Equiangular tight frames from group divisible designs

Fickus, Matthew; Jasper, John

doi:10.1007/s10623-018-0569-z

Cited by 8 publications

(22 citation statements)

References 55 publications

(203 reference statements)

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“…3 ) yields real TFF(D, 3, R) with R = D 2 and R = 2D 3 , respectively. From this result, we see that only ever at most a small portion of an orbit of the form (16) or (17) will correspond to actual TFFs. In particular, the parameters of any TFF(D, 2, R) appear in one of two types of "Naimark-spatial paths" of length two:…”

mentioning

confidence: 87%

“…Their (D ′ , R ′ ) parameters are obtained by moving horizontally or vertically, respectively, from (D, R) to another point on this hyperbola. Interestingly, the path from (3, 1) to (4, 1) to (4, 3) to (17,3), etc., (alternating complements, beginning with Naimark) "interweaves" with that from (3, 1) to (3,2) to (11,2) to (11,9), etc., (alternating complements, beginning with spatial). From this graph, it is clear that Orb(3, 7, 1) is infinite and moreover contains a unique point (D 0 , 7, R 0 ) such that D 0 ≤ D and R 0 ≤ R for all (D, 7, R) ∈ Orb(3, 7, 1), namely (D 0 , 7, R 0 ) = (3, 7, 1).…”

Section: Naimark-spatial Orbits Whenmentioning

confidence: 99%

“…In either case, a trivial real TFF(D, N, R) exists. Similarly if N = 3 and R 0 = D 0 3 then (17) gives that Orb(3R 0 , 3, R 0 ) is {(3R 0 , 3, R 0 ), (0, 3, R 0 ), (0, 3, −R 0 ), (−3R 0 , 3, −R 0 ), (−3R 0 , 3, −2R 0 ), (3R 0 , 3, 2R 0 )}, implying (D, N, R) is either (3R 0 , 3, R 0 ) or (3R 0 , 3, 2R 0 ), and so by Theorem 3.2 that a real TFF(D, N, R) exists. When N = 3 and R 0 = D 0 , (17) instead gives that Orb(R 0 , 3, R 0 ) is n=1 is a TFF(2R, 4, R) for R 2R .…”

Section: The Existence Of Real Tffsmentioning

confidence: 99%

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Certifying the novelty of equichordal tight fusion frames

Fickus,

Mayo,

Watson

2021

Preprint

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An equichordal tight fusion frame (ECTFF) is a finite sequence of equi-dimensional subspaces of a finite-dimensional Hilbert space that achieves equality in Conway, Hardin and Sloane's simplex bound. Every ECTFF is a type of optimal Grassmannian code, being a way to arrange a given number of members of a Grassmannian so that the minimal chordal distance between any pair of them is as large as possible. Any nontrivial ECTFF has both a Naimark complement and spatial complement which themselves are ECTFFs. It turns out that whenever the number of subspaces is at least five, taking iterated alternating Naimark and spatial complements of one ECTFF yields an infinite family of them with distinct parameters. This makes it challenging to certify the novelty of any recently discovered ECTFF: how can one guarantee that it does not arise from any previously known construction in such a Naimark-spatial way? In this paper, we propose a solution to this problem, showing that any ECTFF is a member of a Naimark-spatial family originating from either a trivial ECTFF or one with unique "minimal" parameters. In the latter case, if its minimal parameters do not match those of any previously known ECTFF, it is certifiably new. As a proof of concept, we then use these ideas to certify the novelty of some ECTFFs arising from a new method for constructing them from difference families for finite abelian groups. This method properly generalizes King's construction of ECTFFs from semiregular divisible difference sets.

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mentioning

confidence: 87%

Section: Naimark-spatial Orbits Whenmentioning

confidence: 99%

Section: The Existence Of Real Tffsmentioning

confidence: 99%

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Certifying the novelty of equichordal tight fusion frames

Fickus,

Mayo,

Watson

2021

Preprint

Self Cite

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“…For example, one may use strongly regular graphs to obtain optimal codes in Gr(1, R d ) [66], or use Steiner systems to obtain optimal codes in Gr(1, C d ) [28]. In this spirit, several infinite families of optimal codes have been constructed from combinatorial designs [40,44,27,24,25,23,20,29,19]. In some cases, it is even possible to construct optimal codes from smaller codes [5,63,6,43].…”

Section: Introductionmentioning

confidence: 99%

Testing isomorphism between tuples of subspaces

King¹,

Mixon²,

Waldron³

2021

Preprint

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Given two tuples of subspaces, can you tell whether the tuples are isomorphic? We develop theory and algorithms to address this fundamental question. We focus on isomorphisms in which the ambient vector space is acted on by either a unitary group or general linear group. If isomorphism also allows permutations of the subspaces, then the problem is at least as hard as graph isomorphism. Otherwise, we provide a variety of polynomial-time algorithms to test for isomorphism.

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“…Meanwhile, Steiner ETFs arise from balanced incomplete block designs [26,25]. This construction has recently been generalized to yield new infinite families of ETFs arising from projective planes that contain hyperovals, Steiner triple systems, and group divisible designs [24,21,19].…”

mentioning

confidence: 99%

Harmonic equiangular tight frames comprised of regular simplices

Fickus

Schmitt

2020

Linear Algebra and its Applications

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An equiangular tight frame (ETF) is a sequence of unit-norm vectors in a Euclidean space whose coherence achieves equality in the Welch bound, and thus yields an optimal packing in a projective space. A regular simplex is a simple type of ETF in which the number of vectors is one more than the dimension of the underlying space. More sophisticated examples include harmonic ETFs which equate to difference sets in finite abelian groups. Recently, it was shown that some harmonic ETFs are comprised of regular simplices. In this paper, we continue the investigation into these special harmonic ETFs. We begin by characterizing when the subspaces that are spanned by the ETF's regular simplices form an equi-isoclinic tight fusion frame (EITFF), which is a type of optimal packing in a Grassmannian space. We shall see that every difference set that produces an EITFF in this way also yields a complex circulant conference matrix. Next, we consider a subclass of these difference sets that can be factored in terms of a smaller difference set and a relative difference set. It turns out that these relative difference sets lend themselves to a second, related and yet distinct, construction of complex circulant conference matrices. Finally, we provide explicit infinite families of ETFs to which this theory applies.

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Equiangular tight frames from group divisible designs

Cited by 8 publications

References 55 publications

Certifying the novelty of equichordal tight fusion frames

Certifying the novelty of equichordal tight fusion frames

Testing isomorphism between tuples of subspaces

Harmonic equiangular tight frames comprised of regular simplices

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