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I've come across two different forms of a skewness-adjusted t-statistic, which was developed originally by Johnson (1978): $$ J = t + \frac{gt^2}{3n} + \frac{g}{6n} $$

and $$ J = t + \frac{gt^2}{3\sqrt{n}} + \frac{g}{6\sqrt{n}}, $$

where $t$ is the conventional t-statistic, $n$ is the number of observations, and $g$ is the skewness estimate. The null hypothesis is zero mean.

Could you advise me what's difference between the two forms?

Many thanks, Dave

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    Hey Dave, and welcome to the site. I have fixed the formatting of your question, and just want to let you know that equation can be typed within \$ \$ or \$\$ \$\$ to enable TeX.2012-10-30
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    wow, excellent functionality! thanks Stefan.2012-10-30
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    Can you point to the sources where you found this, particularly the definition of $g$? I found Johnson's original paper, but his form doesn't match either of those given, as far as I can tell.2012-10-30
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    Hi Jonathan, $g$ is defined as follows: $$g = \frac{\sum_{i=1}^n (x_i-\overline{x})^3}{n\sigma(x)^3}$$ As far as I can understand Johnson's statistic given in his equation (2.5) is equivalent to the second form I have written. So $g$ corresponds to $\mu_3$ in his equation, and $\mu=0$.2012-10-30
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    The issue I'm having is that when $\overline{x}$ is very negative, and the data is highly skewed ($g$), the second form yields an adjusted t-statistic that is positive, while the conventional t-statistic is negative. This doesn't happen with the first form (the adjustment is smaller).2012-10-30
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    Sorry, $g$ in my notation is equal to $\hat{\mu}_3/s^3$ in Johnson's notation.2012-10-30

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