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VERTICAL QOS MAPPING
OVER WIRELESS
INTERFACES
Marchese, M.; Mongelli, M.;
Wireless Communications, IEEE
Volume 16, Issue 2, April 2009 Page(s):37 - 43
Report : Jai- Shiarng Chen
Department of Communications Engineering CCU
CN Group
Outline
Introduction
The technology-independent service access
point
TI-SAP model
Vertical QoS mapping problem
Reference scheme for dynamic QoS mapping
over TI-SAP interface
Example results
conclusions
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Introduction
Modern telecommunication networks
Different portions and technologies
The end-to-end Qos is challenged
Over heterogeneous
Horizontal QoS
Source to the destination
The protocol used and the network features
Vertical QoS
Composed of layered architectures
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Introduction(cont.)
Qos achieved at each layer of the network
Define an interface between adjacent layers
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Introduction(cont.)
Establish a QoS-oriented between layers
A good example
European Telecommunications
Standards Institute (ETSI)
Broadband satellite multimedia(BSM)
Satellite-dependent(SD)
Satellite-independent(SI)
Physical , MAC and link control
IP and upper layers
Satellite independent –service
access point(SI_SAP)
Offer QoS service
The architecture is generalized
Different physical supports
Wire and wireless
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Introduction(cont.)
The idea is to extend
Technology-dependent(TD)
Technology-independent(TI)
Technology independent-service access point(TI-SAP)
Use specific hardware/software solution, often covered by
patents
TD and TI communication without affecting TD-layer
implementation
Dynamic bandwidth adaptation at TI-SAP
Vertical QoS mapping
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The technology-independent
service access point
TI-SAP within a wireless portion
Overall IP-based heterogeneous
network composed of wide area
networks
Wireless portion is located in the
middle
Between two generic WANs
The lower must offer a QoS
Guarantee to the upper layer
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TI-SAP model
TI-SAP include
Abstract queue
Identifies a specific QoS level
Transfer packets from the TI to the TD layer
A battery of buffers at the TI-SAP
Any network node is implemented
Different levels of QoS
Different QoS service
TI layer can access and modify the abstract queue
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TI-SAP model
TI resource management entry
Allocates and manage resource (IP)
TD resource management entry
Physically allocates the required
resource
Network control center(NCC)
Bandwidth is allocated
–
Different remote stations
QoS mapping management entry
Receive resource require from TI
The entry maps it on the lower layer
Applied at the TD layer
Translate the request(reservation ,
release and modification actions)
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Vertical QoS mapping problem
Change of information unit
The information come from upper layer
Overhead
TI layer is encapsulated within new frame composed information
TD layer must consider the additional bits of the header
Heterogeneous traffic aggregation
Bandwidth must be adapted at TD
Queue number decreases from upper
to lower layer
Fading effect
Must handle time-vary-channel
condition
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Such as satellite and wireless links
Reference :M. Marchese, QoS over Heterogeneous
Networks, John Wiley & Sons, 2007.
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Vertical QoS mapping problem
(cont.)
Joint problem
Fading effect can be modeled
A multiplicative stochastic process
0(total outage)to 1(free error channel)
The model can be iterated
Bandwidth adaptation
Very challenging
RTD guarantee to TI layer queue
Equivalent bandwidth(EqB)
– Minimum service rate to guarantee a certain degree
of QoS
– Single QoS constraint
The complexity of overall input flow process
– Almost non-applicable
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Reference scheme for dynamic QoS
mapping over TI-SAP interface
Allocate bandwidth periodically at the TD layer
After receiving the QoS constraints through TI-SAP
RTD(tk) allocation the instant tk
An information vector
TD buffer
Simply the error e(tk)
Above 0, minimum additional amount of bandwidth
– Enable the satisfaction of QoS constraints
Below 0, over-provisioned bandwidth
– Maximum amount of bandwidth that can dropped without violating QoS
Minimum bandwidth that guarantees the QoS constraints
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In the interval [tk-1 , tk]
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Reference scheme for dynamic QoS
mapping over TI-SAP interface(cont.)
RTF(tk) = RTD(tk–1) + wk ⋅ e(tk)
wk is a weight
Arrived and lost bits at the TD-layer
Compute the loss rate that can be tolerated
Check the bandwidth under-provision or over-provision
Estimation of the bandwidth requirement
Allocate the bandwidth in the next interval consequently
Reference chaser bandwidth controller(RCBC)
Use the sensitivity of the system performance
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Variations of the allocation bandwidth
Weight : Wk dynamically over time
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Trunk of 50 VoIP
TI -> TI-SAP -> TD
Example results
ATM at TD layer
Only one IP queue
and one ATM queue
Performance metric
Packet loss
2 。10 -2
Packet delay
20 ms
Bandwidth reallocation
Every minute
Buffer size
TI : 1600bytes
(20 VoIP packet)
TD: 3710 byte
(70 ATM cell)
Four peaks
Reduction factor
change
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Quick reaction and bandwidth adaptation
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Conclusion
Dynamic schemes based on measure
Quickly to change in traffic
Performance parameter
Complex mathematical traffic models
Unsuitable for real network conditions
Future research
Implementation detail of bandwidth adaptation
mechanisms
Implement RCBC within a TI-SAP-based architecture
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Thank you
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BSM architecture
Broadband satellite multimedia
CSF-1: The interface between the IETF protocols and the Client function (internal to
the IP layer).
• CSF-2: The interface between the peer IETF Client [interworking] functions.
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• CSF-3: The interface between the Client function and the Server function(s).
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ETSI BSM protocol stack
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Reference : ETSI, Satellite Earth Stations and Systems (SES), Broadband Satellite Multimedia, IP
over Satellite, ETSI Technical Report, TR 101 985 V1.1.2, November 2002.
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