function [ p, Fstat, df1, df2 ] = ftest(n,np1,np2,chi1,chi2)
% [ p, Fstat ] = ftest(n,np1,np2,chi1,chi2)
% Inputs
% n = # of data
% np1, np2 = number of free parameters for each fit.
% chi1 & chi2 = sum of squares of misfits for two models.
% must be positive values
% normalization of chis by n not required
% (normalization divides out in Fstatistic)
%
% Outputs
% p = probability (between 0 - 1) that improvement to fit from
% addition of parameters is due to chance. I.e.,
% 0 means certainty that extra parameters are warranted
% 1 means improvement undoubtedly attributible to chance
% If desired, will also return F-statistic (Fstat) and
% degrees of freedom (df1, df2) for f-distribution
%
% Written by James Conder, Southern Illinois Universty, Oct. 2010
% Citation:
% Anderson, K.B. & Conder, J.A., Discussion of Multicyclic Hubbert
% Modeling as a Method for Forecasting Future Petroleum Production,
% Energy & Fuels, dx.doi.org/10.1021/ef1012648, 2011
%
% Updated June, 2011
% Check added for when df1=1 (giving -Inf). Use MatrixLabs approximation
% for f when df1=1. Acuracy ok, but noticeable small differences against
% fcdf
%
% Updated May 31, 2012
% Allow Fstat, df1, & df2 as outputs.
% Use matlab fcdf from statistics toolbox, if available (fast)
% Some cosmetic clean up
%
% Comments & questions can be directed to conder@geo.siu.edu
%----------------------
%%% check ordering. np2 should be > np1 and chi2 should be < chi1
% i.e., second model should have more parameters and better fit
if np2 == np1
disp('number of model parameters are the same in both cases!')
p = 1;
return
elseif np2 < np1 % np1 should be less than np2. If not, just swap.
nptemp = np1; np1 = np2; np2 = nptemp;
chitemp = chi1; chi1 = chi2; chi2 = chitemp;
end
if chi2 >= chi1
disp('misfit higher for model with more parameters!')
p = 1;
return
end
%%% number of degrees of freedom for f-distribution
df1 = np2 - np1; % number of degrees of freedom
df2 = n - np2 - 1;
%%% F-statistic
Fstat = df2*(chi1 - chi2)/(df1*chi2);
%%% find p by determination of cumulative f-distribution at Fstat
% first check if fcdf from matlab statistics toolbox is present (fast).
% if not, numerically integrate f-distribution.
% cdff is equivalent to result from fcdf in Matlab statistics package.
if exist('fcdf.m','file') == 2 % check for availability of fcdf from statistics toolbox
p = 1 - fcdf(Fstat,df1,df2);
else
if df1 ~= 1 % numerically integrate f-distribution
ifpt = 1000001; % large number of slices for accurate numerical integration
dx = Fstat/(ifpt-1);
x = 0:dx:1.2*Fstat;
fnumgam = gammaln((df1+df2)/2); % gamma func factors can be very large, use ln
fdengam = gammaln(df1/2) + gammaln(df2/2);
fgam = exp(fnumgam - fdengam);
fnum = fgam*((df1/df2)^(df1/2)).*(x.^(0.5*df1 -1));
fden = ((1 + df1*x/df2).^(0.5*(df1+df2)));
f = fnum./fden; % f distribution for df1, df2
%fF = f(ifpt); % f at Fstat
cdff = cumsum(f)*dx; % numerical integration of f distribution
p = 1 - cdff(ifpt);
else % when df1=1 use F-dist approximation from MatrixLabs to avoid -Inf
if Fstat <= 0.5 % Compute using inverse for small F-values
s = df2;
t = df1;
z = 1/Fstat;
else
s = df1;
t = df2;
z = Fstat;
end
j = 2/(9*s);
k = 2/(9*t);
% Use approximation formulas
y = abs((1 - k)*z^(1/3) - 1 + j)/sqrt(k*z^(2/3) + j);
if t < 4
y = y*(1 + 0.08*y^4/t^3);
end
a1 = 0.196854;
a2 = 0.115194;
a3 = 0.000344;
a4 = 0.019527;
p = 0.5/(1 + y*(a1 + y*(a2 + y*(a3 + y*a4))))^4;
% Adjust if inverse was computed
if Fstat <= 0.5
p = 1 - p;
end
end
end
end