Book contents
- Frontmatter
- Contents
- List of Contributors
- 1 Introduction
- 2 Integrated regional risk assessment and safety management: Challenge from Agenda 21
- 3 Risk analysis: The unbearable cleverness of bluffing
- 4 Aspects of uncertainty, reliability, and risk in flood forecasting systems incorporating weather radar
- 5 Probabilistic hydrometeorological forecasting
- 6 Flood risk management: Risk cartography for objective negotiations
- 7 Responses to the variability and increasing uncertainty of climate in Australia
- 8 Developing an indicator of a community's disaster risk awareness
- 9 Determination of capture zones of wells by Monte Carlo simulation
- 10 Controlling three levels of uncertainties for ecological risk models
- 11 Stochastic precipitation-runoff modeling for water yield from a semi-arid forested watershed
- 12 Regional assessment of the impact of climate change on the yield of water supply systems
- 13 Hydrological risk under nonstationary conditions changing hydroclimatological input
- 14 Fuzzy compromise approach to water resources systems planning under uncertainty
- 15 System and component uncertainties in water resources
- 16 Managing water quality under uncertainty: Application of a new stochastic branch and bound method
- 17 Uncertainty in risk analysis of water resources systems under climate change
- 18 Risk and reliability in water resources management: Theory and practice
- 19 Quantifying system sustainability using multiple risk criteria
- 20 Irreversibility and sustainability in water resources systems
- 21 Future of reservoirs and their management criteria
- 22 Performance criteria for multiunit reservoir operation and water allocation problems
- 23 Risk management for hydraulic systems under hydrological loads
10 - Controlling three levels of uncertainties for ecological risk models
Published online by Cambridge University Press: 18 January 2010
- Frontmatter
- Contents
- List of Contributors
- 1 Introduction
- 2 Integrated regional risk assessment and safety management: Challenge from Agenda 21
- 3 Risk analysis: The unbearable cleverness of bluffing
- 4 Aspects of uncertainty, reliability, and risk in flood forecasting systems incorporating weather radar
- 5 Probabilistic hydrometeorological forecasting
- 6 Flood risk management: Risk cartography for objective negotiations
- 7 Responses to the variability and increasing uncertainty of climate in Australia
- 8 Developing an indicator of a community's disaster risk awareness
- 9 Determination of capture zones of wells by Monte Carlo simulation
- 10 Controlling three levels of uncertainties for ecological risk models
- 11 Stochastic precipitation-runoff modeling for water yield from a semi-arid forested watershed
- 12 Regional assessment of the impact of climate change on the yield of water supply systems
- 13 Hydrological risk under nonstationary conditions changing hydroclimatological input
- 14 Fuzzy compromise approach to water resources systems planning under uncertainty
- 15 System and component uncertainties in water resources
- 16 Managing water quality under uncertainty: Application of a new stochastic branch and bound method
- 17 Uncertainty in risk analysis of water resources systems under climate change
- 18 Risk and reliability in water resources management: Theory and practice
- 19 Quantifying system sustainability using multiple risk criteria
- 20 Irreversibility and sustainability in water resources systems
- 21 Future of reservoirs and their management criteria
- 22 Performance criteria for multiunit reservoir operation and water allocation problems
- 23 Risk management for hydraulic systems under hydrological loads
Summary
ABSTRACT
Bayesian methods have been developed to analyze three main types of uncertainties, namely: the model uncertainty, the parameter uncertainty, and the sampling errors. To illustrate these techniques on a real case study, a model has been developed to quantify the various uncertainties when predicting the global proportion of coliform positive samples (CPS) in a water distribution system where bacterial pollution indicators are weekly monitored by sanitation authorities. The data used to fit and validate the model correspond to water samples gathered in the suburb of Paris. The model uncertainty has been evaluated in the reference class of generalized linear multivariate autoregressive models. The model parameter distributions are determined using the Metropolis-Hastings algorithm, one of the Monte Carlo Markov Chain methods. Such an approach, successful when dealing with water quality control, should also be very powerful for rare events modeling in hydrology or in other fields such as ecology.
INTRODUCTION
The bacterial pollution indicators are understood here as the coliforms, a group of bacteria that is “public enemy number one” for water suppliers. Their occurrence in domestic distributed waters is a major concern for many utility companies. The coliform group includes many different species, the most famous one being Escherichia coli. Part of the bacteria belonging to the coliforms group are fecal bacteria and may provoke gastroenteritis or other digestive problems. The other inoffensive part is generally considered as an indicator of a possible presence of their more dangerous cousins.
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- Publisher: Cambridge University PressPrint publication year: 2002