS) system provided the case study context to better understand characteristics of a high performing emergency response system. The unique governance structure of this case allowed researchers to formulate a preliminary understanding of what IT governance is within this context and how it plays a role within private and not-for-profit sector large-scale, inter-organizational, emergency response systems. We applied the time critical information services (TCIS) framework to the specific setting of the San Mateo EMS strategic redesign initiative. The TCIS framework was used to drive roundtable discussions and in addition to obtaining a better understanding of the governance dimension, much was also learned about the operational and organizational dimensions of a high performing emergency response system. From these discussions, a set of 11 key findings were developed in order to guide the county's procurement strategy and future strategic direction. The impact of these findings is that they will be used to formulate public and private sector service contracts that will remain in effect for the next 10 years.

Abstract: In a crisis with casualties, while there is no medical intervention, the severity of the injuries increases, and some people may die. Since the number of rescuers is limited, it is necessary to perform a planning and a deployment of this resource on the basis of a risk criterion illustrating the potential increase of the number of casualties at each point of the concerned area. Emergency planning is still a poorly developed science [3]. This paper provides a dynamical model for the number of casualties, inspired from the Verhulst model classically used for biological systems [5], to evaluate this risk criterion as a function of future time. It calculates the evolution of the number of unrescued casualties, the number of dead people, and the number of rescued people, as a function of the number of rescuers. Numerical results are shown.

Abstract: In an extreme event or major disaster, very often there are both alternative actions that might be considered and far more requests for actions than can be executed immediately. The relative desirability of each option for action could be a collaborative expression of a significant number of emergency managers and experts trying to manage the most desirable alternatives at any given time, in real time. Delphi characteristics can satisfy these needs given that anyone can vote or change their vote on any two options, and voting and scaling are used to promote a group understanding. Further utilized with Thurstone's Law of Comparative Judgment, a group decision or the range of acceptability a group is willing to consent to, can be calculated and utilized as a means of producing the best decision. A ubiquitous system for expeditious real-time decision making by large virtual teams in emergency response environments is described.