According to [ID_sfsls], the following principles
should be obeyed when designing the SLS and
corresponding negotiation process:- Different languages/protocols should be
allowed. - Negotiation at different levels and of different
complexity should be supported. - The services should not be standardised.
- The structures of STS and SIS should be sim-
ple for simple services, yet also allow for
complex services.
The components of an SLS can according to
[ID_sfsls] be grouped as (note that this assumes
DiffServ-based services):- Common unit: describes the terms of offering
the service, e.g. identifying the provider, cus-
tomer, service type, etc. The period of validity
is a central component. - Topology unit: describes the nature and num-
ber of end points, further divided into one Ser-
vice Access Point, SAP, sub-unit and a num-
ber of graph sub-units. The SAP sub-unit
gives a list of end points that specify the
topology (like hose, pipe or funnel). The
end points can for instance be given by IP
addresses. The graph sub-unit gives a list of
sources and destinations and how these are
related. Unidirectional and bidirectional rela-
tions may be described. - QoS related unit: describes the traffic flows
and the service differentiation provided.
Quantitative and qualitative service levels
may be given for some or all parts of the
topology unit. This unit may further be
divided into: i) scope – giving the topology
unit (graph sub-unit or end point) relevant; ii)
traffic descriptor – describing the traffic flows
(including DSCP, port numbers, protocol
information and specification of lower layer);
iii) load descriptor – gives the quantity of
offered traffic, e.g. given by leaky bucket
parameters, as well as treatment of excess of
out-of-profile traffic; iv) QoS parameters –
delay, jitter and loss for the traffic flow.- Monitoring unit: defines a set of parameters
that are to be collected and reported between
the customer and provider. The structure
might be similar to the QoS-related unit.
Example of a schema to apply is also included
in [ID_sfsls] in addition to some selected exam-
ples.4.2 Bandwidth Brokers
The Bandwidth Broker (BB) node is similar to
a Policy Decision Point (PDP), see Section 5, in
the sense that it makes decisions regarding band-
width provisioning. However, bandwidth bro-
kers tend to operate at a higher level than PDPs.
PDPs are typically connected to a (small) num-
ber of Policy Execution Points (PEPs) within an
administrative domain. They tend to be topol-
ogy-aware as a result of their role, e.g. in the
RSVP admission control process. Bandwidth
Brokers are aimed more at the interfaces be-
tween domains. They tend to be less aware of
the topologies within domains.A BB refers to an abstraction that automates the
admission control decisions for service requests
in a network domain. This means that it is
responsible for keeping track of the current allo-
cation of reserved traffic, it is configured with
policies that define which traffic flows belong
to which traffic classes, and it interprets new
requests in the light of these policies and the cur-
rent bandwidth usage. In this sense, a BB can be
considered as a special type of policy server that
is responsible for those related policies for a net-
work domain. A BB is not necessarily a policy
manager but policy management and bandwidth
brokering will need to work together in provid-
ing integrated policy services and admission
control. Another important function of a BB is to
configure network devices according to admitted
QoS requests.The concept of BB can be applied for managing
intradomain and/or interdomain traffic.In the intradomain case, the BB manages the
resources based on the SLA that has been agreed
upon between domains. One or more protocols
are used to exchange information between a host
and a BB, and a BB and a router. The BB willFigure 7 Communication
among BBs
BB1 BB2 BB3AS1 AS2 AS3SLSs SLSsRARsInter-domain Communication
Intra-domain Communicationedge routerservice
users