Graph theory characterizes planar-connected beyond-diagonal RIS architectures realizable on double-layer PCBs and identifies those with the maximum number of degrees of freedom.
A tutorial on beyond-diagonal reconfig- urable intelligent surfaces: Modeling, architectures, system design and optimization, and applications
3 Pith papers cite this work. Polarity classification is still indexing.
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UNVERDICTED 3representative citing papers
NR-BD-RIS on LEO satellites breaks channel reciprocity to support simultaneous multi-user full-duplex beams, yielding higher DL/UL sum-rates than conventional RIS with less frequent reconfiguration.
BD-RIS in secure ISAC networks improves the secrecy-sensing trade-off by jointly optimizing the scattering matrix, beamforming, and artificial noise to maximize per-target reflected power under power and secrecy constraints.
citing papers explorer
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Low-Complexity Planar Beyond-Diagonal RIS Architecture Design Using Graph Theory
Graph theory characterizes planar-connected beyond-diagonal RIS architectures realizable on double-layer PCBs and identifies those with the maximum number of degrees of freedom.
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Enabling Full-Duplex LEO Satellite Systems with Non-Reciprocal BD-RIS-Assisted Beamforming
NR-BD-RIS on LEO satellites breaks channel reciprocity to support simultaneous multi-user full-duplex beams, yielding higher DL/UL sum-rates than conventional RIS with less frequent reconfiguration.
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Beyond-Diagonal RIS For Enhanced Secrecy and Sensing Gains in Secure ISAC Networks: An Optimization Framework
BD-RIS in secure ISAC networks improves the secrecy-sensing trade-off by jointly optimizing the scattering matrix, beamforming, and artificial noise to maximize per-target reflected power under power and secrecy constraints.