International telecommunication union


Distributed cloud for service providers



Download 0.91 Mb.
Page27/46
Date20.10.2016
Size0.91 Mb.
#6466
1   ...   23   24   25   26   27   28   29   30   ...   46

9 Distributed cloud for service providers

9.1 Introduction


Cloud computing services are typically delivered via datacenter-like infrastructure. There are numerous types of datacenters with their respective advantages and disadvantages.

The Figure 6 depicts different types of datacenter:



Figure 6 Type of datacenter

Various 5G applications have different requirements in terms of latency, throughput, and cost. Latency sensitive applications such as gaming, voice, video, and telepresence can benefit from the characteristics offered by regional, metropolitan, or access clouds. In a similar fashion, best-effort none-latency sensitive applications can profit from the cost advantage associated with national or continent-wide datacenter solution.

We can expect that in 5G some operators will leverage the distributed nature of their communication network by highlighting the benefits provided by regional or metropolitan clouds.19

A distributed cloud infrastructure supports the deployment and migration of applications between any of these types of cloud infrastructure. The capability to deploy the same application in either a national datacenter or near the network edge can bring unique advantages to operators. As example, a stock trading application would certainly gain from much shorter latency provided by a metropolitan-area rather than a centralized national cloud infrastructure.

A telecom cloud system management in 5G logically sits above the various types of datacenters. Such cloud manager decides in which particular site and processor pool an application would be initiated to fulfill the characteristics and cost defined in the Service Level Agreement associated with it.

A distributed cloud concept which encompasses processing and network resources is fundamental to the success of IMT-2020 network.

9.2 Key characteristics


In order to facilitate management of the system, both regarding traditional, manual O&M, and dynamic, automatic cloud orchestration as we see it in modern cloud based systems, the world of a VM is expected to be flat. I.e., we want VMs to be seen as running on top of a vast, uniform infrastructure where they can be moved around freely. This means that the physical infrastructure must be abstracted so that it can be presented to the VMs this way, as exemplified in the following Figure 7.

Figure 7 distributed cloud

The key characteristics of distributed cloud are:


  • On-demand self-service

A consumer can unilaterally provision capabilities, such as server time, network storage and network bandwidth, as needed without requiring human interaction with each service’s provider.

  • Ubiquitous network access

Capabilities are available over the network and accessed through standard mechanisms that promote use by heterogeneous thin or thick client platforms (e.g., mobile phones, laptops, and PDAs).

  • Location independent resource pooling

The provider’s computing resources are pooled to serve all consumers using a multi-tenant model, with different physical and virtual resources dynamically assigned and reassigned according to consumer demand. The customer generally has no control or knowledge over the exact location of the provided resources. Examples of resources include storage, processing, memory, network bandwidth, and virtual machines.

  • Rapid elasticity

Capabilities can be rapidly and elastically provisioned to quickly scale up and rapidly released to quickly scale down. To the consumer, the capabilities available for rent often appear to be infinite and can be purchased in any quantity at any time.

  • Measured Service

Resource usage can be monitored, controlled, and reported providing transparency for both the provider and user.

In addition to these characteristics, the distributed cloud provides higher resilience and availability, greater security and the support of differentiating service classes, which will drive the deployment in order to guarantee the described Operational Level.



Gap analysis

The existing IMT network has its limitation and lacks of flexibility and agility for deploying the network functions and applications at any location where the performance and user experience would be optimized. In order to meet the extremely various demands of the services in 5G, for example, from ultra-low latency to high-latency tolerable service, distributed cloud technology provides a viable solution. To realize its benefits, the following gaps would need to be filled: (1) Distributed Storage Services that provide uniform, system-wide, distributed block storage for the applications (e.g.,  OpenStack’s Swift and Cinder subsystems) (2) Networking Services that SDN enables such as cloud-wide, virtualized connectivity, both at L2 and L3 levels, such as OpenStack’s Quantum, (3) Distributed Compute Services that manage VM’s, doings tasks such as start, stop, migration and supervisions of VMs is to be performed by a cloud computing service (e.g.,  CloudStack and OpenStack’s Nova) and (4) Cloud management API for applications on top of the cloud infrastructure  (e.g., OpenStack) for application deployment, migration and portability.

Although it is ideal to have all applications running inside VM’s, reality, at least in the short term, dictates that some tasks must continue to execute on non-virtualized or specialized hardware. In order to limit the extra OPEX burden such system anomalies represent, it is still necessary to provide these environments with an API that makes it possible to manage them the same way (i.e. by abstracting and presenting a uniform interface to the applications) as is done with VM’s, so that it is still possible to keep parts of the management APIs (loading, start, stop etc.) uniform and identical to the ones as in VMs.



Download 0.91 Mb.

Share with your friends:
1   ...   23   24   25   26   27   28   29   30   ...   46




The database is protected by copyright ©ininet.org 2024
send message

    Main page