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I would like to evaluate the inverse Student's t-distribution function for small values, e.g., 1e-18, in Matlab. The degrees of freedom is 2.

Unfortunately, Matlab returns NaN:

tinv(1e-18,2)
NaN

However, if I use R's built-in function:

qt(1e-18,2)
-707106781

The result is sensible. Why can Matlab not evaluate the function for this small value? The Matlab and R results are quite similar to 1e-15, but for smaller values the difference is considerable:

tinv(1e-16,2)/qt(1e-16,2) = 1.05

Does anyone know what is the difference in the implemented algorithms of Matlab and R, and if R gives correct results, how could I effectively calculate the inverse t-distribution, in Matlab, for smaller values?

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    The two cited authorities for the R qt C code function are: Hill, G. W. (1970) Algorithm 396: Student's t-quantiles. Communications of the ACM, 13(10), 619–620. and Hill, G. W. (1981) Remark on Algorithm 396, ACM Transactions on Mathematical Software, 7, 250–1. – 42- Jan 12 '15 at 23:25
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    I confirm that on my machine it fails for the first argument lower than some 1e-16. As for the algorithm, in Matlab you can do open tinv and see what it does – Luis Mendo Jan 12 '15 at 23:26
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    It's also worth pointing out I think that a lot of work has gone into qt() (mostly by Martin Maechler) over the years to make sure it works reliably in lots of extreme cases: github.com/wch/r-source/commits/trunk/src/nmath/qt.c – Ben Bolker Mar 23 '15 at 1:16
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It appears that R's qt may use a completely different algorithm than Matlab's tinv. I think that you and others should report this deficiency to The MathWorks by filing a service request. By the way, in R2014b and R2015a, -Inf is returned instead of NaN for small values (about eps/8 and less) of the first argument, p. This is more sensible, but I think they should do better.

In the interim, there are several workarounds.

Special Cases
First, in the case of the Student's t-distribution, there are several simple analytic solutions to the inverse CDF or quantile function for certain integer parameters of ν. For your example of ν = 2:

% for v = 2
p = 1e-18;
x = (2*p-1)./sqrt(2*p.*(1-p))

which returns -7.071067811865475e+08. At a minimum, Matlab's tinv should include these special cases (they only do so for ν = 1). It would probably improve the accuracy and speed of these particular solutions as well.

Numeric Inverse
The tinv function is based on the betaincinv function. It appears that it may be this function that is responsible for the loss of precision for small values of the first argument, p. However, as suggested by the OP, one can use the CDF function, tcdf, and root-finding methods to evaluate the inverse CDF numerically. The tcdf function is based on betainc, which doesn't appear to be as sensitive. Using fzero:

p = 1e-18;
v = 2
x = fzero(@(x)tcdf(x,v)-p, 0)

This returns -7.071067811865468e+08. Note that this method is not very robust for values of p close to 1.

Symbolic Solutions
For more general cases, you can take advantage of symbolic math and variable precision arithmetic. You can use identities in terms of Gausian hypergeometric functions, 2F1, as given here for the CDF. Thus, using solve and hypergeom:

% Supposedly valid for or x^2 < v, but appears to work for your example
p = sym('1e-18');
v = sym(2);
syms x
F = 0.5+x*gamma((v+1)/2)*hypergeom([0.5 (v+1)/2],1.5,-x^2/v)/(sqrt(sym('pi')*v)*gamma(v/2));
sol_x = solve(p==F,x);
vpa(sol_x)

The tinv function is based on the betaincinv function. There is no equivalent function or even an incomplete Beta function in the Symbolic Math toolbox or MuPAD, but a similar 2F1 relation for the incomplete Beta function can be used:

p = sym('1e-18');
v = sym(2);
syms x
a = v/2;
F = 1-x^a*hypergeom([a 0.5],a+1,x)/(a*beta(a,0.5));
sol_x = solve(2*abs(p-0.5)==F,x);
sol_x = sign(p-0.5).*sqrt(v.*(1-sol_x)./sol_x);
vpa(sol_x)

Both symbolic schemes return results that agree to -707106781.186547523340184 using the default value of digits.

I've not fully validated the two symbolic methods above so I can't vouch for their correctness in all cases. The code also needs to be vectorized and will be slower than a fully numerical solution.

  • Thank you very much for the detailed answer! NaN is returned on 2014a. I wasn't aware of the special case analytical solutions. I used fzero(@(x) tcdf(x,2) - P, 0) to construct the inverse function at several points, then interp1; it is more general, but for df = 2 it is quite wasteful. – Arpi Jan 14 '15 at 7:44
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    @Arpi: You're welcome. Good point about solving for the roots using the numeric CDF function itself. I've updated my answer with your suggestion and additional commentary. – horchler Jan 14 '15 at 22:07

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