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Optimal Power Allocation in Multi-Relay MIMO Cooperative Networks: Theory and Algorithms

Platform : Networking

IEEE Projects Years : 2012

Optimal Power Allocation in Multi-Relay MIMO Cooperative Networks: Theory and Algorithms

Abstract
Cooperative networking is known to have significant potential in increasing
network capacity and transmission reliability. Although there have been extensive studies
on applying cooperative networking in multi-hop ad hoc networks, most works are
limited to the basic three-node relay scheme and single-antenna systems. These two
limitations are interconnected and both are due to a limited theoretical understanding of
the optimal power allocation structure in MIMO cooperative networks (MIMO-CN). In
this paper, we study the structural properties of the optimal power allocation in MIMOCN
with per-node power constraints. More specifically, we show that the optimal power
allocations at the source and each relay follow a matching structure in MIMO-CN. This
result generalizes the power allocation result under the basic three-node setting to the
multi-relay setting, for which the optimal power allocation structure has been heretofore
unknown. We further quantify the performance gain due to cooperative relay and
establish a connection between cooperative relay and pure relay. Finally, based on these
structural insights, we reduce the MIMO-CN rate maximization problem to an equivalent
scalar formulation. We then propose a global optimization method to solve this simplified
and equivalent problem.
Architecture
Existing System
In Existing System, the multi-hop ad hoc networks most works are
limited to the basic three-node relay scheme and single –antenna systems. These
two limitations are interconnected and both are due to a limited theoretical
understanding of the optimal power allocation structure in MIMO cooperative
networks (MIMO-CN). So, capacity level is very low. Indeed, most of current
works on wireless networks attempt to create, adapt, and manage a network on a
maze of point-to-point non-cooperative wireless links. Such architectures can be
seen as complex networks of simple links.
Disadvantages:
1. Low Network Capacity.
2. Communications are focused on physical layer issues, such as
decreasing outage probability and increasing outage capacity, which
are only link-wide metrics.
Proposed System
In Proposed system we use Cooperative diversity. It is a cooperative multiple
antenna technique for improving or maximizing total network channel capacities for any
given set of bandwidths which exploits user diversity by decoding the combined signal of
the relayed signal and the direct signal in wireless multi hop networks. A conventional
single hop system uses direct transmission where a receiver decodes the information only
based on the direct signal while regarding the relayed signal as interference, whereas the
cooperative diversity considers the other signal as contribution.
Advantage
1. To make larger or more powerful; increase.
2. To add to, as by illustrations; make complete.
3. To exaggerate.
4. To produce amplification of: amplify an electrical signal.
Modules
1. Three-node relay transmission
2. Network Constraints
3. Relaying Strategies
4. Cooperative Communications & Optimal Power allocation
5. Multi-hop Transmission
Three-node relay transmission
With physical layer cooperative communications, there are three
transmission manners: direct transmissions, multi-hop transmissions and cooperative
transmissions. Direct transmissions and multi-hop transmissions can be regarded as
special types of cooperative transmissions. A direct transmission utilizes no relays while
a multi-hop transmission does not combine signals at the destination. The cooperative
channel is a virtual multiple-input Multiple-output (MIMO) channel, where spatially
distributed nodes are coordinated to form a virtual antenna to emulate multi-antenna
transceivers.
Network Constraints
Two constraint conditions need to be taken into consideration in the
network connectivity, which is the basic requirement in topology control. The end-to-end
network connectivity is guaranteed via a hop-by-hop manner in the objective function.
Every node is in charge of the connections to all its neighbors. If all the neighbor
connections are guaranteed, the end-to-end connectivity in the whole network can be
preserved. The other aspect that determines network capacity is the path length. An endto-
end transmission that traverses more hops will import more data packets into the
network. Although path length is mainly determined by routing, MIMO – CN limits
dividing a long link into too many hops locally. The limitation is two hops due to the fact
that only two-hop relaying are adopted.
Relaying Strategies
 Amplify-and-forward
 Decode-and-forward
In amplify-and-forward, the relay nodes simply boost the energy of the signal
received from the sender and retransmit it to the receiver. In decode-and-forward, the
relay nodes will perform physical-layer decoding and then forward the decoding result to
the destinations. If multiple nodes are available for cooperation, their antennas can
employ a space-time code in transmitting the relay signals. It is shown that cooperation at
the physical layer can achieve full levels of diversity similar to a MIMO system, and
hence can reduce the interference and increase the connectivity of wireless networks.
Cooperative Communications & Optimal Power allocation
Cooperative transmissions via a cooperative diversity occupying two
consecutive slots. The destination combines the two signals from the source and the relay
to decode the information. Cooperative communications are due to the increased
understanding of the benefits of multiple antenna systems. Although multiple-input
multiple-output (MIMO) systems have been widely acknowledged, it is difficult for some
wireless mobile devices to support multiple antennas due to the size and cost constraints.
Recent studies show that cooperative communications allow single antenna devices to
work together to exploit the spatial diversity and reap the benefits of MIMO systems such
as resistance to fading, high throughput, low transmitted power, and resilient networks.
Multi-hop Transmission
Multi-hop transmission can be illustrated using two-hop transmission. When twohop
transmission is used, two time slots are consumed. In the first slot, messages are
transmitted from the source to the relay, and the messages will be forwarded to the
destination in the second slot. The outage capacity of this two-hop transmission can be
derived considering the outage of each hop transmission.
HARDWARE & SOFTWARE REQUIREMENTS:
HARDWARE REQUIREMENTS:
· System : Pentium IV 2.4 GHz.
· Hard Disk : 40 GB.
· Floppy Drive : 1.44 Mb.
· Monitor : 15 VGA Color.
· Mouse : Logitech.
· Ram : 512 MB.
SOFTWARE REQUIREMENTS:
· Operating system : Windows XP Professional.
· Coding Language : C#.NET



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