664 Geometry and TrigonometryAnd this is Jensen’s inequality applied to the tangent function, which is convex on( 0 ,π 2 ).
682.From the first equation, it follows that ifxis 0, then so isy, makingx^2 indeterminate;
hencex, and similarlyyandz, cannot be 0. Solving the equations, respectively, fory,z,
andx, we obtain the equivalent systemy=
3 x−x^3
1 − 3 x^2,
z=3 y−y^3
1 − 3 y^2,
x=
3 z−z^3
1 − 3 z^2,
wherex, y, zare real numbers different from 0.
There exists a unique numberuin the interval(−π 2 ,π 2 )such thatx=tanu. Theny=3 tanu−tan^3 u
1 −3 tan^2 u=tan 3u,z=
3 tan 3u−tan^33 u
1 −3 tan^23 u=tan 9u,x=3 tan 9u−tan^39 u
1 −3 tan^29 u=tan 27u.The last equality yields tanu=tan 27u,souand 27udiffer by an integer multiple ofπ.
Therefore,u=kπ 26 for someksatisfying−π 2 <kπ 26 <π 2. Besides,kmust not be 0, since
x =0. Hence the possible values ofkare± 1 ,± 2 ,...,± 12 ,each of them generating
the corresponding triplex=tan
kπ
26,y=tan
3 kπ
26,z=tan
9 kπ
26.
It is immediately checked that all of these triples are solutions of the initial system.
683.In the case of the sequence(an)n, the innermost square root suggests one of the
substitutionsan=2 sintnoran=2 costn, withtn∈[ 0 ,π 2 ],n≥0. It is the first choice
that allows a further application of a half-angle formula:2 sintn+ 1 =an+ 1 =√
2 −
√
4 −4 sin^2 tn=√
2 −2 costn=2 sintn
2.
It follows thattn+ 1 = t 2 n, which combined witht 0 =π 4 givestn = 2 nπ+ 2 forn≥0.
Therefore,an=2 sin 2 nπ+ 2 forn≥0.
For(bn)n, the innermost square root suggests a trigonometric substitution as well,
namelybn=2 tanun,n≥0. An easy induction shows that the sequence(bn)nis positive,
so we can chooseun∈[ 0 ,π 2 ). Substituting in the recursive formula, we obtain