Random Access: An Information-Theoretic Perspective

This paper considers a random access system where each sender is in one of two possible states, active or not active, and the states are only known to the common receiver. Active senders encode data into independent information streams, a subset of which is decoded depending on the collective interf...

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Bibliographic Details
Published in:IEEE transactions on information theory 2012-02, Vol.58 (2), p.909-930
Main Authors: Minero, P., Franceschetti, M., Tse, D. N. C.
Format: Article
Language:English
Subjects:
Access methods and protocols, osi model
Additives
Applied sciences
Broadcast approach
capacity
Channel models
Channels
Coding, codes
Decoding
Encoding
Exact sciences and technology
Gaussian
Infinity
Information theory
Information, signal and communications theory
Messages
multiple-access channels
network information theory
Normal distribution
Optimization
Probability
Radiocommunications
Random access
Receivers
Signal and communications theory
slotted ALOHA
Streams
Symmetry
Telecommunications
Telecommunications and information theory
Teleprocessing networks. Isdn
Throughput
Transmitters
Transmitters. Receivers
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Summary:This paper considers a random access system where each sender is in one of two possible states, active or not active, and the states are only known to the common receiver. Active senders encode data into independent information streams, a subset of which is decoded depending on the collective interference. An information-theoretic formulation of the problem is presented and the set of achievable rates is characterized with a guaranteed gap to optimality. Inner and outer bounds on the capacity region of a two-sender system are tight in the case of a binary-expansion deterministic channel and differ by less than one bit in the case of a Gaussian channel. In systems with an arbitrary number of senders, the symmetric scenario of equal access probabilities and received power constraints is studied and the system throughput, i.e., the maximum achievable expected sum rate, is characterized. It is shown that a simple coding scheme where active senders transmit a single message is optimum for a binary-expansion deterministic channel and achieves within one bit of the optimum in the case of a Gaussian channel. Finally, a comparison with the slotted ALOHA protocol is provided, showing that encoding rate adaptation at the transmitters achieves constant (rather than zero) throughput as the number of users tends to infinity.
ISSN:0018-9448
1557-9654
DOI:10.1109/TIT.2011.2173711