Thw two obvious areas where these would be applied were projective geometry, and number theory (less then in fashion). The geometric use was connected with invariant theory[?]. There is a general linear group acting on any given space of quantics, and this group action is potentially a fruitful way to classify algebraic varieties (for example cubic hypersurfaces in a given number of variables).
In more modern language the spaces of quantics are identified with the symmetric tensors of a given degree constructed from the tensor powers of a vector space V of dimension m. (This is straightforward provided we work over a field of characteristic zero). That is, we take the nfold tensor product of V with itself and take the subspace invariant under the symmetric group as it permutes factors. This definition specifies how GL(V) will act.
It would be a possible direct method in algebraic geometry, to study the orbits of this action. More precisely the orbits for the action on the projective space formed from the vector space of symmetric tensors. The construction of invariants would be the theory of the coordinate ring of the 'space' of orbits, assuming that 'space' exists. No direct answer to that was given, until the geometric invariant theory[?] of David Mumford[?]; so the invariants of quantics were studied directly. Heroic calculations were performed, in an era leading up to the work of David Hilbert] on the qualitative theory.
For algebraic forms with integer coefficients, generalisations of the classical results on quadratic forms to forms of higher degree motivated much investigation.
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