Fluid antenna systems and rate-splitting multiple access mutually strengthen each other to deliver better spectral efficiency and interference handling than fixed-antenna baselines in 6G scenarios.
FARS: Elevating rate-splitting multiple access in non-territorial networks with intelligent fluid antenna system
2 Pith papers cite this work. Polarity classification is still indexing.
2
Pith papers citing it
years
2026 2verdicts
UNVERDICTED 2representative citing papers
Dynamic lane allocation in UAM corridors via MILP increases mean lane utilization to 67% and reduces mean travel time by up to 21.6% versus static baselines in a San Francisco Bay Area simulation.
citing papers explorer
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Fluid Antennas Meet Rate-Splitting Multiple Access: A New Path Forward for 6G Networks
Fluid antenna systems and rate-splitting multiple access mutually strengthen each other to deliver better spectral efficiency and interference handling than fixed-antenna baselines in 6G scenarios.
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Dynamic Lane Allocation in UAM Corridors for Efficient Multimodal Door-to-Door Mobility
Dynamic lane allocation in UAM corridors via MILP increases mean lane utilization to 67% and reduces mean travel time by up to 21.6% versus static baselines in a San Francisco Bay Area simulation.