# Calculate Volume of any Tetrahedron given 4 points

I need to calculate the volume of "any" tetrahedron given 4 points. I'm writing a program, that needs to find the volume of the tetrahedron, and what I know is: all X, Y, Z location of the 4 points. The function have to return the volume. I'm stucked in this for 10 hours... I couldn't think in ANY thing. Thanks!

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which language you are doing in?? –  Surya Mar 26 '12 at 4:08
@Surya irrelevant –  bobobobo Mar 26 '12 at 4:17
I will implement it in PHP, to calculate the total Volume of a .STL file en.wikipedia.org/wiki/STL_(file_format) –  Ivan Seidel Mar 26 '12 at 4:29
@bobobobo I thought this guy is finding problem with code as this question is simple. Just apply formula. –  Surya Mar 26 '12 at 16:06

Say if you have 4 vertices a,b,c,d (3-D vectors).

Now, the problem comes down to writing code which solves cross product and dot product of vectors. If you are from python, you can use NumPy or else you can write code on your own.

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(a-b) would be: (ax-bx, ay-by, az-bz), and where do i have to do "Determinant"? thanks! –  Ivan Seidel Mar 26 '12 at 4:28
Look at it clearly, its not determinant. Its mod. The dot product of two vectors will give rise to a number. so, as its volume, we can't assign negative numbers.. Thus mod was kept. –  Surya Mar 26 '12 at 4:41
Now i got it! thanks! –  Ivan Seidel Mar 26 '12 at 4:43
If you are talking about cross product. Say you have 2 vectors, A & B. Create 2 arrays each having 3 numbers. Thus, the cross product should be directly written as <br/> ```iDir = (vectA[0] * ( (vectA[1]*vectB[2]) - (vectA[2]*vectB[1]) ) ) jDir = - ( vectA[1] * ( (vectA[0]*vectB[2]) - (vectA[2]*vectB[0]) ) ) kDir = (vectA[2] * ( (vectA[0]*vectB[1]) - (vectA[1]*vectB[0]) ) ) productAB = [iDir, jDir, kDir]``` –  Surya Mar 26 '12 at 4:45
you could always go for a better algorithm but this one is a basic one to go for. –  Surya Mar 26 '12 at 4:48
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Here is the code, in PHP, that calculates the Volume of any Tetrahedron given 4 points:

``````class Math{
public static function determinant(array \$vals){
\$s = sizeof(\$vals);
\$sum = 0.0;
for( \$i=0; \$i < \$s ; \$i++ ){
\$mult = 1.0;
for(\$j=0; \$j < \$s ; \$j++ ){
\$mult *= \$vals[\$j][ (\$i+\$j)%\$s ];
}
\$sum += \$mult;
}
for( \$i=0; \$i < \$s ; \$i++ ){
\$mult = 1;
for(\$j=0; \$j < \$s ; \$j++ ){
\$mult *= \$vals[\$j][ (\$i-\$j < 0? \$s - (\$j-\$i) :(\$i-\$j)) ];
}
\$sum -= \$mult;
}
return \$sum;
}

public static function subtract(array \$a, array \$b){
for(\$i = 0; \$i < sizeof(\$a); \$i++)
\$a[\$i] -= \$b[\$i];

return \$a;
}
}
// TEST CASE
\$a = array(0,0,0);
\$d = array(2,0,0);
\$c = array(0,2,0);
\$b = array(0,0,2);

echo abs(Math::determinant(array(
Math::subtract(\$a, \$b),
Math::subtract(\$b, \$c),
Math::subtract(\$c, \$d),
)))/6;
``````
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One way to compute this volume is this:

``````     1      [ax bx cx dx]
V = --- det [ay by cy dy]
6      [az bz cz dz]
[ 1  1  1  1]
``````

This involves the evaluation of a 4×4 matrix. It generalizes nicely to simplices of higher dimensions, with the 6 being a special case of n!, the factorial of the dimension. The resulting volume will be oriented, i.e. may be negative depending on the order of points. If you don't want that, take the absolute value of the result.

If you have a math library at hand, the above formulation might be among the easiest to write down, and the software can take it from there. If not, you might simplify things first by subtracting the d coordinates from a through c. This will not change the volume but turn the rightmost column into `(0, 0, 0, 1)`. As a result, you can compute the value of the matrix simply as the determinant of the upper left 3×3 submatrix. And using the equation

det(a, b, c) = a · (b × c)

you end up with the formula from Surya's answer.

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Ivan Seidel's example, in python3 (answer is 1.3333...)

``````def determinant_3x3(m):
return (m[0][0] * (m[1][1] * m[2][2] - m[1][2] * m[2][1]) -
m[1][0] * (m[0][1] * m[2][2] - m[0][2] * m[2][1]) +
m[2][0] * (m[0][1] * m[1][2] - m[0][2] * m[1][1]))

def subtract(a, b):
return (a[0] - b[0],
a[1] - b[1],
a[2] - b[2])

a = [0.0, 0.0, 0.0]
d = [2.0, 0.0, 0.0]
c = [0.0, 2.0, 0.0]
b = [0.0, 0.0, 2.0]

print(
abs(determinant_3x3((subtract(a, b),
subtract(b, c),
subtract(c, d),
))) / 6.0)
``````
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