A new complex baseband model for Rydberg atomic quantum receivers captures signal-dependent shot noise, reveals an operating-point gain-noise tradeoff, and shows MIMO superiority over RF-MIMO requires the quantum noise floor to be lower.
RIS-assisted atomic MIMO receiver
3 Pith papers cite this work. Polarity classification is still indexing.
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The paper develops a receiver-induced channel shaping method using FRIS to minimize quadrature leakage in Rydberg atomic MIMO systems, achieving better bit-error rates than conventional designs.
Stochastic geometry analysis of Rydberg quantum receiver arrays shows performance advantage over conventional receivers in sparse deployments that reverses in dense deployments due to nonlinearity.
citing papers explorer
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Signal-Dependent Shot Noise Modeling of Rydberg Atomic Quantum Receivers: A Design Perspective
A new complex baseband model for Rydberg atomic quantum receivers captures signal-dependent shot noise, reveals an operating-point gain-noise tradeoff, and shows MIMO superiority over RF-MIMO requires the quantum noise floor to be lower.
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Toward a Receiver-Induced Channel Shaping Paradigm: FRIS-Assisted Rydberg Atomic MIMO with Quadrature-Leakage-Aware Design
The paper develops a receiver-induced channel shaping method using FRIS to minimize quadrature leakage in Rydberg atomic MIMO systems, achieving better bit-error rates than conventional designs.
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Coverage Analysis of Rydberg Atom Quantum Receiver Arrays: A Stochastic Geometry Approach
Stochastic geometry analysis of Rydberg quantum receiver arrays shows performance advantage over conventional receivers in sparse deployments that reverses in dense deployments due to nonlinearity.