User:Tomkeelin

Another generalized log-logistic distribution is the log-transform of the metalog distribution, in which power series expansions in terms of ${\displaystyle p}$ are substituted for logistic-distribution parameters ${\displaystyle \mu }$ and ${\displaystyle \sigma }$. The resulting metalog quantile function is highly shape flexible, has a simple closed form, and can be fit to data with linear least squares. The log-logistic distribution is special case of the log-metalog distribution.

Feasibility condition for metalogs with ${\displaystyle k=3}$ terms: ${\displaystyle a_{1}}$ is any real number, ${\displaystyle a_{2}>0}$ and ${\displaystyle |a_{3}|/a_{2}\leq 1.66711}$.

Convex Hull for Feasible Coefficients of Four-Term Metalogs

Feasibility for metalogs with ${\displaystyle k=4}$ terms is defined as follows:

• ${\displaystyle a_{1}}$ is any real number, and
• ${\displaystyle a_{2}\geq 0}$, and
• If ${\displaystyle a_{2}=0}$, then ${\displaystyle a_{3}=0}$ and ${\displaystyle a_{4}>0}$ (uniform distribution exactly)
• If ${\displaystyle a_{2}>0}$, then feasibility conditions are specified numerically
  • For a given ${\displaystyle |a_{3}|/a_{2}}$, feasibility requires that ${\displaystyle a_{4}/a_{2}\geq }$ number shown.
  • For a given ${\displaystyle a_{4}/a_{2}}$, feasibility requires that ${\displaystyle |a_{3}|/a_{2}\leq }$ number shown.
  • At the top of this table, the four-term metalog is symmetric and peaked, similar to a student-t distribution with 3 degrees of freedom.
  • At the bottom of this table, the four-term metalog is a uniform distribution exactly.
  • In between, it has varying degrees of skewness depending on ${\displaystyle a_{3}}$. Positive ${\displaystyle a_{3}}$ yields right skew. Negative ${\displaystyle a_{3}}$ yields left skew. When ${\displaystyle a_{3}=0}$, the four-term metalog is symmetric.

The feasible area can be closely approximated by an ellipse (dashed, gray curve), defined by center ${\displaystyle b=4.5}$ and semi-axis lengths ${\displaystyle c=8.5}$ and ${\displaystyle d=1.95}$. Supplementing this with linear interpolation outside its applicable range, feasibility, given ${\displaystyle a_{2}>0}$, can be closely approximated:

${\displaystyle \ \approx \left\{{\begin{array}{rlcrll}{|a_{3}| \over a_{2}}&\leq {d \over c}{\sqrt {c^{2}-({a_{4} \over a_{2}}-b)^{2}}}&{\text{ for }}&-4.0&\leq {a_{4} \over a_{2}}\leq 4.5,\\{|a_{3}| \over a_{2}}&\leq 0.014({a_{4} \over a_{2}}-4.5)+1.95&{\mbox{ for }}&4.5&<{a_{4} \over a_{2}}\leq 7.0,\\{|a_{3}| \over a_{2}}&\leq 0.004({a_{4} \over a_{2}}-7.0)+1.984&{\mbox{ for}}&7.0&<{a_{4} \over a_{2}}\leq 10.0,\\{|a_{3}| \over a_{2}}&\leq 2.0&{\mbox{ for}}&10.0&<{a_{4} \over a_{2}}.\end{array}}\right.}$