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IMC / 2008 / Problems / Day 2, P12

IMC 2008 · Day 2 · P12

killer

Let H\mathcal{H} be an infinite-dimensional real Hilbert space, let d>0d > 0, and suppose that SS is a set of points (not necessarily countable) in H\mathcal{H} such that the distance between any two distinct points in SS is equal to dd. Show that there is a point yHy \in \mathcal{H} such that {2d(xy):xS}\left\{ \frac{\sqrt{2}}{d} (x - y) : x \in S \right\} is an orthonormal system of vectors in H\mathcal{H}.

Solution (official)

It is clear that, if BB is an orthonormal system in a Hilbert space H\mathcal{H}, then {(d/2)e:eB}\{ (d/\sqrt{2}) e : e \in B \} is a set of points in H\mathcal{H}, any two of which are at distance dd apart. We need to show that every set SS of equidistant points is a translate of such a set.

We begin by noting that if x1,x2,x3,x4Sx_1, x_2, x_3, x_4 \in S are four distinct points, then x2x1,x2x1=d2,x2x1,x3x1=12(x2x12+x3x12x2x32)=d22,x2x1,x4x3=x2x1,x4x1x2x1,x3x1=d22d22=0.\begin{align*} \langle x_2 - x_1, x_2 - x_1 \rangle &= d^2, \\ \langle x_2 - x_1, x_3 - x_1 \rangle &= \tfrac{1}{2} \bigl( \|x_2 - x_1\|^2 + \|x_3 - x_1\|^2 - \|x_2 - x_3\|^2 \bigr) = \tfrac{d^2}{2}, \\ \langle x_2 - x_1, x_4 - x_3 \rangle &= \langle x_2 - x_1, x_4 - x_1 \rangle - \langle x_2 - x_1, x_3 - x_1 \rangle = \tfrac{d^2}{2} - \tfrac{d^2}{2} = 0. \end{align*} This shows that scalar products among vectors which are finite linear combinations of the form λ1x1+λ2x2++λnxn,\lambda_1 x_1 + \lambda_2 x_2 + \dots + \lambda_n x_n, where x1,x2,,xnx_1, x_2, \dots, x_n are distinct points in SS and λ1,λ2,,λn\lambda_1, \lambda_2, \dots, \lambda_n are integers with λ1+λ2++λn=0\lambda_1 + \lambda_2 + \dots + \lambda_n = 0, are universal across all such sets SS in all Hilbert spaces H\mathcal{H}; in particular, we may conveniently evaluate them using examples of our choosing, such as the canonical example above in Rn\mathbb{R}^n. In fact this property trivially follows also when coefficients λi\lambda_i are rational, and hence by continuity any real numbers with sum 0.

If S={x1,x2,,xn}S = \{x_1, x_2, \dots, x_n\} is a finite set, we form x=1n(x1+x2++xn)x = \frac{1}{n}(x_1 + x_2 + \dots + x_n), pick a non-zero vector z[span(x1x,x2x,,xnx)]z \in [\operatorname{span}(x_1 - x, x_2 - x, \dots, x_n - x)]^{\perp} and seek yy in the form y=x+λzy = x + \lambda z for a suitable λR\lambda \in \mathbb{R}. We find that x1y,x2y=x1xλz,x2xλz=x1x,x2x+λ2z2.\langle x_1 - y, x_2 - y \rangle = \langle x_1 - x - \lambda z, x_2 - x - \lambda z \rangle = \langle x_1 - x, x_2 - x \rangle + \lambda^2 \|z\|^2. x1x,x2x\langle x_1 - x, x_2 - x \rangle may be computed by our remark above as x1x,x2x=d22(n1n,1n,1n,,1n) ⁣,(1n,n1n,1n,,1n) ⁣Rn=d22(2(n1)n2+n2n2)=d22n.\langle x_1 - x, x_2 - x \rangle = \frac{d^2}{2} \left\langle \left( \tfrac{n-1}{n}, -\tfrac{1}{n}, -\tfrac{1}{n}, \dots, -\tfrac{1}{n} \right)^{\!\top}, \left( -\tfrac{1}{n}, \tfrac{n-1}{n}, -\tfrac{1}{n}, \dots, -\tfrac{1}{n} \right)^{\!\top} \right\rangle_{\mathbb{R}^n} = \frac{d^2}{2} \left( -\frac{2(n-1)}{n^2} + \frac{n-2}{n^2} \right) = -\frac{d^2}{2n}. So the choice λ=d2nz\lambda = \dfrac{d}{\sqrt{2n}\, \|z\|} will make all vectors 2d(xiy)\frac{\sqrt{2}}{d}(x_i - y) orthogonal to each other; it is easily checked as above that they will also be of length one.

Let now SS be an infinite set. Pick an infinite sequence T={x1,x2,,xn,}T = \{x_1, x_2, \dots, x_n, \dots\} of distinct points in SS. We claim that the sequence yn=1n(x1+x2++xn)y_n = \frac{1}{n} (x_1 + x_2 + \dots + x_n) is a Cauchy sequence in H\mathcal{H}. (This is the crucial observation.) Indeed, for m>nm > n, the norm ymyn\|y_m - y_n\| may be computed by the above remark as ymyn2=d22(1m1n,,1m1n,1m,,1m) ⁣Rm2=d22(n(mn)2m2n2+mnm2)=d22mnmn=d22(1n1m)0,m,n.\|y_m - y_n\|^2 = \frac{d^2}{2} \left\| \left( \tfrac{1}{m} - \tfrac{1}{n}, \dots, \tfrac{1}{m} - \tfrac{1}{n}, \tfrac{1}{m}, \dots, \tfrac{1}{m} \right)^{\!\top} \right\|^2_{\mathbb{R}^m} = \frac{d^2}{2} \left( \frac{n(m-n)^2}{m^2 n^2} + \frac{m-n}{m^2} \right) = \frac{d^2}{2} \cdot \frac{m-n}{mn} = \frac{d^2}{2} \left( \frac{1}{n} - \frac{1}{m} \right) \to 0, \quad m, n \to \infty. By completeness of H\mathcal{H}, it follows that there exists a limit y=limnynH.y = \lim_{n \to \infty} y_n \in \mathcal{H}. We claim that yy satisfies all conditions of the problem. For m>n>pm > n > p, with n,pn, p fixed, we compute xnym2=d22(1m,,1m,11m,1m,,1m) ⁣Rm2=d22(m1m2+(m1)2m2)=d22m1md22,m,\|x_n - y_m\|^2 = \frac{d^2}{2} \left\| \left( -\tfrac{1}{m}, \dots, -\tfrac{1}{m}, 1 - \tfrac{1}{m}, -\tfrac{1}{m}, \dots, -\tfrac{1}{m} \right)^{\!\top} \right\|^2_{\mathbb{R}^m} = \frac{d^2}{2} \left( \frac{m-1}{m^2} + \frac{(m-1)^2}{m^2} \right) = \frac{d^2}{2} \cdot \frac{m-1}{m} \to \frac{d^2}{2}, \quad m \to \infty, showing that xny=d/2\|x_n - y\| = d/\sqrt{2}, as well as xnym,xpym=d22(m2m22m(11m))=d22m0,m,\langle x_n - y_m, x_p - y_m \rangle = \frac{d^2}{2} \left( \frac{m-2}{m^2} - \frac{2}{m} \left( 1 - \frac{1}{m} \right) \right) = -\frac{d^2}{2m} \to 0, \quad m \to \infty, showing that xny,xpy=0\langle x_n - y, x_p - y \rangle = 0, so that {2d(xny):nN}\left\{ \frac{\sqrt{2}}{d} (x_n - y) : n \in \mathbb{N} \right\} is indeed an orthonormal system of vectors.

This completes the proof in the case when T=ST = S, which we can always take if SS is countable. If it is not, let x,xx', x'' be any two distinct points in STS \setminus T. Then applying the above procedure to the set T={x,x,x1,x2,,xn,}T' = \{x', x'', x_1, x_2, \dots, x_n, \dots\} it follows that the limit y=limnx+x+x1+x2++xnn+2=limnx1+x2++xnn=yy = \lim_{n \to \infty} \frac{x' + x'' + x_1 + x_2 + \dots + x_n}{n + 2} = \lim_{n \to \infty} \frac{x_1 + x_2 + \dots + x_n}{n} = y satisfies that {2d(xy),2d(xy)}{2d(xny):nN}\left\{ \frac{\sqrt{2}}{d} (x' - y), \frac{\sqrt{2}}{d} (x'' - y) \right\} \cup \left\{ \frac{\sqrt{2}}{d} (x_n - y) : n \in \mathbb{N} \right\} is still an orthonormal system.

This it true for any distinct x,xSTx', x'' \in S \setminus T; it follows that the entire system {2d(xy):xS}\left\{ \frac{\sqrt{2}}{d} (x - y) : x \in S \right\} is an orthonormal system of vectors in H\mathcal{H}, as required.

How the field did

contestants scored
255
average (of 20)
1.39
solved (≥ 80%)
3.9%
near-0 (≤ 10%)
90.2%
discrimination
0.45

Score distribution (field cohort)

Computed on contestants with a meaningful total (field cohort); discrimination is the corrected item–total correlation.

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