We solve a very classical problem: providing a description of the geometry of a Euclidean tetrahedron from the initial data of the areas of the faces and the areas of the medial parallelograms of Yetter, or equivalently of the pseudofaces of McConnell. In particular, we derive expressions for the dihedral angles, face angles, and (an) edge length, the remaining parts being derivable by symmetry or by identities in the classic 1902 compendium of results on tetrahedral geometry by G. Richardson. We also provide an alternative proof using (bi)vectors of the result of Yetter that four times the sum of the squared areas of the medial parallelograms is equal to the sum of the squared areas of the faces. Despite the classical nature of the problem, it would not have been natural to consider had it not been suggested by recent work in quantum physics.