Find the critical region for this test.

It is now known that in the area in which the plant was found \(90\% \) of all the plants are of species \(A\) and \(10\% \) are of species \(B\).

Find the probability that \(\bar X\) will fall within the critical region of the test.

If, having done the test, the sample mean is found to lie within the critical region, find the probability that the leaves came from a plant of species \(A\).

\(\bar X \sim N\left( {5.2,{\text{ }}\frac{{{{1.2}^2}}}{{16}}} \right)\)     (M1)

critical value is \(5.2 - 1.64485 \ldots  \times \frac{{1.2}}{4} = 4.70654 \ldots \)     (A1)

critical region is \(] - \infty ,{\text{ }}4.71]\)     A1

Note:     Allow follow through for the final A1 from their critical value.

Note:     Follow through previous values in (b), (c) and (d).

[3 marks]

\(0.9 \times 0.05 + 0.1 \times (1 - 0.361 \ldots ) = 0.108875997 \ldots  = 0.109\)     M1A1

Note:     Award M1 for a weighted average of probabilities with weights \(0.1,0.9\).

[2 marks]

attempt to use conditional probability formula     M1

\(\frac{{0.9 \times 0.05}}{{0.108875997 \ldots }}\)     (A1)

\( = 0.41334 \ldots  = 0.413\)     A1

[3 marks]

Total [10 marks]

Solutions to this question were generally disappointing.

In (a), the standard error of the mean was often taken to be \(\sigma (1.2)\) instead of \(\frac{\sigma }{{\sqrt n }}(0.3)\) and the solution sometimes ended with the critical value without the critical region being given.

In (c), the question was often misunderstood with candidates finding the weighted mean of the two means, ie \(0.9 \times 5.2 + 0.1 \times 4.6 = 5.14\) instead of the weighted mean of two probabilities.

Without having the solution to (c), part (d) was inaccessible to most of the candidates so that very few correct solutions were seen.