Dynamic Preamble Subset Allocation for RAN Slicing in 5G Networks

Dynamic Preamble Subset Allocation for RAN Slicing in 5G Networks

The random access (RA) mechanism of Long Term Evolution (LTE) networks is prone to congestion when a large number of devices attempt RA simultaneously, due to the limited set of preambles. If each RA attempt is made by means of transmission of multiple consecutive preambles (codewords) picked from a...

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Bibliographic Details
Published in:IEEE access Vol. 6; pp. 13015 - 13032
Main Authors: Vural, Serdar, Wang, Ning, Bucknell, Paul, Foster, Gerard, Tafazolli, Rahim, Muller, Julien
Format: Journal Article
Language:English
Published: Piscataway IEEE 01-01-2018
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
5G mobile communication
Adaptive algorithms
analysis
coded random access
Collision dynamics
congestion reduction
Long Term Evolution
LTE
Mobile computing
mobile networks
network slicing
Parameter modification
Performance evaluation
RACH
Random access
Resource management
simulations
Slicing
Uplink
Virtual networks
Wireless communications
Wireless networks
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Summary:The random access (RA) mechanism of Long Term Evolution (LTE) networks is prone to congestion when a large number of devices attempt RA simultaneously, due to the limited set of preambles. If each RA attempt is made by means of transmission of multiple consecutive preambles (codewords) picked from a subset of preambles, as proposed, collision probability can be significantly reduced. Selection of an optimal preamble set size can maximize RA success probability in the presence of a trade-off between codeword ambiguity and code collision probability, depending on load conditions. In light of this finding, this paper provides an adaptive algorithm, called Multi-preamble RA , to dynamically determine the preamble set size in different load conditions, using only the minimum necessary uplink resources. This provides high RA success probability, and makes it possible to isolate different network service classes by separating the whole preamble set into subsets each associated to a different service class; a technique that cannot be applied effectively in LTE due to increased collision probability. This motivates the idea that preamble allocation could be implemented as a virtual network function, called vPreamble, as part of a random access network slice. The parameters of a vPreamble instance can be configured and modified according to the load conditions of the service class it is associated to.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2018.2800661