Tarski's exponential function problem

The problem

The ordered real field R is a structure over the language of ordered rings L_or = (+,·,−,<,0,1), with the usual interpretation given to each symbol. It was proved by Tarski that the theory of the real field, Th(R), is decidable. That is, given any L_or-sentence φ there is an effective procedure for determining whether

He then asked whether this was still the case if one added a unary function exp to the language that was interpreted as the exponential function on R, to get the structure R_exp.

Conditional and equivalent results

The problem can be reduced to finding an effective procedure for determining whether any given exponential polynomial in n variables and with coefficients in Z has a solution in Rⁿ. Macintyre & Wilkie (1995) showed that Schanuel's conjecture implies such a procedure exists, and hence gave a conditional solution to Tarski's problem. Schanuel's conjecture deals with all complex numbers so would be expected to be a stronger result than the decidability of R_exp, and indeed, Macintyre and Wilkie proved that only a real version of Schanuel's conjecture is required to imply the decidability of this theory.

Even the real version of Schanuel's conjecture is not a necessary condition for the decidability of the theory. In their paper, Macintyre and Wilkie showed that an equivalent result to the decidability of Th(R_exp) is what they dubbed the Weak Schanuel's Conjecture. This conjecture states that there is an effective procedure that, given n ≥ 1 and exponential polynomials in n variables with integer coefficients f₁,..., f_n, g, produces an integer η ≥ 1 that depends on n, f₁,..., f_n, g, and such that if α ∈ Rⁿ is a non-singular solution of the system

then either g(α) = 0 or |g(α)| > η⁻¹.

Workaround

Recently there are attempts at handling the theory of the real numbers with functions such as exp, sin by relaxing decidability to the weaker notion of quasi-decidability. A theory is quasi-decidable iff there is a procedure that decides satisfiability but that may run forever for inputs that are not robust in a certain, well-defined sense. Such a procedure exists for systems of n equations in n variables (Franek, Ratschan & Zgliczynski (2011)).