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ISMT253a Tutorial 1 By Kris PAN 2008-02-11. Skewness:  a measure of the asymmetry of the probability distribution of a real-valued random variable 

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Presentation on theme: "ISMT253a Tutorial 1 By Kris PAN 2008-02-11. Skewness:  a measure of the asymmetry of the probability distribution of a real-valued random variable "— Presentation transcript:

1 ISMT253a Tutorial 1 By Kris PAN 2008-02-11

2 Skewness:  a measure of the asymmetry of the probability distribution of a real-valued random variable  1)positive skew: The right tail is longer; the mass of the distribution is concentrated on the left of the figure. The distribution is said to be right-skewed.  2)negative skew: The left tail is longer; the mass of the distribution is concentrated on the right of the figure. The distribution is said to be left-skewed.

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4 Kurtosis:  a measure of the "peakedness" of the probability distribution of a real-valued random variable. It is sometimes referred to as the "volatility of volatility."  A high kurtosis portrays a chart with fat tails and a low, even distribution, whereas a low kurtosis portrays a chart with skinny tails and a distribution concentrated toward the mean.

5  distribution with kurtosis of infinity (red); 2 (blue); and 0 (black)

6 2.8 Estimating the Difference Between Two Population Means Here we have two samples and two sets of statistics: Sample 1: Sample 2: and want to use them to estimate the difference between the two population means, µ 1 and µ 2

7 Estimate and Standard Error  A good estimate of the difference in means, ( µ 1 - µ 2 ) is the difference in sample means,.  If we know the standard deviations, the standard error of is:

8 Interval Estimate  If we are sampling from two normal populations, an interval estimate is:  We can also use this as a good approximate interval if both sample sizes are large (n 1  30 and n 2  30).

9 Unknown  1 and  2  We can use this formula only if the population standard deviations are known.  If they are not, we can use the sample standard deviations and get:

10 The Approximate Interval  As before, use of the sample standard deviations means we use a t distribution for the multiplier.  In this case, the results are only approximate and the t distribution has  degrees of freedom (see the text for how  is computed.)

11 The Pooled Variance Estimate  In some cases, it may be reasonable to assume that  1 and  2 are approximately equal, in which case we need only estimate their common value.  For this purpose, we "pool" the two sample variances and get S p 2 which is a weighted average of the two sample variances.

12 The Exact (pooled sample) Interval If this is the situation, we can compute an exact interval: Note that the pooling allows us to combine degrees of freedom: df = (n 1 -1)+(n 2 -1) = n 1 + n 2 -2

13 What Should We Use?  If we know the two population variances are about equal, use the exact procedure.  If we think they differ a lot, we should use the approximate result.  If we do not really know, the approximate approach is probably best.

14 Example 2.10  For the 83 mutual funds we discussed earlier, we want to compare the five-year returns for load funds versus no-load funds.  The Minitab output for both procedures is on the next slide. The exact procedure output is on the lower half.

15 Minitab Two-Sample Output Two-sample T for 5yr ret LoadNoLo N Mean StDev SE Mean 0 32 5.95 5.88 1.0 1 51 5.01 4.80 0.67 Difference = mu (0) - mu (1) Estimate for difference: 0.94 95% CI for difference: (-1.54, 3.42) T-Test of difference = 0 (vs not =): T-Value = 0.76 P-Value = 0.450 DF=56 Two-sample T for 5yr ret LoadNoLo N Mean StDev SE Mean 0 32 5.95 5.88 1.0 1 51 5.01 4.80 0.67 Difference = mu (0) - mu (1) Estimate for difference: 0.94 95% CI for difference: (-1.41, 3.29) T-Test of difference = 0 (vs not =): T-Value = 0.80 P-Value = 0.428 DF=81 Both use Pooled StDev = 5.24 Exact (uses pooled SD) Approximate

16 Interpretation  Since we do not have information that the population variances are equal, it is best to use the approximate procedure.  The degrees of freedom are  =56 and the interval estimate of ( µ NoLoad - µ Load ) is -1.538 to 3.423.  Because this interval contains zero, we can conclude the return rates are not that different.

17 2.9 Hypothesis Tests About the Difference Between Two Population Means Our test is of the form: H 0 : µ 1 = µ 2 (No difference) H a : µ 1  µ 2 (One is higher) which has an equivalent form: H 0 : µ 1 - µ 2 = 0(Difference is zero) H a : µ 1 - µ 2  0 (Difference not zero)

18 Test Statistic  For the hypothesis of zero difference, the test statistic is just:  The standard error (SE) is either: or

19 Choice of Procedure  As before, we use the approximate procedure with  degrees of freedom if we cannot assume  1 and  2 are equal to some common value.  If that is a reasonable assumption, we compute the pooled standard error and use the exact procedure with (n 1 +n 2 -2) degrees of freedom.

20 Example To test the hypothesis that load and no load funds have the same return, we write: H 0 : µ N - µ L = 0 H a : µ N - µ L  0 We do not know that the variances are equal, so we use the approximate procedure which has  = 56 degrees of freedom.

21 Results At a 5% level of significance, Reject H 0 if t > t.025,56  1.96 ** or t < -1.96 Minitab gives us t = 0.76 so we accept H 0 and will conclude there is no difference in average return. ** The correct value for a t 56 is 2.003.

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