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1
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2
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- A Definition of Maritime Networks
- Motivation
- The Maritime Model
- The Management Services
- Results
- Conclusions and Future Work
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3
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4
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5
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- Since maritime units operate in a low bandwidth environment with varying
communications capabilities the efficient use of bandwidth and effective
exchange of information is essential
- While different applications are converged onto a single network they do
not all have the same value. Traffic engineering (TE) can be used to
ensure that critical information is delivered before less urgent
traffic.
- In order to evaluate potential TE services in maritime networks,
modeling provides a low cost alternative to implementation.
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6
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- Small Network
- The connectivity of the small network model showing all the wireless
links is shown
- Based on the description of a single naval task group on patrol
- Large Network
- A straightforward extension of the small network, except with two naval
task groups
- The second task group has two high speed satellite links instead of one
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7
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- Intra-task force mobility
- Based on the Nomadic Community model where the individual nodes of each
task group move randomly within 3 nm of their base position
- Links fail when they exceed 18 nm.
- Inter-task force mobility
- The two task groups begin 18 nm away from each other (at the closest
point) and at a random arrival angle.
- The first task group then approaches the other steadily at a relative
speed of 30 knots (nm/hour) on a set heading evenly distributed from
this trajectory angle of -45° to +45°
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8
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- The nominal load model was made to match as closely as possible the
background traffic seen during a maritime exercise (in is towards the
maritime node)
- The high load model is based on the assumption of increased traffic at
times of increased activity.
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9
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- Traffic Monitoring Service (TMS)
- Designed to measure the incoming and outgoing traffic of a node and
distribute this information in summary form to all other nodes (at a
varying level of detail)
- Traffic Prioritisation Service (TPS)
- Provides a mechanism to rank traffic by importance and prioritise
resource allocation accordingly using DiffServ
- Adaptive Routing Service (ARS)
- Provides load balancing and matches application traffic classes to
network resources, determining what types of traffic must/should travel
over a certain type of bearer
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10
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- Based on the topology, mobility and background traffic described the TMS
was simulated in OPNET
- The effect of increased load is readily apparent in maritime networks,
with the TMS delay almost doubling from nominal to high background
traffic
- Enhanced and detailed modes have a long delay which may be acceptable if
the information is not being used interactively
- Unlikely to be sufficient for problem solving purposes
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11
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- Use of the DiffServ weights shown gave a significant improvement in the
TMS delay.
- Improvement of approximately 20% at saturation and
approximately 33% at high load were seen.
- This confirms that DiffServ-style QoS can make a significant improvement
to prioritized flows in the Maritime environment.
- Further studies in OPNET could be completed to determine the impact of
alternative WFQ weightings.
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12
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- Without TPS or ARS, the delay of two voice calls from the NOC were both
1.4 +/- 0.3 seconds at high load, far less than an generally accepted
maximum of 500 ms.
- In order to improve utilization of the network, an MPLS overlay was
introduced to allow traffic travelling to Ship 4 to take different
routes depending on the application type and priority.
- In this case high priority voice traffic was to travel via Ship 3 while
all other traffic will travel over the default route via Ship 1.
- With the combination of TPS and ARS, the impact on the delay of voice
packets is significant.
- The high-priority voice call which is taking the alternate lightly
loaded route via Ship 3 has a delay of 0.19 +/- 0.03 seconds while the
lower priority voice call which uses the default route has a delay of
0.43 +/- 0.10 seconds.
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13
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- Management services were shown to provide concrete improvements
- TMS Monitoring service with variable overhead and delay
- TPS Prioritisation service gives 20-33% improvement
- ARS Adaptive routing provides load balancing
- Simulation provides low cost alternative to real-time deployment and
testing
- Results are only as good as the model
- Currently using maritime model to investigate guaranteed reservation
service
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Notes