On the geometric and analytic properties of some random fractals

Charmoy, Philippe H. A.

January 2014

The heat content of a domain D of &Ropf;^d is defined as</sp> < p >E(s) = &int;_D u(s,x)dx, where u is the solution to the heat equation with zero initial condition and unit Dirichlet boundary condition. This thesis studies the behaviour of E(s) for small s with a particular emphasis on the case where $D$ is a planar domain whose boundary is a random Koch curve. When &part;D is spatially homogeneous, we show that we can recover the upper and lower Minkowski dimensions of &part;D from E(s). Furthermore, in some cases where the Minkowski dimension does exist, finer fluctuations can be recovered and the heat content is controlled by s^&alpha; exp{f (log(1/s)} for small s, for some positive &alpha; and some regularly varying function f. When &part;D is statistically self-similar, the heat content asymptotics are studied using a law of large numbers for the general branching process, and we show that the Minkowski dimension and content of &part;D exist and can be recovered from E(s). More precisely the heat content has an almost sure expansion E(s) = c₁ s^&alpha; N_&infin; + o(s^&alpha;), a.s. for small s, for some positive c₁ and &alpha; and a positive random variable N_&infin; with unit expectation. To study the fluctuations around these asymptotics, we prove a central limit theorem for the general branching process. The proof follows a standard Taylor expansion argument and relies on the independence built into the general branching process. The limiting distribution established here is reminiscent of those arising in central limit theorems for martingales. When &part;D is a statistically self-similar Cantor subset of &Ropf;, we discuss examples where we have and fail to have a central limit theorem for the heat content. We conclude with an open question about the fluctuations of the heat content when &part;D is a statistically self-similar Koch curve.

514

Separation of Points and Interval Estimation in Mixed Dose-Response Curves with Selective Component Labeling

Flake, Darl D., II

01 May 2016

This dissertation develops, applies, and investigates new methods to improve the analysis of logistic regression mixture models. An interesting dose-response experiment was previously carried out on a mixed population, in which the class membership of only a subset of subjects (survivors) were subsequently labeled. In early analyses of the dataset, challenges with separation of points and asymmetric confidence intervals were encountered. This dissertation extends the previous analyses by characterizing the model in terms of a mixture of penalized (Firth) logistic regressions and developing methods for constructing profile likelihood-based confidence and inverse intervals, and confidence bands in the context of such a model. The proposed methods are applied to the motivating dataset and another related dataset, resulting in improved inference on model parameters. Additionally, a simulation experiment is carried out to further illustrate the benefits of the proposed methods and to begin to explore better designs for future studies. The penalized model is shown to be less biased than the traditional model and profile likelihood-based intervals are shown to have better coverage probability than Wald-type intervals. Some limitations, extensions, and alternatives to the proposed methods are discussed.

logistic regression

mixture models

bias

coverage probability

Statistics and Probability

Distribution of a Sum of Random Variables when the Sample Size is a Poisson Distribution

Pfister, Mark

01 August 2018

A probability distribution is a statistical function that describes the probability of possible outcomes in an experiment or occurrence. There are many different probability distributions that give the probability of an event happening, given some sample size n. An important question in statistics is to determine the distribution of the sum of independent random variables when the sample size n is fixed. For example, it is known that the sum of n independent Bernoulli random variables with success probability p is a Binomial distribution with parameters n and p: However, this is not true when the sample size is not fixed but a random variable. The goal of this thesis is to determine the distribution of the sum of independent random variables when the sample size is randomly distributed as a Poisson distribution. We will also discuss the mean and the variance of this unconditional distribution.

Hierarchical Models

Mixture

Poisson

Probability Mass Function

Probability

Statistical Models

Non-congruence of statistical distributions: how different is different?

Applegate, Terry Lee.

January 1978

Call number: LD2668 .T4 1978 A65 / Master of Science

Distribution (Probability theory)

Masters theses

Maintenance of partial-sum-based histograms

Kan, Kin-fai., 簡健輝.

January 2002

published_or_final_version / abstract / toc / Computer Science and Information Systems / Master / Master of Philosophy

Distribution (Probability theory)

Database management.

Invariant limiting shape distributions for some sequential rectangularmodels

陳冠全, Chen, Koon-chuen.

January 1998

published_or_final_version / Statistics and Actuarial Science / Doctoral / Doctor of Philosophy

Distribution (Probability theory)

Stochastic processes.

Exact and asymptotic solutions of a stochastic replacement problem with an embedded renewal process

Jack, N.

January 1988

No description available.

510

Probability theory][Operations research

Optimal foraging behaviour when faced with an energy-predation trade-off

Welton, Nicola Jane

January 1998

No description available.

519.5

Applied probability; Behavioural ecology

Random polynomials

Hannigan, Patrick

January 1998

No description available.

510

Stochastic processes; Probability theory

On reasoning with uncertainty and belief change

Shi, Shengli

January 1995

No description available.

005

Fuzzy logic; Probability theory