Stephen Tashi said:
Just to focus the discussion on that point, I'll guess No.
Perhaps someone can show a practical problem in architecture where finding the height of a arch or something like that requires a cubic or quintic. That would still leave open the question of whether architects solved the problem that way or whether they used scale models. There is also the question of what is considered a practical application. For example, Cardano was (among other things) an astrologer. He no doubt considered an application of mathematics to astrology to be practical. Do we count it as such?
I think the original post is asking whether the solution of polynomial equations was the focus of intense interest due to the need to solve such problems using the technology of the era when these solutions were developed. The history of math books I read (once upon a time) never mentioned any such pressing need as motivation - but perhaps those books were written by pure mathematicians.
these are good points. i know for a fact that the grand cathedral at chartres was actually constructed through trial-and-error (apparently it fell down more than once), some of which might have been avoided if more knowledge of the mathematics of arches was more widely known.
and, of course, the "cutting edge" of mathematical research was (in the middle ages) often a closely guarded professional secret. even a widely-published mathematician such as Leonardo of Pisa did not reveal all of his "bag of tricks" in print, presumably because to a large extent court patronage (i.e. income, the middle age equivalent of today's research grant) was contingent upon being able to solve things nobody else could. it still makes me chuckle today to think about how Cardano and Tartaglia quarrelled about the cubic.
it would appear, from the scant information history leaves behind, that a good deal of research into polynomials was based on professional pride, and that at the time various solutions to higher-degree polynomials were found, these were considered as some of the more pressing unsolved problems in existence. everyone knew that equations were powerful in their problem-solving potential, and it was no doubt hoped at one time that EVERY equation might one day be cracked open.
it appears, that over time, a curious shift in priority occurred in mathematics. mathematics no doubt developed as a method to solve pragmatic problems: accounting (for), reckoning, estimating and predicting as-yet untranspired events (such as a harvest, or the building materials required for a bridge, etc.). at some point, the methods themselves took over: geometry was no longer about mensuration or surveying problems, and the techniques of al-jabr were not limited to solving astronomy questions, or business transactions, but became objects of study in their own right, divorced from any immediate application.
so it may be impossible to give a completely accurate answer: the orginal impetus for some polynomials may well have been certain physical situations, but at some point, mathematical theory started growing faster than engineering practice. but this wasn't by any means a uniform development, like two cars running down a drag-strip. both fields grew by fits and starts, knowledge become lost, and re-discovered.
for example: i came across a tid-bit that said that most of Euclid's book V was unusable in the 16th century, because of a bad translation. Tartaglia corrected this, making information available that had essentially been lost for centuries.
by Galois' time, universities devoted solely to study of mathematics for mathematics sake were already a feature of most important european cities (Paris had more than one, one of the great set-backs of Galois' life was his failure to get into the school he wanted to go to). In Cardano's time, mathematics was mainly limited to the people who could afford to study it, and there was less of a line drawn between "applied and pure" mathematics (it was still not uncommon for problems to be posed verbally, rather than symbolically). Liber Abaci was still in wide-spread use as a text, which makes no differentiation between "pure" and "applied" mathematics (and which has several problems involving polynomials).
mathematics appeared to be gaining the upper hand as a "pure science" by the beginning of the christian era, but no doubt the local politics of alexandria (where early christian sectarian conflict led to the burning of the great library), as well as the decline of the roman empire, gave "practical problems" a chance to catch up. were it not for the brilliance of islamic mathematicians during the "dark ages", it is doubtful that renaissance mathematics would have been so fecund.
