The brain weights of Swedish men follow a normal distribution with a mean of $1.40$ and a standard deviation of $0.11$

Formula used: Standard Deviation$={\sigma }_{\overline{x}}=\frac{\sigma }{\sqrt{n}}$

Let $x$ represent Swedish men's brain weights. Then, as follows, $x$ follows the Normal distribution: $x~N(1.40,0.11)$

With a mean of $\mu$ and a standard deviation of $\sigma$the population distance is normally distributed. The sample mean sampling distribution for sample size $3$. The sampling distribution $\overline{x}$ will be normal, with a mean of ${\mu }_{\overline{x}}=\mu$ and a standard deviation of ${\sigma }_{\overline{x}}=\frac{\sigma }{\sqrt{n}}$, where $n$ is the sample size.

 is then determined as follows:

Here the sample size $n=3$

Mean of $\overline{x}$ is ${\mu }_{\overline{x}}=\mu =1.40$

Standard deviation of $\overline{x}$ is,

${\sigma }_{\overline{x}}=\frac{\sigma }{\sqrt{n}}$

$$\begin{gathered} =\frac{0.11}{\sqrt{3}} \\ =0.0635 \end{gathered}$$

As a result, the sampling distribution becomes $\overline{x}~N(1.40,0.0635)$

As a result, the brain weights in the sample exhibit a normal distribution, with a mean of $1.40 \mathrm{kg}$ and a standard deviation of $0.064 \mathrm{kg}$

With a mean of $\mu$ and a standard deviation of $\sigma$, the population distance is normally distributed. The sample mean sampling distribution for sample size $12$ is then determined as follows:

The sampling distribution $\overline{x}$ will be normal as well, with a mean of ${\mu }_{\lambda }=\mu$ and a standard deviation of ${\sigma }_{\overline{x}}=\frac{\sigma }{\sqrt{n}}$, where $n$ is the sample size.

Here the sample size $n=12$

Mean of $\overline{x}$ is, ${\mu }_{\dot{x}}=\mu =1.40$

Standard deviation of $\overline{x}$ is,

${\sigma }_{\overline{x}}=\frac{\sigma }{\sqrt{n}}$

$$\begin{gathered} =\frac{0.11}{\sqrt{12}} \\ =0.0317 \end{gathered}$$

As a result, the sampling distribution can be calculated as $\overline{x}~N(1.40,0.0317)$

As a result, the mean brain weights in the sample have a normal distribution, with a mean of $1.40 \mathrm{kg}$ and a standard deviation of $0.032 \mathrm{kg}$

Using Minitab, create the graphs as follows:

• Open Minitab, go to Graph, and select Probability distribution plot from the drop-down menu.
• To continue, select View Single Plot and click Ok.
• Select the Normal distribution and fill in the Mean and Standard Deviations.
• To create the graph, click Ok. 

Let $\mu$ be the average Swedish man's brain weight. The sample size is $n=3$ based on the information provided. The sample mean brain weights of Swedish males are thus designated by $\overline{x}$, and they are roughly distributed with ${\mu }_{\overline{x}}=\mu$ and ${\sigma }_{\overline{x}}=\frac{\sigma }{\sqrt{n}}=\frac{0.1}{\sqrt{3}}=0.064$

The percentage of all three Swedish males whose mean brain weights are within $0.1 \mathrm{kg}$ of the population mean brain weight of $1.40 \mathrm{kg}$ is then about equivalent to the normal curve with parameters $1.40 and 0.064$ and sits between $\mu -0.1$ and $\mu +0.1$ The associated $z-$scores are then,

$$\begin{gathered} z= \frac{(\mu -0.1)-\mu }{0.064} z= \frac{(\mu +0.1)-\mu }{0.064} \\ z= \frac{0.1}{0.064} z= \frac{0.1}{0.064} \\ z= -1.56 z=1.56 \end{gathered}$$

The area under the standard normal curve between $-1.56$ and $1.56$ is, according to Table II.

$\Phi (1.56)-\Phi (-1.56)=0.9406-0.0594 =0.8812$

As a result, the mean brain weights of the three Swedish guys were within $0.1 \mathrm{kg}$ of the population mean brain weight of $1.40 \mathrm{kg}$ in $88.12\%$ of the samples.

Let $\mu$ be the average Swedish man's brain weight. The sample size is $n=12$ based on the information provided. The sample mean brain weights of Swedish males are thus designated by $\overline{x}$, and they are roughly distributed with ${\mu }_{\overline{x}}=\mu$ and ${\sigma }_{\overline{x}}=\frac{\sigma }{\sqrt{n}}=\frac{0.1}{\sqrt{12}}=0.032$

The fraction of $12$ Swedish guys with mean brain weights within $0.1 \mathrm{kg}$ of the population average of $1.40 \mathrm{kg}$ is then about equivalent to the normal curve with parameters $1.40$ and $0.032$ and sits between $\mu -0.1$ and $\mu +0.1$ The associated $z-$scores are then,

$$\begin{gathered} z=\frac{\left(\mu -0.1\right)-\mu }{0.032} z=\frac{\left(\mu +0.1\right)-\mu }{0.032} \\ z=\frac{-0.1}{0.032} z=\frac{0.1}{0.032} \\ =-3.13 =3.13 \end{gathered}$$

The area under the standard normal curve between $-1.56$ and $1.56$ is, according to Table II.

$$\begin{gathered} \Phi (3.13)-\Phi (-3.13)=0.9991-0.0009 \\ =0.9982 \end{gathered}$$

As a result, the mean brain weights of the three Swedish guys are within $0.1 \mathrm{kg}$ of the population mean brain weight of $1.40 \mathrm{kg}$ in $99.82\%$ of the samples.