581 research outputs found
Some Constructions for Amicable Orthogonal Designs
Hadamard matrices, orthogonal designs and amicable orthogonal designs have a
number of applications in coding theory, cryptography, wireless network
communication and so on. Product designs were introduced by Robinson in order
to construct orthogonal designs especially full orthogonal designs (no zero
entries) with maximum number of variables for some orders. He constructed
product designs of orders , and and types and ,
respectively. In this paper, we first show that there does not exist any
product design of order , , and type where the notation is used to show that repeats
times. Then, following the Holzmann and Kharaghani's methods, we construct some
classes of disjoint and some classes of full amicable orthogonal designs, and
we obtain an infinite class of full amicable orthogonal designs. Moreover, a
full amicable orthogonal design of order and type is constructed.Comment: 12 pages, To appear in the Australasian Journal of Combinatoric
Square Complex Orthogonal Designs with Low PAPR and Signaling Complexity
Space-Time Block Codes from square complex orthogonal designs (SCOD) have
been extensively studied and most of the existing SCODs contain large number of
zero. The zeros in the designs result in high peak-to-average power ratio
(PAPR) and also impose a severe constraint on hardware implementation of the
code when turning off some of the transmitting antennas whenever a zero is
transmitted. Recently, rate 1/2 SCODs with no zero entry have been reported for
8 transmit antennas. In this paper, SCODs with no zero entry for transmit
antennas whenever is a power of 2, are constructed which includes the 8
transmit antennas case as a special case. More generally, for arbitrary values
of , explicit construction of rate SCODs
with the ratio of number of zero entries to the total number of entries equal
to is reported,
whereas for standard known constructions, the ratio is . The
codes presented do not result in increased signaling complexity. Simulation
results show that the codes constructed in this paper outperform the codes
using the standard construction under peak power constraint while performing
the same under average power constraint.Comment: Accepted for publication in IEEE Transactions on Wireless
Communication. 10 pages, 6 figure
Free nilpotent and -type Lie algebras. Combinatorial and orthogonal designs
The aim of our paper is to construct pseudo -type algebras from the
covering free nilpotent two-step Lie algebra as the quotient algebra by an
ideal. We propose an explicit algorithm of construction of such an ideal by
making use of a non-degenerate scalar product. Moreover, as a bypass result, we
recover the existence of a rational structure on pseudo -type algebras,
which implies the existence of lattices on the corresponding pseudo -type
Lie groups. Our approach substantially uses combinatorics and reveals the
interplay of pseudo -type algebras with combinatorial and orthogonal
designs. One of the key tools is the family of Hurwitz-Radon orthogonal
matrices
Constructions for orthogonal designs using signed group orthogonal designs
Craigen introduced and studied signed group Hadamard matrices extensively and
eventually provided an asymptotic existence result for Hadamard matrices.
Following his lead, Ghaderpour introduced signed group orthogonal designs and
showed an asymptotic existence result for orthogonal designs and consequently
Hadamard matrices. In this paper, we construct some interesting families of
orthogonal designs using signed group orthogonal designs to show the capability
of signed group orthogonal designs in generation of different types of
orthogonal designs.Comment: To appear in Discrete Mathematics (Elsevier). No figure
Twin bent functions, strongly regular Cayley graphs, and Hurwitz-Radon theory
The real monomial representations of Clifford algebras give rise to two
sequences of bent functions. For each of these sequences, the corresponding
Cayley graphs are strongly regular graphs, and the corresponding sequences of
strongly regular graph parameters coincide. Even so, the corresponding graphs
in the two sequences are not isomorphic, except in the first 3 cases. The proof
of this non-isomorphism is a simple consequence of a theorem of Radon.Comment: 13 pages. Addressed one reviewer's questions in the Discussion
section, including more references. Resubmitted to JACODES Math, with updated
affiliation (I am now an Honorary Fellow of the University of Melbourne
- …