Corrigendum to “Determining a sound-soft polyhedral scatterer by a single far-field measurement” 6 0 0 Giovanni Alessandrini and Luca Rondi 2 [email protected] [email protected] n Dipartimento di Matematica e Informatica a J Universit`a degli Studi di Trieste, Italy 7 1 In the paper, [1], on the determination of a sound-soft polyhedral scatterer ] P by a single far-fieldmeasurement,the proofofProposition3.2 is incomplete. In A this corrigendumweprovidea newproofofthesamepropositionwhichfills the . previous gap. In order to introduce it, we recall some definitions from [1]. h t Let v be a nontrivial real valued solution to the Helmholtz equation a m (1) ∆v+k2v =0 in G, [ in a connected open set G⊂RN, N ≥2. We denote the nodal set of v as 1 v N ={x∈G: v(x)=0} 6 v 0 4 and we let Cv be the set of nodal critical points, that is 1 0 C ={x∈G: v(x)=0 and ∇v(x)=0}. v 6 0 We say that Σ ⊂ N is a regular portion of N if it is an analytic open and v v / h connectedhypersurfacecontainedinNv\Cv.LetusdenotebyA1,A2,...,An,... t the nodal domains of v in G, that is the connected components of {x ∈ G : a m v(x)6=0}=G\Nv. Let us recall the statement of Proposition 3.2 in [1]. : v Proposition 3.2 ([1]) We can order the nodal domains A ,A ,...,A ,... in 1 2 n Xi such a way that for any j ≥2 there exist i, 1≤i<j, and a regular portion Σj of N such that r v a (2) Σ ⊂∂A ∩∂A . j i j The gap in the proof given in [1] stands in the fact that the ordering A ,A ,...,A ,... obtained with that method might not ensure that all the 1 2 n nodal domains are contained in the sequence. We base the new proof on the following theorem. Theorem 1 The set C has Hausdorff dimension not exceeding N −2. v 1 Aproofcanbefoundin[5,Theorem2.1].Furtherdevelopmentsofthetheory on the structure of zero sets of solutions to elliptic equations can be found, for instance, in [2, 3] and in their references. Let G′ = G\C . By the property of C described in the previous theorem, v v andbyusing[4,ChapterVII, Section4]and[4,TheoremIV4,Corollary2],we can conclude that G′ is an open and connected set. We also remark that, for everyx∈N \C ,there areexactly twonodaldomains,AandB, ofv suchthat v v x ∈ ∂A∩∂B. Finally, let us note that the nodal domains of v in G coincide with the nodal domains of v in G′. We shall also make use of the following elementary lemma. Lemma 2 For any connected open set G ⊂ RN, there exists an increasing sequence {G }∞ of bounded, connected open sets such that G = S∞ G m m=1 m=1 m and G ⊂⊂G for every m. m Proof. For every k =1,2,..., we denote D ={x∈G: dist(x,∂G)>1/k, |x|<k}. k Let us assume, without loss of generality, that D 6= ∅ and let us fix y ∈ D . 1 1 For every x ∈ D , let γ be a path in G joining y to x. For every h > 0, let k x Uh = {z ∈ RN : dist(z,γ ) < h}. We obviously have that Uh is a connected x x x h(x) h(x) open set. Let h(x)>0 be such that U ⊂⊂G. We have that {U } is x x x∈Dk anopencoveringofthe compactsetD .Therefore,we canfindx ,...,x ∈D k 1 l k such that D ⊂ Sl Uh(xj). We observe that E = Sl Uh(xj) is an open k j=1 xj k j=1 xj connected set such that D ⊂E ⊂⊂G. Therefore the lemma follows choosing k k G =Sm E . (cid:3) m k=1 k Proof of Proposition 3.2. We apply Lemma 2 to the connected set G′ = G\C . We choose A such that A ∩G 6=∅ and we proceed by induction. v 1 1 1 Let us assume that we have ordered A ,...,A in such a way that there 1 n exist Σ ,...,Σ regular portions of N such that (2) holds for any j =2,...,n 2 n v and for some i<j. ◦ Let Aˆ =A ∪...∪A . If G′\Aˆ = ∅, then we are done. Otherwise, let n 1 n n m ≥ 1 be the smallest number such that G \Aˆ 6= ∅. Since G is connected, m n m we can find y ∈ ∂Aˆ ∩ G and r > 0 such that B (y) ∩ ∂Aˆ is a regular n m r n portionofN andthereexistexactlytwonodaldomains,A˜ ⊂Aˆ andA˜ with v 1 n 2 A˜ ∩Aˆ =∅,whoseintersectionswithB (y)arenotempty.Clearly,A˜ coincides 2 n r 1 withA ,forsomei=1,...,n,andifwepickA =A˜ andΣ =B (y)∩N , i n+1 2 n+1 r v then (2) holds for j =n+1, too. If G contains only finitely many nodal domains, then we can iterate this constructionandafterafinitenumberofstepswerecoverallthenodaldomains, thatisfor somel∈NwehaveG′\Aˆ =∅ andwearedone.Otherwise,we argue l in the following way. Since G is contained in G′, for every x ∈ G there m m is a neighbourhood of x intersecting at most two different nodal domains. By compactness,weobtainthatG intersectsatmostfinitelymanydifferentnodal m domains. Hence, if we iterate the previous construction, after a finite number of steps we find l ∈ N such that G \Aˆ = ∅. By repeating the argument for m l the smallest m′ > m such that Gm′\Aˆl 6= ∅, we conclude that for any m ∈ N there exists l ∈ N such that G \Aˆ = ∅. Therefore the infinite sequence {A } m l i comprises all the nodal domains of v in G. (cid:3) 2 Acknowledgements The authors wish to express their gratitude to Hongyu Liu and Jun Zou for pointing out to them the gap in the proof of Proposition 3.2 in [1] and for kindly sending them their preprint [6]. References [1] G. Alessandrini and L. Rondi, Determining a sound-soft polyhedral scat- terer by a single far-field measurement,Proc.Amer.Math.Soc.133(2005), pp. 1685–1691. [2] Q. Han, R. Hardt and F. Lin, Geometric measure of singular sets of elliptic equations, Comm. Pure Appl. Math. 51 (1998), pp. 1425–1443. [3] R.Hardt,M.Hoffmann-Ostenhof,T.Hoffmann-OstenhofandN.Nadirashvi- li,Critical sets of solutions to elliptic equations,J.DifferentialGeometry 51 (1999), pp. 359–373. [4] W. Hurewicz and H. Wallman, Dimension Theory, Princeton University Press, Princeton N.J., 1948. [5] F.-H. Lin,Nodal sets of solutions of elliptic and parabolic equations,Comm. Pure Appl. Math. 44 (1991), pp. 287–308. [6] H. Liu and J. Zou, Uniqueness in an inverse acoustic obstacle scattering problem for both sound-hard and sound-soft polyhedral scatterers, preprint (2005). 3