From 8885eddcee8e771fa60b5aaa17e2fda2362f2b95 Mon Sep 17 00:00:00 2001 From: Prayson Pate Date: Wed, 6 Apr 2016 15:21:10 -0400 Subject: 01-intro.rst: clarified some of the text. 02-use_cases.rst: added info on vCPE and micro DC use cases. --- docs/requirements/01-intro.rst | 4 +-- docs/requirements/02-use_cases.rst | 54 +++++++++++++++++++++++++++++--------- 2 files changed, 44 insertions(+), 14 deletions(-) diff --git a/docs/requirements/01-intro.rst b/docs/requirements/01-intro.rst index 3da6f86..4d15cc7 100644 --- a/docs/requirements/01-intro.rst +++ b/docs/requirements/01-intro.rst @@ -13,9 +13,9 @@ Edge NFVI location has certain specific requirements related to: 1. Appropriate Tunneling for User Traffic across WAN (Ethernet, IP/MPLS) links #. Appropriate Tunneling for Management Traffic across WAN links -#. Including reachability requirements to the compute platform (‘eth0’ resilience, +#. Including reachability requirements to the compute platform ('eth0' resilience, this also include backup path through other media e.g. 4G/5G) -#. Extending Multi-DC management to address many small "DC" locations +#. Extending Multi-data center management to address many small or micro data center locations #. Monitoring Capabilities required for a remote Compute Node #. Squaring Bare Metal with remote survivability and whether IaaS is more appropriate for remote locations #. Security. As demarcation technology is operated in an un-trusted environment (CSP perspective) diff --git a/docs/requirements/02-use_cases.rst b/docs/requirements/02-use_cases.rst index 6777a02..828cdab 100644 --- a/docs/requirements/02-use_cases.rst +++ b/docs/requirements/02-use_cases.rst @@ -1,29 +1,59 @@ Use cases and scenarios ======================= -There are several use cases related to Edge NFV: +There are several use cases related to Edge NFV. +This section will briefly describe them, along with the issues or complexities that they +introduce versus a typical data center (DC) deployment. + 1. vE-CPE. - [vE-CPE]_ is related to most popular NFV use case where NFVI compute node is - located at customer premises. Typical applications are virtual Firewall and Virtual BGP router; - VNF chain can be hosted in vE-CPU host and/or DC + [vE-CPE]_ is related to most popular NFV use case where a NFVI compute node is + located at customer premises. + Typical applications are virtual firewall and virtual router to replace physical equivalents. + The service chain can include VNFs hosted in vE-CPE host and/or a centralized data center. + Complexities include: + + * This application is very cost-sensitive, so the server will typically be lower performance + than in the DC. + * There may not be layer 2/Ethernet connectivity at the deployment site, so tunneling may be required. + * There may not be initial connectivity to the node, so some sort of zero-touch protocol may be required. -2. Stand-alone vE-CPE. - It is the same as above but all virtual appliances are hosted at the same CPE compute node. +#. Stand-alone vE-CPE. + It is the same as above but all virtual network functions are hosted at the same CPE compute node. -3. Residential GW. +#. Residential GW. Similar to vE-CPE, the major difference is scale. Typical VNFs are "WAN fault monitoring", - "Performance monitoring". Ratio between deployed vE-CPE - and Residential GW might reach 1:100 or even 1:1000, thus VNF management overhead must be minimized. + "Performance monitoring". + Ratio between deployed vE-CPE and Residential GW might reach 1:100 or even 1:1000, + so VNF management overhead must be minimized. For instance, self-termination after predefined activity period seems preferable over explicit VNF removing via management system. -4. Distributed Base station. +#. Distributed Base station. TBD. What is the difference for it? -5. Network connectivity. +#. Network connectivity. In most cases CPE is connected to Metro Ethernet [#f1]_ . - +#. Micro Data Center + NFVI resources may be located at the edge of the network for the use cases listed above. + Doing so increases the scale of the clouds or locations that must be orchestrated and controlled. + If OpenStack is run in a distributed fashion, with a central node controlling distributed + NFVI servers, the following issues may be seen: + + * Lack of security between OpenStack client and server. + * Lack of compatibility between different versions of OpenStack. + * Scalability of OpenStack. + * Operation in low speed or lossy networks is complicated by the amount of messaging required. + * OpenStack communications are not secured. This creates a vulnerability in a distributed application. + * OpenStack numbers VNF ports in a sequential manner, with the sequence serially numbered + in the VM/VNF. + The difficulty comes when trying to verify that the LAN has been connected to the correct LAN port, + the WAN has been connected to the correct WAN port and so on. + * While OpenStack provides a rich set of APIs, critical support is lacking: + + * No APIs for ssh access to VM/VNFs. + * No APIs for port mirroring in Neutron. + * No APIs for OpenStack oversubscription parameter setting .. [#f1] In all above use cases management traffic is coming inband with tenant traffic. -- cgit 1.2.3-korg