NOTATION: $P(x)$ stands for the product of all primes which do not exceed real $x$; e.g. $P(10)=210$.
QUESTION: Given any real $x\ge 3$, compute or estimate the smallest natural number $n:=n(x)\ge 3$ such the remainder of the division of $n$ by any odd prime $p\le x$ is $1$ or $2$ (it may be any combination of $1$s and $2$s).
In particular, improve upon my simple theorem below, and still better upon its consecutive improvements provided by the MO participants.
THEOREM $$ n(x)\ > \ \left\lceil\sqrt{P(x)}\right\rceil + 1 $$
EXAMPLEs (small calculations):
- $n(3) = 4$
- $n(5) = 7$
- $n(7) = 16$
REMARK (warning): First I talk about all primes (see NOTATION), then about odd primes (see QUESTION).
PROOF of the THEOREM
PROOF of the THEOREM
Let integer $n\ge 3$ be such that all mentioned remainders are $1$ or $2$. Let $A$ be the product of all odd primes $p\le x$ for which $n=1\mod p$, and $B$ be the same for remainder $2$. Thus $A|n-1$ and $B|n-2$, henceand
$$A\cdot B\ =\ \frac{P(x)}2 $$
Furthermore, $2|n-1$ or $2|n-2$, hence $A'|n-1$ and $B'|n-2$ for certain natural numbers such that
$$ A'\cdot B'\ =\ P(x) $$
It follows that
$$ n\ \ \ge\ \ \max(A'\ B') + 1$$
while
$$ \max(A'\ B')\ \ \ge\ \ \left\lceil\sqrt{A'\cdot B'}\right\rceil\ \ =\ \ \left\lceil\sqrt{P(x)}\right\rceil $$
This proves the required inequality:
$$ n\ \ \ge\ \ \left\lceil\sqrt{P(x)}\right\rceil + 1 $$