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On the Bandwidth Management for Hose-Model VPN Service

On the Bandwidth Management for Hose-Model VPN Service. GRADUATE INSTITUTE OF INFORMATION MANAGEMENT NATIONAL TAIWAN UNIVERSITY. Outline. An Introduction to VPN VPN Service Models (Bandwidth management) The pipe model The hose model Implementation Alternatives of the Hose Model VPN

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On the Bandwidth Management for Hose-Model VPN Service

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  1. On the Bandwidth Management for Hose-Model VPN Service GRADUATE INSTITUTE OF INFORMATION MANAGEMENT NATIONAL TAIWAN UNIVERSITY Yu-Liang Liu

  2. Outline An Introduction to VPN VPN Service Models (Bandwidth management) The pipe model The hose model Implementation Alternatives of the Hose Model VPN Hose-Model VPN Service Provisioning Future Works Yu-Liang Liu

  3. Private Network A Private Network (PN) is established by dedicated leased lines connecting several geographically dispersed sites (endpoints). Each site is a campus or a branch office of an enterprise. Since the lines are dedicated, security and Quality of Service (QoS) are ensured. But connecting a large number PN sites with dedicated lines is expensive. Yu-Liang Liu

  4. Virtual Private Network Virtual Private Network (VPN) is a replacement for Private Network. A VPN establishes connectivity between a set of endpoints over a shared network infrastructure (eg: MPLS network backbone). The goal of VPN is to provide endpoints with a service comparable to Private Network. Thus providers of VPN services need to address QoS and security issues. Yu-Liang Liu

  5. VPN Three Types In terms of commercial applications, VPN can be classified into three types: Access VPN (a.k.a Remote Access VPN) Intranet VPN (a.k.a Enterprise VPN) Extranet VPN (a.k.a E-commerce VPN) Yu-Liang Liu

  6. VPN Three Types (con’t) Nomadic user Enterprise B Shard Network or Enterprise A Enterprise A Yu-Liang Liu

  7. Outline An Introduction to VPN VPN Service Models (Bandwidth management) The pipe model The hose model Implementation Alternatives of the Hose Model VPN Hose-Model VPN Service Provisioning Future Works Yu-Liang Liu

  8. VPN Service Models VPN customers need a flexible ways to specify their bandwidth requirement. Two common VPN service Models are The Customer-pipe model The Hose model Yu-Liang Liu

  9. The Customer-Pipe Model In this model, VPN customers buy a customer-pipe for each endpoints pair. VPN customers need to specify bandwidth requirement of each customer-pipe in advance. VPN service provider uses a path between endpoints pair to implement a customer-pipe. VPN service provider also need to allocate adequate bandwidth along the path. Yu-Liang Liu

  10. The Customer-Pipe Model (con’t) Yu-Liang Liu

  11. The Pro and Cons of the Customer Pipe Model Pro The task of bandwidth allocation becomes more simple. Con It requires the customer to have precise knowledge of the bandwidth requirement of each endpoints pair in advance. Bandwidth made available to a customer pipe cannot be allocated to other traffic. Yu-Liang Liu

  12. Motivation for the Hose-Model VPN customers may unwilling to unable to know the bandwidth requirement between each endpoints pair in advance. This is especially true when the number of endpoints per VPN is large. Yu-Liang Liu

  13. The Hose Model In this model, VPN customers only need to specify two parameters for each endpoint: Egress bandwidth requirement: the bandwidth for aggregate outgoing traffic from the endpoint to all the other endpoints. Ingress bandwidth requirement: the bandwidth for aggregate incoming traffic out of all the other endpoints to this endpoint. Yu-Liang Liu

  14. Advantages of the Hose Model Ease of specification Flexibility Yu-Liang Liu

  15. Challenge of Provision the Hose Model VPN From a VPN service provider’s perspective, it is more challenging to support the hose model VPN: The need to meet the bandwidth requirement with a very weak specification. This complicate the VPN’s bandwidth management issue. Yu-Liang Liu

  16. Outline An Introduction to VPN VPN Service Models The pipe model The hose model Implementation Alternatives of the Hose Model Hose-Model VPN Service Provisioning Future Works Yu-Liang Liu

  17. Implementation Alternatives of the Hose Model The most important implementation alternatives for the hose model VPNs are: Provider-pipe algorithm Hose-specific state algorithm VPN-specific state algorithm Tree routing algorithm Yu-Liang Liu

  18. Provider-Pipe scheme Yu-Liang Liu

  19. Hose-specific state scheme Yu-Liang Liu

  20. VPN-specific state scheme Yu-Liang Liu

  21. Tree RoutingScheme Yu-Liang Liu

  22. Is the Hose Model a Viable Alternative • The main question to introduce the hose model in ISP networks is how does it relate to the customer pipe solution in terms of bandwidth efficiency. • The flexibility of the hose model will never pay off if it requires significant overprovisioing compared to customer-pipe models. Yu-Liang Liu

  23. Generate Comparable Hose Model Parameters Customer-Pipe Model parameters: Hose-Model parameters: Yu-Liang Liu

  24. Overprovisioning Factor • The ratio between the bandwidth reservation of the hose and the customer-pipe model is called overporvisioning factor. It is a good indicator of the required extra capacity. Yu-Liang Liu

  25. Experimental Results Provider-pipe VPN-specific state Hose-specific state Tree routing Yu-Liang Liu

  26. Experimental Results Yu-Liang Liu

  27. Outline An Introduction to VPN VPN Service Models (Bandwidth management) The pipe model The hose model Implementation Alternatives of the Hose Model VPN Hose-Model VPN Service Provisioning Future Works Yu-Liang Liu

  28. Hose-Model VPN Service Provisioning • In terms of VPN service provisioning, service provider must establish multiple VPNs on the network backbone in an on-line manner. • The available bandwidth for VPN service on links of the network backbone is finite. • VPN setup request arrive one by one independently. • Each VPN setup request corresponds to a Hose-Model VPN to be established. • Information about future VPN setup request is unknown. Yu-Liang Liu

  29. Hose-Model VPN Service Provisioning • If there is not enough residual bandwidth on the link when the bandwidth is being allocated, vri will be rejected. • In this scenario, the performance metric for comparing different VPN provisioning algorithm is rejection ratio. Yu-Liang Liu

  30. Example • In this scenario, even tree routing algorithm cannot achieve rejection ratio. • Service provider received two VPN setup requests vr1=(2,3,3) and vr2=(3,3,3). • The available bandwidth on all links is 5 units. Yu-Liang Liu

  31. Rejection Ratio of Tree Routing Scheme vr2 will be rejected, the rejection ratio achieved is 50%. Yu-Liang Liu

  32. Optimal Arrangement Both VPN setup requests will be accepted, the rejection ratio achieved is 0%. Yu-Liang Liu

  33. Modified Tree Routing Algorithm • The design philosophy of MTRA is to look after both bandwidth allocation efficiency and load balance. • It can reduce rejection ratio effectively. Yu-Liang Liu

  34. Parameters Configuration Yu-Liang Liu

  35. Experimental Results Yu-Liang Liu

  36. Future Works • In order to ensure service quality and availability of VPN services, seamless recovery from failures is essential. • Failure restoration algorithm for Hose-Model VPN. Yu-Liang Liu

  37. 1 2 3 Recovery from Link Failure Tree Link (1,4) fail and the corresponding backup path is activated: 4 Yu-Liang Liu

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