At this point, people are even modeling figures on Ancient Greek pottery to determine the biomechanical merit of their fighting stances: https://www.mdpi.com/2075-4663/12/12/317
The same or similar techniques, of course, can apply to any combination of fighters (or dancers, or swimmers, etc.) at any particular moment. At the highest levels of sport, biomechanics analysts are employed, e.g.: https://pubmed.ncbi.nlm.nih.gov/34402417/
In any case, I don't think that I made any extraordinary claims. There are a lot of unknowns, though, as the most valuable analyses tend to be extremely computationally demanding.
It can assuredly be done in practice, with currently available technology. It would, however, be very expensive and time-consuming.
I'm thinking of putting together a set of general biomechanical models for foil or kendo fencing. Both forms feature a highly constrained ruleset, which simplifies things. Hobby project, though, so maybe one of these days...
At this point, people are even modeling figures on Ancient Greek pottery to determine the biomechanical merit of their fighting stances: https://www.mdpi.com/2075-4663/12/12/317
The same or similar techniques, of course, can apply to any combination of fighters (or dancers, or swimmers, etc.) at any particular moment. At the highest levels of sport, biomechanics analysts are employed, e.g.: https://pubmed.ncbi.nlm.nih.gov/34402417/
In any case, I don't think that I made any extraordinary claims. There are a lot of unknowns, though, as the most valuable analyses tend to be extremely computationally demanding.