Probstat/week13 practice 1

This is part of probstat

Reviews

1. We toss a fair coin 100 times. Let random variable ${\displaystyle X}$ be the number of heads.

• Find the minimum value ${\displaystyle T}$ such that ${\displaystyle P\{|X-50|>T\}\leq 0.05}$. You may use computers to compute ${\displaystyle T}$ exactly.
• Find the minimum value ${\displaystyle T}$ such that ${\displaystyle P\{X>50+T\}\leq 0.05}$. You may use computers to compute ${\displaystyle T}$ exactly.
• Find the minimum value ${\displaystyle T}$ such that ${\displaystyle P\{|X-50|>T\}\leq 0.01}$. You may use computers to compute ${\displaystyle T}$ exactly.
• Find the minimum value ${\displaystyle T}$ such that ${\displaystyle P\{X>50+T\}\leq 0.01}$. You may use computers to compute ${\displaystyle T}$ exactly.

Hint: In this question, you can calculate the probability ${\displaystyle P\{X=i\}}$ for ${\displaystyle i=0,\ldots ,100}$ because ${\displaystyle X}$ is a binomial random variable.

2. What is the variance of ${\displaystyle X}$ from question 1?

3. Let's approximate ${\displaystyle X}$ from question 1 with the normal distribution.

• Find the minimum value ${\displaystyle T}$ such that ${\displaystyle P\{|X-50|>T\}\leq 0.05}$. Use the standard normal distribution table to answer this. Compare with the answer from question 1.
• Find the minimum value ${\displaystyle T}$ such that ${\displaystyle P\{X>50+T\}\leq 0.05}$. Use the standard normal distribution table to answer this. Compare with the answer from question 1.
• Find the minimum value ${\displaystyle T}$ such that ${\displaystyle P\{|X-50|>T\}\leq 0.01}$. Use the standard normal distribution table to answer this. Compare with the answer from question 1.
• Find the minimum value ${\displaystyle T}$ such that ${\displaystyle P\{X>50+T\}\leq 0.01}$. Use the standard normal distribution table to answer this. Compare with the answer from question 1.

Tests concerning the mean of a population: known ${\displaystyle \sigma }$

1. An ISP claims to provide an Internet connection with the speed of 10Mbps. You know that the speed is normally distributed with s.d. ${\displaystyle \sigma =1.5}$. You plan to obtain a sample of size 10 of the Internet connection speed, and compute the sample mean ${\displaystyle {\bar {X}}}$. Design 3 statistical tests with levels of significances ${\displaystyle \alpha }$ = 0.1, 0.05, and 0.01 to show if we should believe the claim from the ISP. Define explicitly what your null hypothesis ${\displaystyle H_{0}}$ is.

Hint: your tests should specify the conditions to reject ${\displaystyle H_{0}}$ and should depend on ${\displaystyle {\bar {X}}}$.

2. Consider the tests you design from question 1. What is the probability that the tests accept ${\displaystyle H_{0}}$ when the actual speed is 9.5Mbps?

Tests concerning the mean of a population: unknown ${\displaystyle \sigma }$

1. An ISP claims to provide an Internet connection with the speed of 10Mbps. You know that the speed is normally distributed but you do not know ${\displaystyle \sigma }$. You plan to obtain a sample of size 10 of the Internet connection speed, and compute the sample mean ${\displaystyle {\bar {X}}}$ and the sample standard deviation ${\displaystyle S}$. Design 3 statistical tests with levels of significances ${\displaystyle \alpha }$ = 0.1, 0.05, and 0.01 to show if we should believe the claim from the ISP. Define explicitly what your null hypothesis ${\displaystyle H_{0}}$ is.

Hint: your tests should specify the conditions to reject ${\displaystyle H_{0}}$ and should depend on ${\displaystyle {\bar {X}}}$ and ${\displaystyle S}$.

2. Consider the tests you design from question 1. What is the probability that the tests accept ${\displaystyle H_{0}}$ when the actual speed is 9.5Mbps?

Tests concerning the equality means of normal population: known ${\displaystyle \sigma }$

We have two populations: students who attend special track-and-field training and students who do not attend the training. Let's call the average time for a 100m-run of the first group of students ${\displaystyle \mu _{x}}$ and of the second group of students ${\displaystyle \mu _{y}}$. Suppose that we know that the run time are normally distributed with standard deviation ${\displaystyle \sigma =2}$ seconds.

Suppose that we randomly choose ${\displaystyle n}$ students from the first group and find the sample mean ${\displaystyle {\bar {X}}}$ of their times for 100m runs. Also, we randomly choose ${\displaystyle m}$ students from the second group and find the sample mean ${\displaystyle {\bar {Y}}}$ of times of 100m runs.

We would like to know if the training has any effects on student run times.

1. What is the distribution of ${\displaystyle {\bar {X}}}$?

2. What is the distribution of ${\displaystyle {\bar {Y}}}$?

3. What is the distribution of ${\displaystyle {\bar {X}}-{\bar {Y}}}$?

4. Describe statistical tests of significant levels ${\displaystyle \alpha }$ = 0.1, 0.05, and 0.01.