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这是悉尼大学统计推断课程的代写成功案例。
STAT3023 课程简介
In today’s data-rich world more and more people from diverse fields are needing to perform statistical analyses and indeed more and more tools for doing so are becoming available; it is relatively easy to point and click and obtain some statistical analysis of your data. But how do you know if any particular analysis is indeed appropriate? Is there another procedure or workflow which would be more suitable? Is there such a thing as the best possible approach in a given situation? All of these questions (and more) are addressed in this unit. You will study the foundational core of modern statistical inference, including classical and cutting-edge theory and methods of mathematical statistics with a particular focus on various notions of optimality. The first part of the unit covers various aspects of distribution theory which are necessary for the second part which deals with optimal procedures in estimation and testing. The framework of statistical decision theory is used to unify many of the concepts. You will apply the methods learnt to real-world problems in laboratory sessions. By completing this unit you will develop the necessary skills to confidently choose the best statistical analysis to use in many situations.
Prerequisites
At the completion of this unit, you should be able to:
- LO1. deduce the (limiting) distribution of sums of random variables using moment-generating functions
- LO2. derive the distribution of a transformation of two (or more) continuous random variables
- LO3. derive marginal and conditional distributions associated with certain multivariate distributions
- LO4. classify many common distributions as belonging to an exponential family
- LO5. derive and implement maximum likelihood methods in various estimation and testing problems
- LO6. formulate and solve various inferential problems in a decision theory framework
- LO7. derive and apply optimal procedures in various problems, including Bayes rules, minimax rules, minimum variance unbiased estimators and most powerful tests.
STAT3023 Statistical Inference HELP(EXAM HELP, ONLINE TUTOR)
Let $X_n$ have a $\chi_n^2$ distribution.
(a) Find an approximating normal distribution for $X_n$.
(b) Find an approximating normal distribution for $Y_n=\sqrt{X_n}$.
(c) Find an approximating normal distribution for $Z_n=\log X_n$.
(d) How good are the approximations in parts (a), (b), and (c) for $n=$ $5,10,20,100 ?$
(a) A $\chi_n^2$ random variable $X_n$ has the same distribution as $\sum_{i=1}^n U_i$ with the $U_i$ i.i.d. $\chi_1^2$ random variables. So the central limit theorem states that
$$
X_n \sim A N(n, 2 n)
$$
$$
\text { as } n \rightarrow \infty \text {. }
$$
(b) Let $V_n=\sqrt{X_n / n}=f\left(X_n / n\right)$. Now $X_n / n \stackrel{P}{\rightarrow} 1, X_n / n \sim A N(1,2 / n)$, $f(1)=1$, and $f^{\prime}(1)=1 / 2$. So
$$
V_n \sim A N\left(1, \frac{1}{4} 2 / n\right)=A N\left(1, \frac{1}{2 n}\right)
$$
and thus
$$
Y_n=\sqrt{n} V_n \sim A N(\sqrt{n}, 1 / 2)
$$
(c) Let $W_n=\log \left(X_n / n\right)=f\left(X_n / n\right)$. Now $X_n / n \stackrel{P}{\rightarrow} 1, X_n / n \sim A N(1,2 / n)$, $f(1)=0$, and $f^{\prime}(1)=1$. So
$$
W_n \sim A N(0,2 / n)
$$
and thus
$$
Z_n=V_n+\log n \sim A N(\log n, 2 / n)
$$
(d) The exact CDFs and PDFs of $Y_n$ and $Z_n$ are
$$
\begin{array}{ll}
F_{Y_n}(y)=F_{X_n}\left(y^2\right) & f_{Y_n}(y)=f_{X_n}\left(y^2\right) 2 y \
F_{Z_n}(z)=F_{X_n}\left(e^z\right) & f_{Z_n}(z)=f_{X_n}\left(e^z\right) e^z
\end{array}
$$
You can look at graphs of the densities or CDFs, or at quantile plots, or at numerical measures of the discrepancies of the exact and approximate CDFs.
The height $H$ and radius $R$ of a cylinder are measured with error; the measurements are independent, normally distributed, and
$$
\mu_H=75 \mathrm{~cm} \quad \sigma_H=2 \mathrm{~cm} \quad \mu_R=10 \mathrm{~cm} \quad \sigma_R=1 \mathrm{~cm} .
$$
The estimated volume of the cylinder is $V=\pi R^2 H$. Find a normal approximation to the distribution of $V$.
$V=f(R, H)$ with $f(r, h)=\pi r^2 h$. The gradient of $f$ is
$$
\nabla f(r, h)=\left(2 \pi r h, \pi r^2\right) .
$$
So
$$
\begin{aligned}
V & \approx f(10,75)+\frac{\partial}{\partial r} f(10,75)(R-10)+\frac{\partial}{\partial h} f(10,75)(H-75) \
& =\pi \times 7500+\pi \times 1500 \times(R-10)+\pi \times 100 \times(H-75) \
& \sim \mathrm{N}\left(\pi \times 7500,(\pi \times 1500 \times 1)^2+(\pi \times 100 \times 2)^2\right) \
& \approx \mathrm{N}\left(23561.94,(4754.09)^2\right)
\end{aligned}
$$
Let $X_1, \ldots, X_n$ be a random sample from an exponential distribution with mean $\theta$.
(a) Find a normal approximation to the distribution of the sample mean $\bar{X}_n$.
(b) Let $Y_n=g\left(\bar{X}_n\right)$ where $g$ is differentiable. Find a normal approximation to the distribution of $Y_n$.
(c) Can you find a function $g$ such that the variance of the normal approximation in (b) does not depend on $\theta$ ?
(a) The variance of the exponential distribution with mean $\theta$ is $\theta^2$. So by the $\operatorname{CLT} \bar{X}_n \sim \mathrm{N}\left(\theta, \theta^2 / n\right)$.
(b) By the delta method $Y_n=g\left(\bar{X}_n\right) \sim \mathrm{N}\left(g(\theta),\left(g^{\prime}(\theta)\right)^2 \theta^2 / n\right)$.
(c) The approximate variance is constant in $\theta$ if $g^{\prime}(\theta)=1 / \theta$, or $g(\theta)=\log \theta$. This is an example of a variance stabilizing transformation.
Let $X_1, \ldots, X_n$ he a random sample from a Poisson distribution with mean $\lambda>0$. Let $\bar{X}_n$ be the sample average and let $U_n=\sqrt{n}\left(\bar{X}_n-\lambda\right) / \sqrt{\bar{X}_n}$. Find the limiting distribution of $U_n$ as $n$ tends to infinity.
By the weak law of large numbers $\bar{X}_n$ converges in probability to $E\left[X_1\right]=\lambda$. By the continuous mapping theorem $T_n=\sqrt{\bar{X}_m}$ converges in probability to $\sqrt{\lambda}$. Using the strong law of large numbers and basic continuity shows that convergence also holds almost surely.
Since $\operatorname{Var}\left(X_1\right)=\lambda$ the central limit theorem implies that $\bar{X}_n \sim \operatorname{AN}(\lambda, \lambda / n)$. Since the square root function $f(x)=\sqrt{x}$ is differentiable at positive $x$ the delta method implies that
$$
T_n \sim \mathrm{AN}\left(f(\lambda),\left(f^{\prime}(\lambda)^2 \lambda / n\right)=\mathrm{AN}\left(\sqrt{\lambda},\left(\frac{1}{2 \sqrt{\lambda}}\right)^2 \lambda / n\right)=\mathrm{AN}\left(\sqrt{\lambda}, \frac{1}{4 n}\right) .\right.
$$
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