We study the Radical Identity Testing problem (RIT): Given an algebraic circuit representing a polynomial $f\in \mathbb{Z}[x_1, \ldots, x_k]$ and nonnegative integers $a_1, \ldots, a_k$ and $d_1, \ldots,$ $d_k$, written in binary, test whether the polynomial vanishes at the real radicals $\sqrt[d_1]{a_1}, \ldots,\sqrt[d_k]{a_k}$, i.e., test whether $f(\sqrt[d_1]{a_1}, \ldots,\sqrt[d_k]{a_k}) = 0$. We place the problem in coNP assuming the Generalised Riemann Hypothesis (GRH), improving on the straightforward PSPACE upper bound obtained by reduction to the existential theory of reals. Next we consider a restricted version, called $2$-RIT, where the radicals are square roots of prime numbers, written in binary. It was known since the work of Chen and Kao that $2$-RIT is at least as hard as the polynomial identity testing problem, however no better upper bound than PSPACE was known prior to our work. We show that $2$-RIT is in coRP assuming GRH and in coNP unconditionally. Our proof relies on theorems from algebraic and analytic number theory, such as the Chebotarev density theorem and quadratic reciprocity.
翻译:我们研究激进身份测试问题(RIT):鉴于一个代表多元体[x_1,\ldots, x_k]$和非负数整数[x_1,\ldots,\ldots, a_k$和$d_1,\ldots, $d_k$, 以二进制写成, 测试多元体细胞是否在真正的基质中消失 $\sqrt[d_1]{a_1},\ldots,\sqrt[d_k]{a_k}$, 即测试美元(sx_ld_1, x_k]$)和非负数($xxxxxx_xxxx_xxx,xxxxxxxxk]$,xxx_k]美元和非负数($d_1,ldot,a_k$xxk$xxxxxxxxxxxxxxxxxxxxxxxxx),
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