3 research outputs found
Multi-cell Coordination Techniques for DL OFDMA Multi-hop Cellular Networks
The main objective of this project is to design coordinated spectrum sharing and reuse
techniques among cells with the goal of mitigating interference at the cell edge and
enhance the overall system capacity. The performance of the developed algorithm will be
evaluated in an 802.16m (WiMAX) environment.
In conventional cellular networks, frequency planning is usually considered to keep an
acceptable signal-to-interference-plus noise ratio (SINR) level, especially at cell
boundaries. Frequency assignations are done under a cell-by-cell basis, without any
coordination between them to manage interference. Particularly this approach, however,
hampers the system spectral efficiency at low reuse rates. For a specific reuse factor, the
system throughput depends highly on the mobile station (MS) distribution and the channel
conditions of the users to be served. If users served from different base stations (BS)
experience a low level of interference, radio resources may be reused, applying a high
reuse factor and thus, increasing the system spectral efficiency. On the other side, if the
served users experience large interference, orthogonal transmissions are better and
therefore a lower frequency reuse factor should be used. As a consequence, a dynamic
reuse factor is preferable over a fixed one.
This work addresses the design of joint multi-cell resource allocation and scheduling with
coordination among neighbouring base stations (outer coordination) or sectors belonging to
the same one (inner coordination) as a way to achieve flexible reuse factors. We propose a
convex optimization framework to address the problem of coordinating bandwidth
allocation in BS coordination problems.
The proposed framework allows for different scheduling policies, which have an impact on
the suitability of the reuse factor, since they determine which users have to be served.
Therefore, it makes sense to consider the reuse factor as a result of the scheduling decision.
To support the proposed techniques the BSs shall be capable of exchanging information
with each other (decentralized approach) or with some control element in the back-haul
network as an ASN gateway or some self-organization control entity (centralized
approach)
Multi-cell Coordination Techniques for DL OFDMA Multi-hop Cellular Networks
The main objective of this project is to design coordinated spectrum sharing and reuse
techniques among cells with the goal of mitigating interference at the cell edge and
enhance the overall system capacity. The performance of the developed algorithm will be
evaluated in an 802.16m (WiMAX) environment.
In conventional cellular networks, frequency planning is usually considered to keep an
acceptable signal-to-interference-plus noise ratio (SINR) level, especially at cell
boundaries. Frequency assignations are done under a cell-by-cell basis, without any
coordination between them to manage interference. Particularly this approach, however,
hampers the system spectral efficiency at low reuse rates. For a specific reuse factor, the
system throughput depends highly on the mobile station (MS) distribution and the channel
conditions of the users to be served. If users served from different base stations (BS)
experience a low level of interference, radio resources may be reused, applying a high
reuse factor and thus, increasing the system spectral efficiency. On the other side, if the
served users experience large interference, orthogonal transmissions are better and
therefore a lower frequency reuse factor should be used. As a consequence, a dynamic
reuse factor is preferable over a fixed one.
This work addresses the design of joint multi-cell resource allocation and scheduling with
coordination among neighbouring base stations (outer coordination) or sectors belonging to
the same one (inner coordination) as a way to achieve flexible reuse factors. We propose a
convex optimization framework to address the problem of coordinating bandwidth
allocation in BS coordination problems.
The proposed framework allows for different scheduling policies, which have an impact on
the suitability of the reuse factor, since they determine which users have to be served.
Therefore, it makes sense to consider the reuse factor as a result of the scheduling decision.
To support the proposed techniques the BSs shall be capable of exchanging information
with each other (decentralized approach) or with some control element in the back-haul
network as an ASN gateway or some self-organization control entity (centralized
approach)