Understanding Uncertainty Quantification: A Comprehensive Overview

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Uncertainty Quantification (UQ) is crucial in determining likely outcomes in scenarios with unknown factors. Explore the concept through the Algae Example, where parameters like growth rates pose challenges due to uncertainty. Statistical techniques like MCMC and the DRAM algorithm play key roles in quantifying and addressing uncertainties effectively.


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  1. An Introduction To Uncertainty Quantification By Addison Euhus, Guidance by Edward Phillips

  2. Book and References Book Uncertainty Quantification: Theory, Implementation, and Applications, by Smith Example Source/Data from http://helios.fmi.fi/~lainema/mc mc/

  3. What is Uncertainty Quantification? UQ is a way of determining likely outcomes when specific factors are unknown Parameter, Structural, Experimental Uncertainty Algae Example: Even if we knew the exact concentration of microorganisms in a pond and water/temperature, there are small details (e.g. rock positioning, irregular shape) that cause uncertainty

  4. The Algae Example Consider the pond with phytoplankton (algae) A, zooplankton Z, and nutrient phosphorous P

  5. The Algae Example This can be modeled by a simple predator prey model

  6. Observations and Parameters Concentrations of A, Z, and P can be measured as well as the outflow Q, temperature T, and inflow of phosphorous Pin However, the rest of the values cannot be measured as easily growth rate mu, rho s, alpha, k, and theta. Because of uncertainty, these will be hard to determine using standard methods

  7. Observed Algae Data

  8. Statistical Approach: MCMC Markov Chain Monte Carlo (MCMC) Technique Specify parameter values that explore the geometry of the distribution Constructs Markov Chains whose stationary distribution is the posterior density Evaluate realizations of the chain, which samples the posterior and obtains a density for parameters based on observed values

  9. DRAM Algorithm Delayed Rejection Adaptive Metropolis (DRAM) Based upon multiple iterations and variance/covariance calculations Updates the parameter value if it satisfies specific probabilistic conditions, and continues to iterate on the initial chain Monte Carlo on the Markov Chains

  10. Running the Algorithm Using MATLAB code, the Monte Carlo method runs on the constructed Markov Chains (the covariance matrix V) After a certain amount of iterations, the chain plots will show whether or not the chain has converged to values for the parameters After enough iterations have been run, the chain can be observed and the parameter calculations can be used to predict behavior in the model

  11. Small Iterations

  12. Large Iterations

  13. Results from the Algae Model

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