Number Theory 705Hence
[(
p− 1
2
)
!
] 2
≡− 1 (modp),as desired.
To show that the equation has no solution ifp≡ 3 (mod 4), assume that such a
solution exists. Call ita. Using Fermat’s little theorem, we obtain
1 ≡ap−^1 ≡a^2 ·p− 21
≡(− 1 )p− 21
=− 1 (modp).This is impossible. Hence the equation has no solution.
773.Multiplying the obvious congruences
1 ≡−(p− 1 )(modp),
2 ≡−(p− 2 )(modp),
···
n− 1 ≡−(p−n+ 1 )(modp),we obtain
(n− 1 )!≡(− 1 )n−^1 (p− 1 )(p− 2 )···(p−n+ 1 )(modp).Multiplying both sides by(p−n)!further gives
(p−n)!(n− 1 )!≡(− 1 )n−^1 (p− 1 )!(modp).Because by Wilson’s theorem(p− 1 )!≡− 1 (modp), this becomes
(p−n)!(n− 1 )!≡(− 1 )n(modp),as desired.
(A. Simionov)
774.Because the common difference of the progression is not divisible byp, the numbers
a 1 ,a 2 , ..., aprepresent different residue classes modulop. One of them, sayai,is
divisible byp, and the others give the residues 1, 2 ,...,p−1 in some order. Applying
Wilson’s theorem, we have
a 1 a 2 ···ap
ai≡(p− 1 )!≡− 1 (modp);hencea 1 a 2 ···aapi+1 is divisible byp. Sinceaiis divisible byp, we find thata 1 a 2 ···ap+
aiis divisible byp^2 , as desired.
(I. Cucurezeanu)