Heron's Formula For Tetrahedra 

In another article we gave a very direct derivation of Heron's formula based on Pythagoras's Theorem for right triangles. However, we might also observe that Heron's formula is essentially equivalent to Pythagoras' Theorem for right tetrahedra. For a right tetrahedron with vertices (0,0,0), (a,0,0), (0,b,0), and (0,0,c), the base and height of the "hypotenuse" are 

_{} 

where (by similar triangles) h = ab/(Base) is the distance from the origin to the base, so we have 

_{} 

Thus if B,C,D denote the areas of the three orthogonal faces of a right tetrahedron with orthogonal edge lengths a,b,c, and if A denotes the area of the "hypotenuse face", we have 

_{} 

where B = ab/2, C = ac/2, and D = bc/2. This is essentially Heron's formula. To make this explicit, note that the edges of the hypotenuse face d,e,f are directly related to a,b,c according to the Pythagorean relations 

_{} 

so we can express the areas B,C,D in equation (1) in terms of d^{2}, e^{2}, and f^{2} to give Heron's formula explicitly. 

It might seem as if this derivation does not apply to obtuse triangles, because the "hypotenuse face" of a right tetrahedron is necessarily acute (i.e., each of its angles must be less than 90 degrees). However, any triangle can be the hypotenuse face of a right tetrahedron, provided the orthogonal edge lengths and areas are allowed to be imaginary. Thus for any values of d,e,f we can solve equations (2) for the orthogonal edges of the right tetrahedron whose hypotenuse is the triangle with the edges lengths d, e, f. This gives 

_{} 

For example, suppose we want the area of a triangle with edge lengths 8, 5, and 5, which is an obtuse triangle. Substituting these into the above equations gives 

_{} 

so the "c" leg has imaginary length. Consequently, two of the three orthogonal faces (those given by ac/2 and bc/2) are also imaginary. However, these areas only appear squared in the Pythagorean formula for right tetrahedrons, so we're guaranteed to get a real area for the hypotenuse face. As Hadamard said, "The shortest path to any truth involving real quantities often passes through the complex plane". 

I honestly wouldn't be surprised if the ancient Greeks were aware of the connection between the generalized Pythagorean theorem and Heron's formula, but refrained from presenting it in that form because of difficulties with interpreting the obtuse case. Recall that Descartes, for one, believed the ancient Greeks had discovered most of their theorems analytically by means of coordinate geometry and algebra, but concealed their methods, presenting them in synthetic form, so as to make the results seem more daunting and impressive to the uninitiated. (See the note on Prisca Sapientia.) It has always seemed doubtful that Heron's formula was discovered via the thought process of Heron's proof, which is absurdly circuitous. In any case, this is a nice example of how imaginary numbers can arise naturally in dealing with questions of purely real quantities. 

As for higher dimensional simplexes, there is no complete generalization of Heron's formula giving the volume of a general tetrahedron in terms of the areas of its faces, because the face areas don't uniquely determine the volume (in contrast to the case of triangles, where the three edge lengths determine the area). However, it is possible to derive a "Heron's formula" for tetrahedrons if we restrict ourselves to just those that would fit as the "hypotenuse face" of a right fourdimensional solid. (Notice that every triangle is the face of a right tetrahedron, which explains why Heron's formula is complete for triangles). 

To review, remember that Heron's formula for triangles is essentially equivalent to Pythagoras' Theorem for right tetrahedrons. Let's let A_{xyo}, A_{xoz}, and A_{oyz} denote the areas of the three orthogonal faces of a right tetrahedron, and A_{xyz} denote the area of the "hypotenuse face", so we have 

_{} 

Now if we let L_{x}, L_{y}, L_{z} denote the three orthogonal edge lengths of the tetrahedron, then the areas of its orthogonal faces are simply 

_{} 

and so equation (3) can be rewritten in the form 

_{} 

Furthermore, the three edges L_{1}, L_{2}, L_{3} of the hypotenuse face are directly related to L_{x}, L_{y}, L_{z} by the twodimensional Pythagorean theorem 

_{} 

Equations (5) are three linear equations in the three squared edge lengths, so we can solve for these squared lengths in terms of L_{1}, L_{2}, and L_{3}, and then substitute these into equation (4) to give the ordinary Heron's formula for triangles, as before. 

Now, we can do the same thing for tetrahedrons based on the generalized Pythagorean theorem for volumes of right fourdimensional solids 

_{} 

If we let L_{w}, L_{x}, L_{y}, L_{z}, denote the orthogonal edge lengths of the fourdimensional solid, then the volumes of the four orthogonal "faces" are simply 

_{} 

so equation (3') can be rewritten as 

_{} 

Furthermore, the four areas A_{1}, A_{2}, A_{3}, A_{4} of the hypotenuse "face" are directly related to L_{x}, L_{y}, L_{z} by the threedimensional Pythagorean theorem (4) 

_{} 

Thus, given the four face areas A_{1}, A_{2}, A_{3}, A_{4}, we have four equations in the four unknowns L_{2}, L_{x}, L_{y}, L_{z}, so we can solve for these values and then compute the volume of the tetrahedron using (4'). 

At this point people usually turn away from this approach, for two reasons. First, everything we're doing is restricted to the "special" tetrahedrons that can serve as the hypotenuse of a "right" fourdimensional simplex, so we're certainly not going to end up with a general formula applicable to every tetrahedron (as is clear from the fact that we have only four independent edge lengths here, whereas the general tetrahedron has six). General formulas giving the volume in terms of the edge lengths do exist, such as the one give by the Italian painter Piero della Francesca. Of course, all such formulae can be traced back to the wellknown determinant expression for volumes. 

The second reason that people usually give up on equations (5') is that they are somewhat messy to solve, since they are nonlinear in the lengths. Still, we might decide to press on anyway. It turns out (after extensive algebraic manipulation) that we can reduce (5') 
to a single quartic in the square of any of the four edge lengths L_{w}, L_{x}, L_{y}, or L_{z}. Arbitrarily selecting L_{y}, and letting A,B,C,D denote 4 times the squares of the face areas (i.e., the left hand sides of equations (5')), we can express the quartic in x = L_{y}^{2} with coefficients that are functions of B and the elementary symmetric polynomials of A,C,D 

_{} 

In these terms the quartic for x = L_{y}^{2} is 

_{} 

Of course, the analogous quartics can be given for L_{w}^{2}, L_{x}^{2}, and L_{z}^{2}, but once we have any one of them we can more easily compute the others. For example, given L_{y} we can compute L_{x} from the relation 

_{} 

and the values of L_{w} and L_{z} follow easily, allowing us to compute the volume using equation (4'). It would be nice if we could express the volume as an explicit function of the face areas, but I don't know if such a formula exists. 

In the preceding discussion we developed a tetrahedral version of Heron's formula for a restricted class of tetrahedra, namely those that can serve as the hypotenuse of a "right" fourdimensional simplex, but there are other special classes of tetrahedra that possess interesting volume formulas. The one that gives the closest analogue to Heron's formula is the class of tetrahedra whose opposite edges lengths are equal. Thus there are only three independent edge lengths, and each face of the tetrahedron is identical. Letting (a,f), (b,e), and (c,d) denote the pairs of opposite edge lengths, we can set a = f, b = e, and c = d in the basic determinant expression for the volume, or equivalently in Piero della Francesca's formula, and we find that the resulting expression for the squared volume factors as 

_{} 

which is certainly reminiscent of Heron's formula for the area of each face 

_{} 

This also shows that if each face is an identical right triangle, the volume is zero, as it must be, since four such triangles connected by their edges to give a tetrahedron necessarily all lie flat in the same plane: 


Obviously we can construct a regular tetrahedron with equilateral triangles of the same area as these right triangles, and the volume is _{}, which illustrates the fact that the face areas of a tetrahedron do not in general determine it's volume. 
