Table 4.

Simulation results when Y has an asymmetric distribution

		Model A $\widehat{Y}=\widehat{\alpha }+\widehat{\beta }·X$	Model B $\widehat{Y}=\widehat{\alpha }+\widehat{\beta }·{log}_b\left(X\right)$	Model C $\widehat{{log}_a\left(Y\right)}=\widehat{\alpha }+\widehat{\beta }·X$	Model D $\widehat{{log}_a\left(Y\right)}=\widehat{\alpha }+\widehat{\beta }·{log}_b\left(X\right)$
Beta-hat coefficient and standard error from regression model		$\widehat{\beta }$ = 0.625 se($\widehat{\beta }$) = 0.254	$\widehat{\beta }$ = 5.834 se($\widehat{\beta }$) = 2.441	$\widehat{\beta }$ = 0.011 se($\widehat{\beta }$) = 0.005	$\widehat{\beta }$ = 0.103 se($\widehat{\beta }$) = 0.044
Absolute change in Y for an absolute change of c units in X	Effect size	0.625	0.557	0.551	0.493
	95% CI	(0.128–1.122)	(0.101–1.013)	(0.100–1.006)	(0.080–0.909)
Absolute change in Y for a relative change of k times in X	Effect size	0.625	0.557	0.551	0.493
	95% CI	(0.128–1.122)	(0.101–1.013)	(0.100–1.006)	(0.080–0.909)
Relative change in Y for an absolute change of c units in X	Effect size	1.0125	1.0111	1.0110	1.0099
	95% CI	(1.0026–1.0224)	(1.0020–1.0203)	(1.0020–1.0201)	(1.0016–1.0182)
Relative change in Y for a relative change of k times in X	Effect size	1.0125	1.0111	1.0110	1.0099
	95% CI	(1.0026–1.0224)	(1.0020–1.0203)	(1.0020–1.0201)	(1.0016–1.0182)

Note: c = 1 and k = 1.1