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.
Towards atomic MIMO receivers
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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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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.