11,571 research outputs found

    Additive Property of Drazin Invertibility of Elements

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    In this article, we investigate additive properties of the Drazin inverse of elements in rings and algebras over an arbitrary field. Under the weakly commutative condition of ab=λbaab = \lambda ba, we show that a−ba-b is Drazin invertible if and only if aaD(a−b)bbDaa^{D}(a-b)bb^{D} is Drazin invertible. Next, we give explicit representations of (a+b)D(a+b)^{D}, as a function of a,b,aDa, b, a^{D} and bDb^{D}, under the conditions a3b=baa^{3}b = ba and b3a=abb^{3}a = ab.Comment: 17 page

    Full Diversity Space-Time Block Codes with Low-Complexity Partial Interference Cancellation Group Decoding

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    Partial interference cancellation (PIC) group decoding proposed by Guo and Xia is an attractive low-complexity alternative to the optimal processing for multiple-input multiple-output (MIMO) wireless communications. It can well deal with the tradeoff among rate, diversity and complexity of space-time block codes (STBC). In this paper, a systematic design of full-diversity STBC with low-complexity PIC group decoding is proposed. The proposed code design is featured as a group-orthogonal STBC by replacing every element of an Alamouti code matrix with an elementary matrix composed of multiple diagonal layers of coded symbols. With the PIC group decoding and a particular grouping scheme, the proposed STBC can achieve full diversity, a rate of (2M)/(M+2)(2M)/(M+2) and a low-complexity decoding for MM transmit antennas. Simulation results show that the proposed codes can achieve the full diversity with PIC group decoding while requiring half decoding complexity of the existing codes.Comment: 10 pages, 3 figures

    Validity of single-channel model for a spin-orbit coupled atomic Fermi gas near Feshbach resonances

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    We theoretically investigate a Rashba spin-orbit coupled Fermi gas near Feshbach resonances, by using mean-field theory and a two-channel model that takes into account explicitly Feshbach molecules in the close channel. In the absence of spin-orbit coupling, when the channel coupling gg between the closed and open channels is strong, it is widely accepted that the two-channel model is equivalent to a single-channel model that excludes Feshbach molecules. This is the so-called broad resonance limit, which is well-satisfied by ultracold atomic Fermi gases of 6^{6}Li atoms and 40^{40}K atoms in current experiments. Here, with Rashba spin-orbit coupling we find that the condition for equivalence becomes much more stringent. As a result, the single-channel model may already be insufficient to describe properly an atomic Fermi gas of 40^{40}K atoms at a moderate spin-orbit coupling. We determine a characteristic channel coupling strength gcg_{c} as a function of the spin-orbit coupling strength, above which the single-channel and two-channel models are approximately equivalent. We also find that for narrow resonance with small channel coupling, the pairing gap and molecular fraction is strongly suppressed by SO coupling. Our results can be readily tested in 40^{40}K atoms by using optical molecular spectroscopy.Comment: 6 pages, 6 figure
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