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Managing Interference Correlation Through Random Medium Access

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arxiv 1304.1851 v2 pith:USAPQSCY submitted 2013-04-06 cs.NI cs.ITmath.IT

Managing Interference Correlation Through Random Medium Access

classification cs.NI cs.ITmath.IT
keywords localdelayinterferencemeancorrelationaccessalohaevaluate
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The capacity of wireless networks is fundamentally limited by interference. However, little research has focused on the interference correlation, which may greatly increase the local delay (namely the number of time slots required for a node to successfully transmit a packet). This paper focuses on the question that whether increasing randomness in the MAC, such as frequency-hopping multiple access (FHMA) and ALOHA, helps to reduce the effect of interference correlation. We derive closed-form results for the mean and variance of the local delay for the two MAC protocols and evaluate the optimal parameters that minimize the mean local delay. Based on the optimal parameters, we propose the definitions of two operation regimes: correlation-limited regime and bandwidth-limited regime. Our results reveal that while the mean local delays for FHMA with N sub-bands and for ALOHA with transmit probability p are the same when p=1/N with thermal noise ignored, significant difference exists between the variances. At last, we evaluate the mean delay-jitter tradeoff and the bounds on the tail probability of the local delay, which shed key insights into the system design.

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