2023
DOI: 10.1109/tcomm.2023.3255907
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A Dominant Interferer Plus Mean Field-Based Approximation for SINR Meta Distribution in Wireless Networks

Abstract: This paper proposes a novel approach for computing the meta distribution of the signal-to-interferenceplus-noise ratio (SINR) for the downlink transmission in a wireless network with Rayleigh fading.The novel approach relies on an approximation mix of exact and mean-field analysis of interference (dominant interferer-based approximation) to reduce the complexity of analysis and enhance tractability.In particular, the proposed approximation omits the need to compute the first or the second moment of the SINR th… Show more

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Cited by 8 publications
(5 citation statements)
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“…λ T (r Ω (ω, β) ω −α+1 dβ dω. By recalling the expressions of f Z1 (z 1 ) from Corollary 2 and F Z0|Z1 (z 0 |z 1 ) from Corollary 5, the dominant-interferer-based approximation of the SINR meta distribution [24] can be computed as (23) where…”
Section: Sinr Meta Distributionmentioning
confidence: 99%
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“…λ T (r Ω (ω, β) ω −α+1 dβ dω. By recalling the expressions of f Z1 (z 1 ) from Corollary 2 and F Z0|Z1 (z 0 |z 1 ) from Corollary 5, the dominant-interferer-based approximation of the SINR meta distribution [24] can be computed as (23) where…”
Section: Sinr Meta Distributionmentioning
confidence: 99%
“…Then, recalling that Z 0 < Z 1 , the dominant-interfererbased approximation of the SINR meta distribution can be obtained as [24] FPc (γ) = P(P c > γ)…”
Section: Appendix D Proof Of Theoremmentioning
confidence: 99%
“…Since the typical IU transmitter is located at the center of a circular network area and each IU in this network follows uniformly i.i.d., the probability density function of l can be given by f l (l) = 2πl πR 2 = 2l R 2 [18], where R is the radius of the circular network area and 0 < l ≤ R.…”
Section: A Sensing Performance Analysismentioning
confidence: 99%
“…Let r denote the distance between the typical IU receiver and an IU transmitter. Since the receiver is located at the center of a circular area and each transmitter follows an independent and identical uniform distribution, the probability density function of r is given by f r (r) = 2πr πR 2 = 2r R 2 [18] . From the definition of the probability of coverage P C in Section II-C, we obtain P C (ζ c ) as [16],…”
Section: B Communication Performance Analysismentioning
confidence: 99%
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