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, _{2}*F*_{1}, 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 _{2}*F*_{1} 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.

`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`open tinv`

and see what it does – Luis Mendo Jan 12 '15 at 23:26`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