We found a match
Your institution may have access to this item. Find your institution then sign in to continue.
- Title
Hazmat risk area assessment by atmospheric dispersion modelling using Latin hypercube sampling with weather ensemble.
- Authors
Sigg, Robert; Lindgren, Petter; von Schoenberg, Pontus; Persson, Leif; Burman, Jan; Grahn, Håkan; Brännström, Niklas; Björnham, Oscar
- Abstract
Atmospheric dispersion modelling is always encumbered by errors and uncertainties originating from different aspects of the weather description as well as the source and dispersion models. Even so, the typical results from these kinds of studies are limited to one realization with no measure of uncertainties in either the temporal or spatial dimensions. This result is then to be interpreted as the most probable outcome given the current information. However, in many situations this limited result and the presentation thereof are far from satisfying and in the worst case even dangerously misleading. To address this shortcoming, this work presents a well‐established method for uncertainty investigation in simulations called Latin hypercube sampling in combination with a weather ensemble which results in an alternative way of estimating the resulting risk area as a function of weather forecast time from a statistical perspective. The main idea with this approach is to use the entire probability distribution of the simulation parameters instead of only one value as is the case in traditional methodology. This is a useful concept that provides additional and valuable information for decision makers. By applying weather ensembles a probabilistic field of risk area, following the atmospheric release of a hazardous substance, can be obtained, in contrast to a traditional deterministic field. This figure illustrates the profound difference that may occur when the risk area is estimated a few days in advance. A methodology to address this issue in combination with other sources of uncertainties is proposed and discussed.
- Subjects
RISK assessment of hazardous substances; DISPERSION (Atmospheric chemistry); LATIN hypercube sampling; WEATHER forecasting; UNCERTAINTY (Information theory)
- Publication
Meteorological Applications, 2018, Vol 25, Issue 4, p575
- ISSN
1350-4827
- Publication type
Article
- DOI
10.1002/met.1722