Does anyone know where I could find code for the "Inverse Error Function?" Freepascal/Delphi would be preferable but C/C++ would be fine too.
The TMath/DMath library did not have it :(
Does anyone know where I could find code for the "Inverse Error Function?" Freepascal/Delphi would be preferable but C/C++ would be fine too.
The TMath/DMath library did not have it :(
Here's an implementation of erfinv()
. Note that for it to work well, you also need a good implementation of erf()
.
function erfinv(const y: Double): Double;
//rational approx coefficients
const
a: array [0..3] of Double = ( 0.886226899, -1.645349621, 0.914624893, -0.140543331);
b: array [0..3] of Double = (-2.118377725, 1.442710462, -0.329097515, 0.012229801);
c: array [0..3] of Double = (-1.970840454, -1.624906493, 3.429567803, 1.641345311);
d: array [0..1] of Double = ( 3.543889200, 1.637067800);
const
y0 = 0.7;
var
x, z: Double;
begin
if not InRange(y, -1.0, 1.0) then begin
raise EInvalidArgument.Create('erfinv(y) argument out of range');
end;
if abs(y)=1.0 then begin
x := -y*Ln(0.0);
end else if y<-y0 then begin
z := sqrt(-Ln((1.0+y)/2.0));
x := -(((c[3]*z+c[2])*z+c[1])*z+c[0])/((d[1]*z+d[0])*z+1.0);
end else begin
if y<y0 then begin
z := y*y;
x := y*(((a[3]*z+a[2])*z+a[1])*z+a[0])/((((b[3]*z+b[3])*z+b[1])*z+b[0])*z+1.0);
end else begin
z := sqrt(-Ln((1.0-y)/2.0));
x := (((c[3]*z+c[2])*z+c[1])*z+c[0])/((d[1]*z+d[0])*z+1.0);
end;
//polish x to full accuracy
x := x - (erf(x) - y) / (2.0/sqrt(pi) * exp(-x*x));
x := x - (erf(x) - y) / (2.0/sqrt(pi) * exp(-x*x));
end;
Result := x;
end;
If you haven't got an implementation of erf()
then you can try this one converted to Pascal from Numerical Recipes. It's not accurate to double precision though.
function erfc(const x: Double): Double;
var
t,z,ans: Double;
begin
z := abs(x);
t := 1.0/(1.0+0.5*z);
ans := t*exp(-z*z-1.26551223+t*(1.00002368+t*(0.37409196+t*(0.09678418+
t*(-0.18628806+t*(0.27886807+t*(-1.13520398+t*(1.48851587+
t*(-0.82215223+t*0.17087277)))))))));
if x>=0.0 then begin
Result := ans;
end else begin
Result := 2.0-ans;
end;
end;
function erf(const x: Double): Double;
begin
Result := 1.0-erfc(x);
end;
Pascal Programs for Scientists and Engineers has the gaussian Error function (erf) and its complement erfc=(1-errf), but not the Inverse of the Error function. Obviously, you don't just take 1/ErrF. The inverse means x = erfinv(y) satisfies y = erf(x).
http://infohost.nmt.edu/~armiller/pascal.htm
Error function and its complement, are shown in this listing.
Again, the definition of Error Function Complement is 1-ErrF
, not ErrF^-1
, but this has got to be getting you close:
http://infohost.nmt.edu/~es421/pascal/list11-3.pas
I found this interesting implementation (language unknown, I'm guessing it's matlab). maybe it and its coefficients can help you:
http://w3eos.whoi.edu/12.747/mfiles/lect07/erfinv.m
Another PDF here: http://people.maths.ox.ac.uk/~gilesm/files/gems_erfinv.pdf
Relevant snippet:
Table 1: Pseudo-code to compute y = erfinv(x) , with p1(t)..p6(t) representing a 1st through 6th polynomial function of t :
a = |x|
if a > 0.9375 then
t = sqrt( log(a) )
y = p1(t) / p2(t)
else if a > 0.75 then
y = p3(a) / p4(a)
else
y = p5(a) / p6(a)
end if
if x < 0 then
y = −y
end if
Apparently the library code functions by approximation, it's less work. Sometimes the approximations are to less than 6 decimal places accuracy, I read.
Fortran code that many people use for a reference, is here, it cites "Rational Chebyshev approximations for the error function" by W. J. Cody, Math. Comp., 1969, PP. 631-638.:
Boost seems to have it as error_inv so look at the code.
I've used this, which I believe is reasonably accurate and quick (usually 2 iterations of the loop), but of course caveat emptor. NormalX assumes that 0<=Q<=1, and would likely give silly answers if that assumption doesn't hold.
/* return P(N>X) for normal N */
double NormalQ( double x)
{ return 0.5*erfc( x/sqrt(2.0));
}
#define NORX_C0 2.8650422353e+00
#define NORX_C1 3.3271545598e+00
#define NORX_C2 2.7147548996e-01
#define NORX_D1 2.8716448975e+00
#define NORX_D2 1.1690926940e+00
#define NORX_D3 4.7994444496e-02
/* return X such that P(N>X) = Q for normal N */
double NormalX( double Q)
{
double eps = 1e-12;
int signum = Q < 0.5;
double QF = signum ? Q : (1.0-Q);
double T = sqrt( -2.0*log(QF));
double X = T - ((NORX_C2*T + NORX_C1)*T + NORX_C0)
/(((NORX_D3*T + NORX_D2)*T + NORX_D1)*T + 1.0);
double SPI2 = sqrt( 2.0 * M_PI);
int i;
/* newton's method */
for( i=0; i<10; ++i)
{
double dX = (NormalQ(X) - QF)*exp(0.5*X*X)*SPI2;
X += dX;
if ( fabs( dX) < eps)
{ break;
}
}
return signum ? X : -X;
}
function erf(const x: extended): extended;
var
n: integer;
z: extended;
begin
Result := x;
z := x;
n := 0;
repeat
inc(n);
z := -z * x * x * (2 * n - 1) / ((2 * n + 1) * n);
Result := Result + z;
until abs(z) < 1E-20;
Result := Result * 2 / sqrt(pi);
end;
function erfinv(const x: extended): extended;
var
n: integer;
z: extended;
begin
Result := 0;
n := 0;
repeat
inc(n);
z := (erf(Result) - x) * sqrt(pi) / (2 * exp(-Result * Result));
Result := Result - z;
until (n = 100) or (abs(z) < 1E-20);
if abs(z) < 1E-20 then
n := -20
else
n := Floor(Log10(abs(z))) + 1;
Result := RoundTo(Result, n);
end;
Here is what I have from spe. To me it looks like they tried to speed it up by dragging all functions into one big polynomal. Keep in mind this is code from the 386 era
// Extract from package Numlib in the Free Pascal sources (http://www.freepascal.org)
// LGPL-with-static-linking-exception, see original source for exact license.
// Note this is usually compiled in TP mode, not in Delphi mode.
Const highestElement = 20000000;
Type ArbFloat = double; // can be extended too.
ArbInt = Longint;
arfloat0 = array[0..highestelement] of ArbFloat;
function spesgn(x: ArbFloat): ArbInt;
begin
if x<0
then
spesgn:=-1
else
if x=0
then
spesgn:=0
else
spesgn:=1
end; {spesgn}
function spepol(x: ArbFloat; var a: ArbFloat; n: ArbInt): ArbFloat;
var pa : ^arfloat0;
i : ArbInt;
polx : ArbFloat;
begin
pa:=@a;
polx:=0;
for i:=n downto 0 do
polx:=polx*x+pa^[i];
spepol:=polx
end {spepol};
function speerf(x : ArbFloat) : ArbFloat;
const
xup = 6.25;
sqrtpi = 1.7724538509055160;
c : array[1..18] of ArbFloat =
( 1.9449071068178803e0, 4.20186582324414e-2, -1.86866103976769e-2,
5.1281061839107e-3, -1.0683107461726e-3, 1.744737872522e-4,
-2.15642065714e-5, 1.7282657974e-6, -2.00479241e-8,
-1.64782105e-8, 2.0008475e-9, 2.57716e-11,
-3.06343e-11, 1.9158e-12, 3.703e-13,
-5.43e-14, -4.0e-15, 1.2e-15);
d : array[1..17] of ArbFloat =
( 1.4831105640848036e0, -3.010710733865950e-1, 6.89948306898316e-2,
-1.39162712647222e-2, 2.4207995224335e-3, -3.658639685849e-4,
4.86209844323e-5, -5.7492565580e-6, 6.113243578e-7,
-5.89910153e-8, 5.2070091e-9, -4.232976e-10,
3.18811e-11, -2.2361e-12, 1.467e-13,
-9.0e-15, 5.0e-16);
var t, s, s1, s2, x2: ArbFloat;
bovc, bovd, j: ArbInt;
begin
bovc:=sizeof(c) div sizeof(ArbFloat);
bovd:=sizeof(d) div sizeof(ArbFloat);
t:=abs(x);
if t <= 2
then
begin
x2:=sqr(x)-2;
s1:=d[bovd]; s2:=0; j:=bovd-1;
s:=x2*s1-s2+d[j];
while j > 1 do
begin
s2:=s1; s1:=s; j:=j-1;
s:=x2*s1-s2+d[j]
end;
speerf:=(s-s2)*x/2
end
else
if t < xup
then
begin
x2:=2-20/(t+3);
s1:=c[bovc]; s2:=0; j:=bovc-1;
s:=x2*s1-s2+c[j];
while j > 1 do
begin
s2:=s1; s1:=s; j:=j-1;
s:=x2*s1-s2+c[j]
end;
x2:=((s-s2)/(2*t))*exp(-sqr(x))/sqrtpi;
speerf:=(1-x2)*spesgn(x)
end
else
speerf:=spesgn(x)
end; {speerf}
function spemax(a, b: ArbFloat): ArbFloat;
begin
if a>b
then
spemax:=a
else
spemax:=b
end; {spemax}
function speefc(x : ArbFloat) : ArbFloat;
const
xlow = -6.25;
xhigh = 27.28;
c : array[0..22] of ArbFloat =
( 1.455897212750385e-1, -2.734219314954260e-1,
2.260080669166197e-1, -1.635718955239687e-1,
1.026043120322792e-1, -5.480232669380236e-2,
2.414322397093253e-2, -8.220621168415435e-3,
1.802962431316418e-3, -2.553523453642242e-5,
-1.524627476123466e-4, 4.789838226695987e-5,
3.584014089915968e-6, -6.182369348098529e-6,
7.478317101785790e-7, 6.575825478226343e-7,
-1.822565715362025e-7, -7.043998994397452e-8,
3.026547320064576e-8, 7.532536116142436e-9,
-4.066088879757269e-9, -5.718639670776992e-10,
3.328130055126039e-10);
var t, s : ArbFloat;
begin
if x <= xlow
then
speefc:=2
else
if x >= xhigh
then
speefc:=0
else
begin
t:=1-7.5/(abs(x)+3.75);
s:=exp(-x*x)*spepol(t, c[0], sizeof(c) div sizeof(ArbFloat) - 1);
if x < 0
then
speefc:=2-s
else
speefc:=s
end
end {speefc};