Solution:

$\begin{aligned} \bar{X} &=53, \mu=56, N=16 . \\ S &=\sqrt{\frac{\Sigma(X-X)^{2}}{N-1}}=\sqrt{\frac{150}{15}}=\sqrt{10}=3.162 . \\ t &=\frac{\bar{X}-\mu}{S} \sqrt{N} \\ &=\frac{53-56}{3. 162} \sqrt{16}=\frac{3 \times 4}{3 .162}=\frac{12}{3.162}=3 . 8 . \end{aligned}$

The value of t for 16-1=15 degrees of freedom at 5% level of significance is 2.13 . $3. 8>2 . 13$ , hence the result of experiment does not support the hypothesis that the sample is taken from the universe having mean of 56 .

 95% confidence limits for the population mean

$\begin{aligned} \bar{X} \pm \frac{S}{\sqrt{N}} t .05 &=53 \pm \frac{3.162}{\sqrt{16}} \times 2.131 \\ &=53 \pm \frac{3.162 \times 2.131}{4} \\ &=53 \pm 1.685 \\ &=54.685 \text { to } 51.315 \end{aligned}$

 99% confidence limits of the population mean :

$\begin{aligned} \bar{X} \pm \frac{S}{\sqrt{N}} t .01 &=53 \pm \frac{3.162}{\sqrt{16}} \times 2.947 \\ &=53 \pm \frac{3.162 \times 2.947}{4}=53 \pm 2.329 \\ &=50.671 \text { to } 55.329 \end{aligned}$