Rotatable antenna arrays with joint optimization of pose and boresights achieve higher weighted sum-rates than fixed-array or single-adjustment baselines by enhancing channel orthogonality and gain alignment.
MIMO capacity characterization for movable antenna systems
4 Pith papers cite this work. Polarity classification is still indexing.
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eess.SP 4years
2026 4verdicts
UNVERDICTED 4representative citing papers
The CEBAP design optimizes slow movable antenna positions using cell-specific long-term APS to maximize ergodic system utility with reduced overhead.
A three-stage GNN jointly optimizes PA placement, RIS phases, beamforming and associations to maximize sum rate and energy efficiency in multi-BS multi-RIS pinching-antenna systems.
Movable-antenna array zooming fuses multi-measurement observations to mitigate aliasing in sparse near-field localization and optimizes configurations to suppress false peaks.
citing papers explorer
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Beyond Beamforming: Phase-and-Gain Channel Shaping via Rotatable Antenna Arrays
Rotatable antenna arrays with joint optimization of pose and boresights achieve higher weighted sum-rates than fixed-array or single-adjustment baselines by enhancing channel orthogonality and gain alignment.
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Slow Movable Antenna System Design Based on Cell-Specific Long-Term Angular Power Spectrum
The CEBAP design optimizes slow movable antenna positions using cell-specific long-term APS to maximize ergodic system utility with reduced overhead.
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Spectral- and Energy-efficient Multi-BS Multi-RIS Pinching-antenna Systems: A GNN-based Approach
A three-stage GNN jointly optimizes PA placement, RIS phases, beamforming and associations to maximize sum rate and energy efficiency in multi-BS multi-RIS pinching-antenna systems.
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Array Zooming Optimization for Near-Field Localization With Movable Antennas
Movable-antenna array zooming fuses multi-measurement observations to mitigate aliasing in sparse near-field localization and optimizes configurations to suppress false peaks.