rofessor Cornish studied rainfall cycles and sunspot cycles. (Reference: Australian Journal of Physics, Vol. 7, pp. 334-346.) Part of the data include amount of rain (in mm) for 6-day intervals. The following data give rain amounts for consecutive 6-day intervals at Adelaide, South Australia.

7	28	7	1	69	3	1	4	22	7	16	4	54	160
60	73	27	3	3	1	7	144	107	4	91	44	1	8
4	22	4	59	116	52	4	155	42	24	11	43	3	24
19	74	26	63	110	39	34	71	52	39	8	0	15	2
14	9	1	2	4	9	6	10

(i) Find the median. (Use 1 decimal place.)

(ii) Convert this sequence of numbers to a sequence of symbols A and B, where A indicates a value above the median and B a value below the median. Test the sequence for randomness about the median at the 5% level of significance.

(b) Find the number of runs R, n₁, and n₂. Let n₁ = number of values above the median and n₂ = number of values below the median.

R
n1
n2

(c) In the case, n₁ > 20, we cannot use Table 10 of Appendix II to find the critical values. Whenever either n₁ or n₂ exceeds 20, the number of runs R has a distribution that is approximately normal, as follows.

 

We convert the number of runs R to a z value, and then use the normal distribution to find the critical values. Convert the sample test statistic R to z using the following formula. (Use 2 decimal places.)

z =

R – μR σR

(d) The critical values of a normal distribution for a two-tailed test with level of significance α = 0.05 are -1.96 and 1.96 (see Table 5(c) of Appendix II). Reject H₀ if the sample test statistic z ≤ -1.96 or if the sample test statistic z ≥ 1.96. Otherwise, do not reject H₀.

Sample z ≤ -1.96	-1.96 < sample z < 1.96	Sample z ≥ 1.96
Reject H0	Fail to reject H0	Reject H0