By definition, a rigid graph in Rd (or on a sphere) has a finite
number of embeddings up to rigid motions for a given set of edge length
constraints. These embeddings are related to the real solutions of an algebraic
system. Naturally, the complex solutions of such systems extend the notion of
rigidity to Cd. A major open problem has been to obtain tight upper
bounds on the number of embeddings in Cd, for a given number ∣V∣
of vertices, which obviously also bound their number in Rd.
Moreover, in most known cases, the maximal numbers of embeddings in
Cd and Rd coincide. For decades, only the trivial bound
of O(2d⋅∣V∣) was known on the number of embeddings.Recently, matrix
permanent bounds have led to a small improvement for d≥5. This work
improves upon the existing upper bounds for the number of embeddings in
Rd and Sd, by exploiting outdegree-constrained orientations on a
graphical construction, where the proof iteratively eliminates vertices or
vertex paths. For the most important cases of d=2 and d=3, the new bounds
are O(3.7764∣V∣) and O(6.8399∣V∣), respectively. In general, the
recent asymptotic bound mentioned above is improved by a factor of 1/2​. Besides being the first substantial improvement upon a long-standing
upper bound, our method is essentially the first general approach relying on
combinatorial arguments rather than algebraic root counts