What is being done in here ? (Used math recognition)

I know this isn't exactly programming related per se, but programmers are the most probable of all people who will recognize this maybe.

I have the following (X and Y are arrays, both with 3 elements), and I cannot recognize (although it reminds me of a few things, but none quite!) what is being done here. Does it ring any bells for anyone else ?

I gather you can disregard the lower part; the upper should probably give it away ... but I still cannot see it.

At first it reminded me of linear interpolation in 3d space ...

``````  SUBROUTINE TRII(X,Y,XR,YR)
DIMENSION X(3),Y(3)

D=X(1)*(X(2)**2-X(3)**2)+
>    X(2)*(X(3)**2-X(1)**2)+
>    X(3)*(X(1)**2-X(2)**2)

D1=Y(1)*(X(2)*X(3)**2-X(3)*X(2)**2)+
>     Y(2)*(X(3)*X(1)**2-X(1)*X(3)**2)+
>     Y(3)*(X(1)*X(2)**2-X(2)*X(1)**2)

D2=Y(1)*(X(2)**2-X(3)**2)+
>     Y(2)*(X(3)**2-X(1)**2)+
>     Y(3)*(X(1)**2-X(2)**2)

D3=X(2)*(Y(3)-Y(1))+
>     X(1)*(Y(2)-Y(3))+
>     X(3)*(Y(1)-Y(2))

A=D1/D
B=D2/D
C=D3/D

YR=A+B*XR+C*XR**2

RETURN
END

SUBROUTINE TRIM(X,Y,XR,YR,XM,YM)
DIMENSION X(3),Y(3)

D=X(1)*(X(2)**2-X(3)**2)+
>    X(2)*(X(3)**2-X(1)**2)+
>    X(3)*(X(1)**2-X(2)**2)

D1=Y(1)*(X(2)*X(3)**2-X(3)*X(2)**2)+
>     Y(2)*(X(3)*X(1)**2-X(1)*X(3)**2)+
>     Y(3)*(X(1)*X(2)**2-X(2)*X(1)**2)

D2=Y(1)*(X(2)**2-X(3)**2)+
>     Y(2)*(X(3)**2-X(1)**2)+
>     Y(3)*(X(1)**2-X(2)**2)

D3=X(2)*(Y(3)-Y(1))+
>     X(1)*(Y(2)-Y(3))+
>     X(3)*(Y(1)-Y(2))

A=D1/D
B=D2/D
C=D3/D

XR=-B/(2.*C)
YR=A+B*XR+C*XR**2

XM=XR
IF(XR.GT.X(1).OR.XR.LT.X(3))XM=X(1)
YM=A+B*XM+C*XM**2
IF(YM.LT.Y(1))XM=X(1)
IF(YM.LT.Y(1))YM=Y(1)

RETURN
END
``````

">" is a continuation sign.

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Ewwwwwwwwwwwwww –  Steven Schlansker Jun 26 '10 at 23:27
Can you provide some context? During what kind of operation does this code get executed? –  Mike Daniels Jun 26 '10 at 23:31
@Mike - It is a subroutine (what is above is pretty much all of it, except the calling part). I cannot unfortunatelly be any more specific (well, not much! more), since I also am trying to understand / reverse engineer some code. I know what it does (the whole code). It's just the math/means how it does it is what I'm trying to understand. It is not secret or anything, but pasting the whole of code is somewhat unpractical. And this is one of the subroutines that gets called often, so I gathered the above should be enough. –  ldigas Jun 26 '10 at 23:36
@Idigas: Does the subroutine have any sort of meaningful name? I know it's not a given, especially with older Fortran code.... –  Pillsy Jun 26 '10 at 23:43
Programmers can write Fortran in any language. Oh...wait, this is Fortran. –  Nathan Ernst Jun 28 '10 at 2:56

The code run as follows

Routine TRII takes as input the coordinates of three points (x,y) and interpolates a parabola using Lagrange interpolation. Also takes as input the coordinate XR. Returns in YR the value at XR for the interpolating parabola. I guess the name of the routine comes from "TRI" (Croatian for "three" (points)) and "I" for Interpolation.

Routine TRIM also calculates the same parabola, and returns the minimun value of the function in the interval {X(1),X(3)}.The name comes from "TRI" and "M" (minimum)

(I "really" executed the program) >)

Note that this is FORTRAN code and the parameters are passed by reference, so the results are returned back in the same parameters (very odd!)

Edit

Just for fun, let's run TRII

``````TRII[X_, Y_, XR_] :=
Module[{D0, D1, D2, D3, A, B, C},
D0 = X[[1]]*(X[[2]]^2 - X[[3]]^2) +
X[[2]]*(X[[3]]^2 - X[[1]]^2) +
X[[3]]*(X[[1]]^2 - X[[2]]^2);
D1 = Y[[1]]*(X[[2]]*X[[3]]^2 - X[[3]]*X[[2]]^2) +
Y[[2]]*(X[[3]]*X[[1]]^2 - X[[1]]*X[[3]]^2) +
Y[[3]]*(X[[1]]*X[[2]]^2 - X[[2]]*X[[1]]^2);
D2 = Y[[1]]*(X[[2]]^2 - X[[3]]^2) +
Y[[2]]*(X[[3]]^2 - X[[1]]^2) +
Y[[3]]*(X[[1]]^2 - X[[2]]^2);
D3 = X[[2]]*(Y[[3]] - Y[[1]]) +
X[[1]]*(Y[[2]] - Y[[3]]) +
X[[3]]*(Y[[1]] - Y[[2]]);
A = D1/D0;
B = D2/D0;
C = D3/D0;
Return[A + B*XR + C*XR^2];];

X = RandomReal[1, 3];
Y = RandomReal[1, 3];
Show[Plot[TRII[X, Y, x], {x, 0, 1}],
ListPlot[Transpose[{X, Y}], PlotMarkers -> Automatic]]
``````

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Good detective work, seems correct to me. –  waxwing Jun 27 '10 at 8:55
Indeed. (Although others put in their fair share as well.) –  ldigas Jun 27 '10 at 17:06
@belisarius - Nor so much odd, really. This was written for UNIVAC machine. –  ldigas Jun 27 '10 at 17:07
@Idigas With a few syntax mods it runs in Mathematica ... –  belisarius Jun 28 '10 at 0:30
@belisarius - I doubt it would. With all optimizations from IVF turned on, the program runs about 7min20sec on my computer (a year old). Mind you, it has been somewhat updated since its original version. –  ldigas Jun 28 '10 at 12:07

D is the determinant of the matrix:

``````        | x(1) x(1)² 1 |
D = det | x(2) x(2)² 1 |
| x(3) x(3)² 1 |
``````

In D1, the rightmost column has been replaced with Y:

``````         | x(1) x(1)² Y(1) |
D1 = det | x(2) x(2)² Y(2) |
| x(3) x(3)² Y(3) |
``````

In D2, and D3 it's the first and second columns, respectively. Is it easier to recognize now? Looks a lot like using Cramer's rule to solve a linear equation to me.

Edit: To be more precise: (A, B, C) is the solution to the system:

``````A + x(1)*B + x(1)²*C = Y(1)
A + x(2)*B + x(2)²*C = Y(2)
A + x(3)*B + x(3)²*C = Y(3)
``````

YR is the square of the solution to the quadratic equation (nb, different x!):

``````C*x² + B*x + A = 0
``````

I feel like this should be obvious now, but I can't quite grasp it...

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no, it's not. 2 arrays with 3 elements != one 3x3 and one 1x3 matrix. I just realized it. –  Femaref Jun 26 '10 at 23:53
@Femaref - that's right. Two arrays (vectors if you like), 1x3 (1 column, 3 rows each). –  ldigas Jun 27 '10 at 0:05
The matrix D is called Vadermonde Matrix mathworld.wolfram.com/VandermondeMatrix.html –  belisarius Jun 27 '10 at 0:19

I'm not sure what language this is, but it's clear that this is some sort of solver for quadratic equations. The `XR` and `YR` expressions are a dead giveaway:

``````XR = -B / (2.*C)
YR = A + B*XR + C*XR**2
``````

Without knowing what the `X(1..3)` and `Y(1..3)` expressions are, however, it's not going to be possible to infer too much more about what the A/B/C coefficients represent, however. Lots of things use quadratic equations -- area of a circle given the radius, intensity of light at a given distance, et cetera. More contextual data is required.

Update: The OP indicated that he can't be too much more specific for secrecy reasons. Here are some hints, though:

• What does the subroutine return? How are those results used later on? That may lead to better insights.

• It appears that Y(1) is some sort of magic lower bound for the result of this computation. Notice that if `YM` is less than `Y(1)`, then both `XM` and `YM` are set to `X(1)` and `Y(1)`, respectively.

• The "D" expressions look like this, in more natural syntax:

``````d = x1 * [x2^2 - x3^2] + x2 * [x3^2 - x1^2] + x3 * [x1^1 - x2^2]
d1 = y1 * [x2*x3^2 - x3*x2^2] + y2 * [x3*x1^2 - x1*x3^2] + y3 * [x1*x2^2 - x1*x2^2]
d2 = y1 * [x2^2 - x3^2] + y2 * [x3^2 - x1^2] + y3 * [x1^2 - x2^2]
d3 = x2 * [y3 - y1] + x1 * [y2 - y3] * x3 * [y1 - y2]
``````
• This looks very much like some sort of matrix operation; `D` is almost certainly for "determinant". But there are other things that have the same mathematical relationship.
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A-ah, well, that's a start. Yes, you're right about the X,Y, but as I said to @Mike in the question comments, what is above is in a subroutine, and except the calling part that is pretty much it. So X and Y could be anything. But I'm still mostly interested in the first lines (the D, D1, ...) - they present the biggest unknown to me (and yet, they awfully remind me of something). –  ldigas Jun 26 '10 at 23:38
That language is Fortran. Using `.LT.` and `.GT.` as comparisons, `()` for array indices and `**` for exponentiation give it away. –  Pillsy Jun 26 '10 at 23:39
Thanks for the additional insight, Pillsy. +1! –  John Feminella Jun 26 '10 at 23:41
@Pillsy - Yes. Didn't mention it; didn't think it makes any difference. –  ldigas Jun 26 '10 at 23:42
No, no. I'm not being secretive at all. It's just those are the routines used in a rather large program ("finding an optimum problem", based on some regression analysis expressions). The whole code is some 20k lines, and I have trouble finding my way in it; (and I know what it does, and the background); less alone someone who just stumbled into it. –  ldigas Jun 26 '10 at 23:54

This code represents a kind of interpolation/quadratic curve fitting on three 2d points together with a way to compute the minimum or maximum value of such a fitted quadratic within the interval itself. I guess that TRII stands for triple (point)-interpolation and TRIM stands for triple (point) minimum or maximum.

To be more precised TRII solves the problem :- find a quadratic curve that passes through the points (x1,y1),(x2,y2) and (x3,y3) in the form Y=A+B*X+C*X^2 and compute the Y value of the quadratic at the point XR and return as YR. This is basically a way to interpolate smoothly between three 2d points. It is often used to find a better approximation for the max or min value of a set of discrete data points.

All the D, D1, D2, D3 stuff is to solve the matrix equation:

(1 X1 X1^2) *(A) = (Y1)

(1 X2 X2^2) *(B) = (Y2)

(1 X3 X3^2) *(C) = (Y3)

using Cramers rule as mentioned in one of the other comments, D is the matrix determinant and D1, D2, D3 are co-factors.

TRIM again computes the quadratic Y=A+B*X+C*X^2 and then finds a max/min of this quadratic (XM, YM). This is done by initially finding the point where the quadratic has a turning point: if F(X)=A+B*X+C*X^2, F'(XR)=B+2*C*XR=0, or XR=-B/2*C, YR=A+B*XR+C*XR^2. There is then some logic to force the returned XM, YM min or max values to lie within certain bounds.

The code:

XM=XR . . . IF(YM.LT.Y(1))YM=Y(1)

Is a little weird since if we assume that GT and LT mean greater than and less than respectively then we need to assume that X3'<'X1 otherwise the condition (XR.GT.X(1).OR.XR.LT.X(3)) is trivial and XM,YM are set to X1, Y1.

So X3'<'X1 and the condition says that if the quadratics max/min value is outside the interval (X1,X3) then set (XM,YM) to (X1, Y1) as before. If not then if Y1 is above the min/max value in Y then again set (XM,YM) to (X1, Y1).

It is hard to understand what this means and I suspect the code may be wrong! Any thoughts?

Ivan

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