Respuesta :
Answer:
a1) [tex]\mu_{\bar{X}} = 70[/tex]
a2)[tex]\sigma_{\bar{X}} = 0.4[/tex]
b1) [tex]\mu_{\bar{X}} = 70[/tex]
b2) [tex]\sigma_{\bar{X}} = 0.2[/tex]
c) X is more likely to be within 1 GPa of 70 GPa in the random sample of part b because of the largeness in sample size and less scattering of data
Step-by-step explanation:
Mean value, [tex]\mu = 70[/tex]
Standard deviation, [tex]\sigma = 1.6[/tex]
a1) sample size, n = 16
Mean of the sampling distribution of the sample mean = mean value, i.e.
[tex]\mu_{\bar{X}} = \mu\\\mu_{\bar{X}} = 70[/tex]
a2) The standard deviation of the sampling distribution of the sample mean
[tex]\sigma_{\bar{X}} = \frac{\sigma}{\sqrt{n} } \\\sigma_{\bar{X}} = \frac{1.6}{\sqrt{16} }\\\sigma_{\bar{X}} = 0.4[/tex]
b1) For sample size, n = 64
Mean of the sampling distribution of the sample mean = mean value, i.e.
[tex]\mu_{\bar{X}} = \mu\\\mu_{\bar{X}} = 70[/tex]
a2) The standard deviation of the sampling distribution of the sample mean
[tex]\sigma_{\bar{X}} = \frac{\sigma}{\sqrt{n} } \\\sigma_{\bar{X}} = \frac{1.6}{\sqrt{64} }\\\sigma_{\bar{X}} = 0.2[/tex]
c) X is more likely to be within 1 GPa of 70 GPa in the random sample of part b because it has a larger sample size, hence a decrease in the variability. This makes us easily determine the position of the sample around the population mean
