Table Of Contents
Tested Deployments and Site Models
Multisite Distributed Deployment Options
Multisite Centralized Call Processing with SRST Router
Multisite with Distributed Call Processing
Cisco Intercompany Media Engine
Unified Communications on Virtualized Servers
Cisco Unified Communications Manager - Session Manager Edition Site
Europe and Emerging Markets Site Models
Large Multisite Centralized with Unified SRST
Medium Site Centralized with Unified SRST
Cisco Unified Communications Manager Session Management Edition
Medium Site Dual-stack Centralized with Unified SRST
Cisco Unified Communications Manager Interoperability Site Centralized with Unified SRST
Mid-Market Multi-Site Centralized (Unified CMBE)
Mid-Market Multi-Site Centralized (Unified CMBE 3000)
Tested Deployments and Site Models
Cisco Unified Communications Release 8.6(1) testing for IP telephony was designed to test the hardware and software components that work together in a multisite distributed IP telephony deployment.
For this testing, the following site models were created. Each site model was designed to test a specific set of features and interactions. The site models can be used in various combinations to create different versions of a multisite distributed deployment model.
•North America site models:
–Multisite with Centralized Call Processing with SRST Router(SFO-ORD)
–Campus (DFW and SJC/RFD)
–Multisite with Distributed Call Processing (ICT traffic between all sites, including (YYZ/ATL)
–Cisco Unified Communications Manager Session Manager Edition (MCI-LAX)
–Cisco Intercompany Media Engine (SFO/ORD)
–Clustering Over the IP WAN (SJC/RFD sites and SFO/ORD)
–Unified Communications on Virtualized Servers (SJC/RFD and SFO/ORD)
–Call Routing and Dial Plan Distribution Using Call Control Discovery for the Service Advertisement Framework (MCI-LAX talking to SJC/RFD and SFO/ORD)
–Video Enhancements
•Europe Union and Emerging Markets (EUEM) site models
–Large Multisite Centralized with Unified SRST (CDG)
–Medium Site Centralized with Unified SRST (GVA)
–Multi-site and Medium-site Centralized Co-located with Cisco Unified Communications Manager Session Management Edition (CDG-SME, GVA-SME and MLN-SME)
–Medium Site Dual-stack Centralized with Unified SRST (BRU)
–Small Site (MAD)
–Cisco Unified Communications Manager Interoperability Site Centralized with Unified SRST (LGW)
–Cisco Unified Communications Manager Interoperability Site (Cisco SIP CME Site Aggregated by Cisco Unified SIP Proxy) (RKV)
–Small Campus Multi-site H.323 (WAW)
–Mid-Market Multi-Site Centralized Site with Unified CMBE (MAN)
–Mid-Market Multi-Site Centralized Site with Unified CMBE 3000 (BLR)
This topic describes each site model.
For additional guidelines, recommendations, and best practices for implementing enterprise networking solutions, refer to the Cisco Solution Reference Network Design (SRND) guides and related documents, which are available at this URL:
For a list of the release versions of the components used in the site models, see System Release Notes for IP Telephony: Cisco Unified Communications System, Release 8.6(1)
This topic includes the following sections:
•Multisite Distributed Deployment Options
•Europe and Emerging Markets Site Models
Purpose of Solution Tests
An efficient, effective, and reliable IP telephony solution requires many interrelated hardware and software components. The site models that are described in this manual provide you with models and guidance as you implement an IP telephony system for your organization. Cisco has selected, installed, configured, and tested hardware and software designed to work together seamlessly and to provide a complete and optimized IP telephony solution.
Each site model addresses some or all of the following issues:
•End-to-end functionality
•Operability in a real-world environment
•Scalability
•Stability
•Stress
•Load
•Redundancy
•Reliability
•Usability
•Availability
•Installability
•Upgradeability
•Serviceability
•Regression
•Negative Scenario
Multisite Distributed Deployment Options
The site models within each test group (North America and EUEM) can be implemented in various combinations to create deployment models to meet the needs of a wide range of organizations.
For detailed information about the sites used in North America deployments, see the North America Site Models.
For detailed information about the sites used in EUEM IP telephony deployment, see the Europe and Emerging Markets Site Models.
The Solution integration test bed topologies diagrams for NA and EUEM for IP telephony tested in Cisco Unified Communications Release 8.6(1) is available from the Resource Library tab of the Technical Information Site.
North America Site Models
Eight site models were created and tested for Cisco Unified Communications Release 8.6(1) testing for North America IP telephony. Each site model tested specific hardware and software components, features, functions, protocols, and related items.
A site model includes one or more sites. Each site has a three-letter name (for example, SFO, ORD, and SJC). Examples throughout this manual refer to these site names.
The following sections describe each site model in detail. Each section includes an explanation of the design characteristics of the site model, and includes a table that lists the hardware and software components used in the model. The tables contain the following information for each component:
•Component—Hardware or software component
•Description—Information such model number5 release number, protocol, and hardware platform
•Qty.—Quantity of the component used in the model
Table 1 lists the site models and references to sections that provide detailed information.
Table 1 North America Site Models
Site Model and Reference Sites IncludedSan Francisco (SFO), Chicago (ORD)
San Jose (SJC), Rockford (RFD), Dallas (DFW)
ICT traffic between all sites, including the CME sites Toronto (YYZ) and Atlanta (ATL)
San Francisco (SFO), Chicago (ORD)
San Jose (SJC), Rockford (RFD), and San Francisco (SFO), Chicago (ORD)
San Jose (SJC), Rockford (RFD), and San Francisco (SFO), Chicago (ORD)
Kansas City (MCI), Los Angeles (LAX) talking to San Jose (SJC), Rockford (RFD), and San Francisco (SFO), Chicago (ORD) and Dallas (DFW)
Cisco Unified Communications Manager - Session Manager Edition Site
Kansas City (MCI), Los Angeles (LAX)
Multisite Centralized Call Processing with SRST Router
The Multisite Centralized Call Processing with Remote Site Survivability (SRST Router) site model represents a very large financial company deployment in which two sites, San Francisco (SFO) and Chicago (ORD), are used to cluster Cisco Unified Communications Manager over an IP WAN. In this model, half of the cluster resides in SFO and the other half in ORD. These sites provide centralized call processing to remote Cisco Unified Survivable Remote Site Telephony (Unified SRST) sites. Communications with remote sites takes place over the IP WAN.
Remote sites are connected to the WAN (4 T1s) using Cisco 7200 Series router. Each site support approximately equal volumes of network traffic, and each is capable of carrying 100 percent of the traffic in the event of a failure in the other's network. Cisco 2921 series integrated services routers are configured with Hot Standby Routing Protocol (HSRP) and Survivable Remote Site Telephony (SRST). For load sharing between the sites, Multi-group HSRP (MHSRP) is configured.
The Cisco 3800 Series integrated services routers provide gateway connectivity to public switched telephone network (PSTN) providers using T1/E1 primary rate interfaces (2 PRIs). Each remote site is connected to a Cisco Catalyst 37xx series Switch, which connects VOIP endpoints to remote sites, which also includes Power over Ethernet features to power Cisco IP phones. Packet markings are also done at Cisco37xx using Modular QoS CLI (MQC) based configuration using class-map and policy-map.
The tested Multisite Centralized site model has the following design characteristics:
•Single Unified Communications Manager cluster. Some centralized call processing deployments may require more than one Unified CM cluster, for instance, if scale calls for more endpoints than can be serviced by a single cluster or if a cluster needs to be dedicated to an application such as a call center.
• For smaller deployments, Cisco Unified CMBE 3000 may be deployed in centralized call processing configurations for up to 9 remote sites
•Unified CMBE 5000 or CMBE 6000 may be deployed in centralized call processing configurations for up to 19 remote sites.
•Maximum of 30,000 configured and registered Skinny Client Control Protocol (SCCP) or Session Initiation Protocol (SIP) IP phones or SCCP video endpoints per cluster.
•Maximum of 2,000 locations or branch sites per Cisco Unified Communications Manager cluster.
•Maximum of 2,100 gateways and trunks (that is, the total number of H.323 gateways, H.323 trunks, digital MGCP devices, and SIP trunks) per Cisco Unified Communications Manager cluster.
•PSTN connectivity for all off-net calls.
•Digital signal processor (DSP) resources for conferencing, transcoding, and media termination point (MTP) are distributed locally to each site to reduce WAN bandwidth consumption on calls requiring DSPs.
•Capability to integrate with legacy private branch exchange (PBX) and voicemail systems. Interfaces to legacy voice services such as PBXs and voicemail systems can connect within the central site, with no operational costs associated with bandwidth or connectivity. Connectivity to legacy systems located at remote sites may require the operational expenses associated with the provisioning of extra WAN bandwidth.
•The system allows for the automated selection of high-bandwidth audio (for example, G.711, G.722, or Cisco Wideband Audio) between devices within the site, while selecting low-bandwidth audio (for example, G.729 or G.728) between devices in different sites.
•The system allows for the automated selection of high-bandwidth video (for example, 384 kbps or greater) between devices in the same site, and low-bandwidth video (for example, 128 kbps) between devices at different sites. The Cisco Unified Video Advantage Wideband Codec, operating at 7 Mbps, is recommended only for calls between devices at the same site.
•A minimum of 768 kbps or greater WAN link speed should be used when video is to be placed on the WAN.
•Cisco Unified Communications Manager locations (static or RSVP-enabled) provide call admission control.
•For voice and video calls, Automated Alternate Routing (AAR) provides the automated rerouting of calls through the PSTN when call admission control denies a call due to lack of bandwidth. AAR relies on a gateway being available to route the call from the calling phone toward the PSTN, and another gateway to accept the call from the PSTN at the remote site, to be connected to the called phone.
•Call Forward Unregistered (CFUR) functionality provides the automated rerouting of calls through the PSTN when an endpoint is considered unregistered due to a remote WAN link failure. CFUR relies on a gateway being available to route the call from the calling phone toward the PSTN, and another gateway to accept the call from the PSTN at the remote site, to be connected to the called phone.
•Survivable Remote Site Telephony (SRST) for video. SCCP video endpoints located at remote sites become audio-only devices if the WAN connection fails.
•Cisco Unified Communications Manager Express (Unified CME) may be used for remote site survivability instead of an SRST router.
•Cisco Unified Communications Manager Express (Unified CME) can be integrated with the Cisco Unity server in the branch office or remote site. The Cisco Unity server is registered to the Unified CM at the central site in normal mode and can fall back to Unified CME in SRST mode when Unified CM is not reachable, or during a WAN outage, to provide the users at the branch offices with access to their voicemail with MWI.
Figure 1 provides an overview of the Multisite Centralized Call Processing with SRST site model.
Figure 1 Multisite Centralized, Call Processing with SRST Model
Table 2 lists the hardware and software components used in the Multisite Centralized, Clustering over the WAN with Unified SRST site model.
Campus
The Campus site model represents a very large campus in which two sites, San Jose (SJC) and Rockford (RFD), are used to cluster Cisco Unified Communications Manager over an IP WAN. This site also supports RSVP cluster.
The Cisco Unified Communications Manager cluster in this site model consists of the following:
•One publisher
•Ten subscribers (Five in each site)
•Two music on hold servers (one in each site)
•Two TFTP servers (one in each site)
The campus site model also consists of another site called Dallas (DFW). This site includes a Cisco Unified Communications Manager cluster that includes the following:
•One publisher
•Four subscribers
•MOH and TFTP servers (one each)
This deployment model has the following characteristics:
•Single Cisco Unified Communications Manager cluster. Some campus call processing deployments may require more than one Unified CM cluster, for instance, if scale calls for more endpoints than can be serviced by a single cluster or if a cluster needs to be dedicated to an application such as a call center.
•Maximum of 30,000 configured and registered Skinny Client Control Protocol (SCCP) or Session Initiation Protocol (SIP) IP phones or SCCP video endpoints per Unified CM cluster.
•Maximum of 2,100 gateways and trunks (that is, the total number of H.323 gateways, H.323 trunks, digital MGCP devices, and SIP trunks) per Unified CM cluster.
•Trunks and/or gateways (IP or PSTN) for all calls to destinations outside the campus.
•Co-located digital signal processor (DSP) resources for conferencing, transcoding, and media termination point (MTP).
•Other Unified Communications services, such as messaging (voicemail), presence, and mobility are typically co-located.
•Interfaces to legacy voice services such as PBXs and voicemail systems are connected within the campus, with no operational costs associated with bandwidth or connectivity.
•High-bandwidth audio is available (for example, G.722 or Cisco Wideband Audio) between devices within the site.
•High-bandwidth video (for example, 384 kbps or greater) is available between devices within the site. The Cisco Unified Video Advantage Wideband Codec, operating at 7 Mbps, is also supported.
Figure 2 shows the topology of the Campus site model.
Figure 2 Campus
Table 3 lists the hardware and software components used in the Campus site model.
Figure 3 shows the topology of the Dallas (DFW) Site model.
Figure 3 DFW Site Model
Multisite with Distributed Call Processing
The model for a multisite deployment with distributed call processing consists of multiple independent sites, each with its own call processing agent cluster connected to an IP WAN that carries voice traffic between the distributed sites. One of these sites is called Atlanta (ATL). This site includes:
•Two Cisco Unified Communications Manager Express routers
•100 SIP endpoints
Another site is called Toronto (YYZ). This site includes:
•Two Cisco Unified Communications Manager Express routers
•One H.323 gatekeeper
•265 SCCP Endpoints
The remainder of this model consists of Intercluster Trunk (ICT) traffic between the SFO/ORD, SJC/RFD, and DFW clusters. H.323 gatekeeper controlled trunks and SIP trunks are used. Location-based and End-to-End RSVP call admission control are also included in testing.
Figure 4 shows the topology of the Campus site model.
Figure 4 Multisite with Distributed Call Processing Model
Cisco Intercompany Media Engine
Cisco Intercompany Media Engine (IME) is another variation of a multisite deployment with distributed call processing; however, with IME the sites are separate enterprise organizations. The term boundary-less Unified Communications is used to describe this technology because it allows for the business-to-business extension of Unified Communications capabilities such as high-fidelity codecs, enhanced caller ID, and video telephony outside the corporate networks. The solution learns routes in a dynamic, secure manner and provides for secure communications between organizations across the internet. Organizations that work closely together and have high levels of intercompany communications will benefit most from the enhanced communications offered by IME. This section discusses the components of the solution and the high-level architecture, with relevant design considerations for deploying IME.
Cisco Intercompany Media Engine (IME) consists of several components to allow for the dynamic learning of IME routes and the secure encryption of call signaling and media between organizations. The following additional integral components are deployed on-premises:
•Cisco Intercompany Media Engine Server
•Cisco Unified Communications Manager (Unified CM)
•Cisco Adaptive Security Appliance (ASA)
100 SIP endpoints
Clustering Over the IP WAN
The Clustering over the IP WAN site model is used in the implementation of the SJC/RFD, SFO/ORD, and MCI-LAX clusters. It is possible to deploy a single Unified Communications Manager cluster across multiple sites that are connected by an IP WAN with QoS features enabled. Clustering over the WAN can support two types of deployments:
•Local Failover Deployment Model - Local failover requires that you place the Unified Communications Manager subscriber and backup servers at the same site, with no WAN between them. This type of deployment is ideal for two to four sites with Unified Communications Manager.
•Remote Failover Deployment Model - Remote failover allows you to deploy primary and backup call processing servers split across the WAN. Using this type of deployment, you may have up to eight sites with Unified Communications Manager subscribers being backed up by Unified Communications Manager subscribers at another site.
A combination of the two deployment models can be used to satisfy specific site requirements. For example, two main sites may each have primary and backup subscribers, with another two sites containing only a primary server each and utilizing either shared backups or dedicated backups at the two main sites.
Unified Communications on Virtualized Servers
The clusters for SFO/ORD, SJC/RFD and parts of MCI/LAX run on virtual machines hosted on Cisco UCS B-Series Blade Servers and Cisco UCS C-Series Rack-Mount Servers. SAN based storage is used for the B-series servers and both SAN and direct attached (disk) storage are used with the C-series servers.
•One publisher/TFTP/MOH Server
•One subscriber
This site supports a mix of 1000 SIP and SCCP endpoints.
Call Routing and Dial Plan Distribution Using Call Control Discovery for the Service Advertisement Framework
The Call Routing and Dial Plan Distribution Using Call Control Discovery for the Service Advertisement Framework site model consists of sites Kansas City (MCI), Los Angeles (LAX) talking to San Jose (SJC) / Rockford (RFD) and San Francisco (SFO)/Chicago (ORD).
When multiple call processing agents are present in the same system, each can be configured manually to be aware of the others. This configuration can be time consuming and error prone. Call routing between the various call processing agents requires the configuration of static routes on the call agents and updating them when changes occur.
Instead, the Cisco Service Advertisement Framework (SAF) can be used to share call routing and dial plan information automatically between call agents. SAF allows non-Cisco call agents (such as TDM PBXs) to partake in the Service Advertisement Framework when they are interconnected through a Cisco IOS gateway.
Table 4 lists the hardware and software components used in the Cisco Service Advertisement Framework (SAF) Site.
Cisco Unified Communications Manager - Session Manager Edition Site
The Cisco Unified Communications Manager - Session Manager Edition site model contains two sites, Kansas City (MCI) and Los Angeles (LAX), designed to simulate Session Management Edition of the Unified Communications 8.5 system train.
This cluster includes:
•One publisher and one subscriber (MCI)
•Two subscribers (LAX)
This deployment model has the following characteristics:
•Mix platform with MCS & UCS: MCI site has IBM MCS servers, and LAX site has one IBM MCS server, and one UCS B-series based virtual server.
•Distributed call processing deployment model with Clustering over the IP WAN configuration.
•All non-SAF ICT SIP and H.323 (Non Gatekeeper) trunks configured on SME use Call routing enhancement option to run SIP trunks on every subscriber node in the cluster.
•All SIP trunks configured on SME cluster use SIP option PING to track the status of the configured destination of SIP trunks and only send SIP messages to reachable remote peers.
•SIP Early Offer Enhancement option is enabled on selected SIP trunks in SME and on leaf clusters.
•End-to-end (E2E) RSVP Call Admission Control: in SME test bed topology, there is only signaling traffic, no media traffic between SME and leaf clusters. All calls coming in from the leaf clusters and going out to the leaf clusters are not subjected to the location Call Admission Control in SME. RSVP agents on leaf clusters represent locations between leaf clusters, and are subjected to the RSVP Call Admission Control. Calls between SJC and DFW leaf clusters perform E2E RSVP Call Admission Control.
•The Service Advertisement Framework (SAF) deployed in the test bed, coexists with the SME cluster and enables leaf nodes to discover automatically other network services run on other leaf nodes through centralized SME cluster.
•Cisco Unified Border Element Scalability and Load Balancing: Cisco Unified SIP Proxy is used to provide a central route point for management of pair of Cisco Unified Border Elements, MCI-CUBE-1 & MCI-CUBE-2 in MCI side and LAX-CUBE-1 and LAX-CUBE-2 in LAX side of SME cluster. In Cisco Unified SIP Proxy, load balancing and rule-based routing is applied for ingress and egress traffic. Each pair of the Cisco Unified Border Element uses same configuration. If a CUBE is unavailable, Cisco Unified SIP Proxy can intelligently reroute to an alternate Cisco Unified Border Element. When the Cisco Unified Border Element returns to service, Cisco Unified SIP Proxy resumes sending traffic to the Cisco Unified Border Element.
Figure 5 shows the topology of this site:
Figure 5 Cisco Unified Communications Manager - Session Manager Edition (SME) Site Topology
Table 5 lists the hardware and software components used in this model.
Video enhancements
During this Release additional video testing is included in all of the site models. Testing included adding new Tandberg video endpoints and the Cisco TelePresence System 1000. Calls between the various video endpoints, including intracluster calls and intercluster calls, were tested along with supplementary services such as conference, transfer and hold.
Europe and Emerging Markets Site Models
Eight site models were created and tested for Cisco Unified Communications Release 8.6(1) testing for Europe and Emerging Markets (EUEM) IP telephony. Each site model tested specific hardware and software components, features, functions, protocols, and related items.
A site model includes a site with a three-letter name (for example, CDG, GVA, and MAD). Examples throughout this manual refer to these site names.
The following sections describe each site model in detail. Each section includes an explanation of the design characteristics of the site model, and includes a table that lists the hardware and software components used in the model. The tables contain the following information for each component:
•Component—Hardware or software component
•Description—Information such model number, release number, protocol, and hardware platform
•Qty.—Quantity of the component used in the model
Table 6 lists the site models and references to sections that provide detailed information.
Table 6 EUEM Site Models
Site Model and Reference Sites IncludedParis (CDG)
Geneva (GVA)
Cisco Unified Communications Manager Session Management Edition
Co-located in Paris (CDG-SME and Geneva (GVA-SME); Milan (MLN-SME)for Load testing
Brussels (BRU)
Madrid (MAD)
Cisco Unified Communications Manager Interoperability Site Centralized with Unified SRST
London (LGW)
Reykjavik (RKV)
Warsaw (WAW)
Manchester (MAN)
Bangalore (BLR)
For an illustration showing how these site models were deployed for testing, go to the Resource Library tab of the Technical Information Site.
Large Multisite Centralized with Unified SRST
The Large Multisite Centralized with Unified SRST site model consists of one site called Paris (CDG). This site model represents an international deployment with up to 21 remote sites deployed across various countries. It includes Cisco Unity Connection and third-party components. Cisco Unified Communications Manager uses QSIG, H.323, and SIP to interoperate between sites. Remote sites are interconnected through the WAN and all are RSVP-enabled to the central site. For Geneva (GVA) and Paris (CDG), inter cluster RSVP is enabled.
In this model, a Cisco Unified Communications Manager cluster serves 6000 phone in local and remote locations, with all endpoints and gateways fully encrypted (RTP and signaling). PBXs that support the QSIG ISO and QSIG ECMA variants connect to this cluster through direct QSIG links. The Cluster connects to the rest of the network through MPLS WAN networks.
Calls between the CDG site, the LGW site, and the MAD site are provided by H.323 intercluster trunks. Cisco Unity Connection provides voice messaging. PBX users access voice messaging features through the QSIG trunks to Cisco Unified Communications Manager.
Access to the PSTN for normal off-net calls is provided by ten E1 ETSI PRI links to the PSTN. Remote sites have either centralized breakout to the PSTN or local PSTN breakout using E1 PRI, BRI, or FXO connections. PSTN access is controlled by Cisco Unified Communications Manager using MGCP, H.323, or SIP. Unified SRST is used in each remote site.
Access to the SIP network is provided through a SIP trunk to a remote Cisco Unified SIP Proxy (CUSP). Access to third-party services such as operator console, if available, is provided locally. Some of the sites will also have video endpoints and Cisco Unified Videoconferencing Gateways, and remote QSIG PBXs.
Cisco Unified Communications Integration™ for Microsoft Office Communicator and Cisco Unified Presence Server are tested as part of this site model. Cisco Unified Communications Integration™ for Microsoft Office Communicator provides interoperability with Microsoft Office Communicator Server 2007 (OCS) R2 version with Microsoft Office Communicator (MOC) clients.
The Large Multisite Centralized with Unified SRST site model have these design characteristics:
•Cisco Unified Communications Manager cluster for redundancy and system scaling
•Inline power to IP phones
•Encryption of RTP, SIP, SCCP, and H.323 where available.
•SIP and SCCP phones
•Cisco Unified Communications Integration™ for Microsoft Office Communicator with Microsoft OCS 2007 R2 version with Microsoft Office Communicator clients
•Cisco Unified Enterprise Attendant Console Windows 2008 server on Cisco MCS 7825 Unified Communications Manager Appliance
•Cisco Unified Personal Communicator
•Quality of service from the desktop
•Video phones, MCUs, and Cisco Unified Videoconferencing H.320 Gateways in local and remote sites
•Locally connected third-party applications for attendant console
•Cisco Unity Connection connected through an SCCP link to Cisco Unified Communications Manager
•PBX connectivity to Cisco Unified Communications Manager and Cisco Unity through Cisco Unified Communications Manager using a direct QSIG trunks
•QSIG feature transparency between PBXs to PBX, PBX to Cisco Unified Communications Manager, Cisco Unified Communications Manager to PBX, and Cisco Unified Communications Manager to Cisco Unified Communications Manager clusters
•Cisco IME server to transport all Cisco IME calls over Cisco IME SIP trunks.
•Cisco Unified Communications Manager Session Management Edition to consolidate SIP trunks and application interfaces across multi vendor voice deployments
•Service Advertisement Framework (SAF) to advertise the DN pattern of Unified Communications Manager and Unified Communications Manager Express through Call Control Discovery so that other call control entities have access through the SAF network, thereby adapting their routing behavior.
•Central and remote PSTN breakout for remote sites with MGCP PRI, BRI, and FXO backhaul, and SIP and H.323 control
•Cisco RSVP Agent
Figure 6 shows the topology of the Large Multisite Centralized with Unified SRST Site model.
Figure 6 Large Multisite Centralized with Unified SRST Site Topology
Table 7 lists the hardware and software components used in the Multisite Centralized, Clustering over the WAN with Unified SRST site model.
Table 7 Large Multisite Centralized with Unified SRST Site Model Components
Component Description Qty.Datacenter Catalyst switch
WS-C6509-E
3
Analog gateway
Cisco ATA 187 Analog Telephone Adaptor
3
Cisco Unified Communications Manager Server
Cisco UCS B Series 7, Cisco Wallop C210M2-2, MCS 7835 Unified Communications Manager Appliance - 4
131
Firewall-ASA
Data center - 5510
1
Cisco IME - 5520
1
Cisco Unified SRST Routers
Cisco 2801
3
Cisco 2811
1
Cisco 2821
3
Cisco 2851
2
Cisco 3825
1
Cisco 3845
1
Cisco 7200
1
Cisco 2901
1
Cisco 3925
2
Cisco 3945
1
Cisco Unified Contact Center Express
Cisco B-series
2
Cisco Unified IP Phone
Cisco Unified IP Phone 7971G-GE
10
Cisco Unified IP Phone 7970G
10
Cisco Unified IP Phone 7961G/7961G-GE
5
Cisco Unified IP Phone 7941G/7941G-GE
5
Cisco Unified IP Phones models 6921, 6941, 6961
5
Cisco Unified IP Phone 8941
1
Cisco Unified IP Phone 8945
1
Cisco IP Communicator
2
Cisco Unified Communications Integration™ for Microsoft Office Communicator
6
Cisco Unified Personal Communicator
2
Cisco Unified IP Phones models 8961
5
Cisco Unity Connection
Cisco B-series
2
Core Catalyst chassis
WS-C6506-E
2
RSVP Agent
Cisco 3825
1
Cisco 1861
1
E1 gateway card
Cisco 3845
1
Gateway
Cisco 2801
2
Cisco 2811
2
Cisco 2821
2
Cisco 2851
2
Cisco 3825
2
Cisco 3845
2
Cisco 2901
1
Cisco 3925
2
Cisco 3945
1
PSTN Gateway
Cisco 3845
3
Access switch
WS-C3550-24PWR-SMI
3
WS-C3750-24PS-S
3
WS-C3750-48PS-S
2
Router
Cisco 7206-VXR
1
Video conferencing
Cisco Unified Videoconferencing MCU 3545
2
Video endpoint
Cisco Unified Video Advantage
4
Cisco IP Phone 7985
5
Cisco Unified IP Phones models 9951and 9971, Tandberg E20, Tandberg EX90 and Tandberg MXP 1700
5
Tandberg Codian MCU
Tandberg Codian 4501
1
Video MCU and Gateway
IPVC-3545-CHAS
1
1 Divided into two Unified Communications Manager clusters: one main cluster consisting of 11 servers and a second smaller cluster of two servers supporting the Unified Contact Center Express server and agent phones.
Medium Site Centralized with Unified SRST
The Medium Site model consists of one centralized site with three SRST remote sites called Geneva (GVA). In this model, a Cisco Unified Communications Manager cluster serves 2000 phones. The Cisco Unified Communications Manager cluster connects to the rest of the network through MPLS WAN networks.
A local Cisco Unity Connection provides voice messaging services for local PBX and Cisco Unified Communications Manager users. Access to the PSTN for normal off-net calls is provided by five E1 RTSI PRI links to the PSTN. Access to other sites and to services such as Cisco Unified MeetingPlace Express is provided by H.323 gatekeeper controlled trunks and an IP-to-IP gateway. Access to the SIP network is through a SIP trunk to a remotely located Cisco Unified SIP Proxy (CUSP). Third-party operator consoles are provided on Cisco Unified Communications Manager to serve local phones and to provide backup to the operator console in the CDG site.
The Medium Site model has these design characteristics:
•Cisco Unified Communications Manager cluster for redundancy and system scaling
•Inline power to IP phones
•SIP and SCCP phones
•Quality of service from the desktop
•Locally connected third-party applications for attendant console, billing, and voice recording, if available
•Cisco Unified Communications Integration™ for Microsoft Office Communicator with Microsoft OCS 2007 R2 version with Microsoft Office Communicator clients
•Cisco Unified Personal Communicator
•Cisco IME server to transport all Cisco IME calls over Cisco IME SIP trunks.
•Cisco Unified Communications Manager Session Management Edition to consolidate SIP trunks and application interfaces across multi vendor voice deployments
•Service Advertisement Framework (SAF) to advertise the DN pattern of Unified Communications Manager and Unified CME through Call Control Discovery so that other call control entities have access through the SAF network, thereby adapting their routing behavior.
•Cisco RSVP agent is enabled
•Cisco Unified Communications Integration™ for Real Time eXchange and Real Time eXchange (RTX) server.
•VG30D
Figure 7 shows the topology of the EUEM Medium Site model (GVA).
Figure 7 EUEM Medium Site Topology
Table 8 lists the hardware and software components used in the Medium Site model.
Cisco Unified Communications Manager Session Management Edition
The Cisco Unified Communications Manager Session Management Edition deployment is a variation of multisite distributed call processing deployments model, which interconnects large numbers of Cisco Unified Communcations systems. In the EUEM sites, the Unified Communications Manager Session Management Edtion deployments consists of two sites: Paris (CDG-SME) and Geneva (GVA-SME). For load testing, another site is used: Milan (CDG-SME). The MLN-SME cluster is a centralized Session Manager Edition cluster. The MLN-SME consists of MLN (Unified Communications Manager Servers), MLN Cisco Unity Connection server, PSTN. The MLN-SME cluster is connected to CDG, GVA, MAD, and RKV leaf through SAF enabled QSIG over SIP trunks. The MLN-SME cluster is connected to CDG, GVA, and LGW through H323 Annex M1 trunk.
The IPT-SI deployment for Cisco Unified Communications Manager Session Management Edition can be explained as follows:
In this deployment there are two Unified CM-SME clusters namely CDG-SME cluster and GVA-SME cluster, CDG-SME cluster is co-located with CDG site and aggregates trunks (SIP, H.323, QSIG, and QSIG over SIP) from the CDG leaf node, MAD eaf node and LGW leaf node. The GVA-SME cluster is co-located with GVA site and aggregates trunks (SIP, H.323, QSIG, and QSIG over SIP) from the GVA leaf node, RKV leaf node and Brussels leaf node.
CDG-SME cluster and its leaf nodes (CDG, CDG-remotes, MAD) are running in the SAF Autonomous system 333 and GVA-SME cluster and its leaf nodes (GVA, RKV, Brussels) are running in the SAF Autonomous system 444, at present we have NOT enabled static re-distribution between the two SAF's.
Cisco Unity Connection server provides voice mail services to Unified Communications Manager, Unified CM-SME, and remote users.
Service Advertisement Framework (SAF) and Session Management Edition (SME) Setup: SAF allows networking applications to discover the existence, location, and configuration of networked services (Call Control Discovery) within networks by using the underlying network as a transport for service advertisements
Cisco Unified Communications Manager Session Management Edition: Cisco Unified Communications Manager-SME is essentially a Unified Communications Manager clusters supporting a large number of trunk interfaces and enables the aggregation of multiple UC systems using multiple trunk types for voice, video and fax calls
The focus of SAF testing for Fairborn release is centered on combining the Cisco Unified Communications Manager-SME (Centralized Architecture) and SAF (Distributed Architecture)
Milan (MLN-SME) site
The MLN-SME cluster is a centralized Session Manager Edition cluster. The MLN-SME consists of MLN (Unified Communications Manager Servers), MLN Cisco Unity Connection server, PSTN. The MLN-SME cluster is connected to CDG, GVA, MAD, and RKV leaf through SAF enabled QSIG over SIP trunks. The MLN-SME cluster is connected to CDG, GVA, and LGW through H323 Annex M1 trunk.
The MLN-SME cluster Site model has these design characteristics:
•GVA-SME cluster (Unified Communications Manager Session Management Edition servers)
•Cisco Unity Connection for voicemail
•PSTN Gateway
Paris (CDG-SME) site
The CDG-SME cluster consists of CDG leaf cluster (Unified Communications Manager Servers), Cisco Unity Connection server, Gateways and Gatekeepers. The CDG-SME cluster is connected to MAD leaf cluster through a QSIG SIP trunk and to the LGW leaf cluster through H.323 Annex M1 trunks. There are two QSIG SIP trunks configured between CGD leaf and CDG-SME cluster and also between CDG-SME and MAD leaf cluster. One of the SIP trunks is a SAF enabled SIP trunk and the other is a static SIP trunk.
When a call is made from CDG (leaf) to MAD (leaf) via CDG-SME cluster, first leg from CDG (leaf) to CDG-SME cluster will be SAF trunk and second leg from CDG-SME cluster to MAD (leaf) will be static SIP (QSIG) trunk.
The CDG-SME cluster Site model has these design characteristics:
•CDG Leaf cluster (Unified Communicatons Manager servers)
•CDG-SME cluster (Unified Communicatons Manager Session Management Edition servers)
•Cisco Unity Connection for voicemail
•Gateways (Cisco Unified Border Element, Cisco 3545 MCU) and Gatekeepers (Cisco 3845)
•Static QSIG SIP trunk between CDG leaf and CDG-SME cluster
•SAP enabled QSIG SIP trunk between CDG leaf and CDG-SME cluster
•Static QSIG SIP trunk and SAP enabled QSIG SIP trunk between CDG-SME and MAD leaf cluster
•H.323 Annex M1 trunk between CDG-SME cluster and LGW leaf
Geneva (GVA-SME) site
The GVA-SME cluster consists of GVA leaf cluster (Unified Communications Manager Servers), Cisco Unity Connection server, Gateways and Gatekeepers. The GVA-SME cluster is connected to RKV leaf through SAF enablaed SIP trunks and to the BRU leaf through both statis SIP trunk and SAF enabled SIP trunk.
The GVA-SME cluster Site model has these design characteristics:
•GVA Leaf cluster (Unified Communicatons Manager servers)
•GVA-SME cluster (Unified Communicatons Manager Session Management Edition servers)
•Cisco Unity Connection for voicemail
•Gateways (Cisco Unified Border Element) and Gatekeepers (Cisco 3845)
•Static QSIG SIP trunk between GVA leaf and GVA-SME cluster
•SAP enabled QSIG SIP trunk between GVA leaf and GVA-SME cluster
•Static QSIG SIP trunk and SAP enabled QSIG SIP trunk between GVA-SME and BRU leaf cluster
•SAP enabled QSIG SIP trunk between GVA-SME cluster and RKV leaf
•Analog Gateway (VG30D)
Figure 8 shows the topology of the Unified Communications Manager Session Management Edition depolyment model (EUEM site)
Figure 8 Unified Communications Manager Session Management Edition deployment model (EUEM) site Topology
Table 9 lists the hardware and software components used in the Unified Communications Manager Session Management Edition depolyment model (EUEM site).
Medium Site Dual-stack Centralized with Unified SRST
The Medium Site Dual-stack Centralized with Unified SRST (Brussels-BRU) consists of one site called Brussels (BRU) for IPT-SI testing. However, load testing is based on the Cisco Unified Communications Manager on Unified Communications System.
In this model, two servers—Cisco Unified Communications Manager Linux based Unified Communications Manager clusters serve 1000 phone users in both local and remote locations. The publisher is on Cisco Services Ready Engine module and the subscriber is on the MCS hardware.
A separate Cisco Network Registrar (CNR) server is used to provide DHCP IPv4/IPv6 addressing for the central site. It also acts as the DNS IPv6 and IPv4 for both the central and remote sites. This cluster is connected to the rest of the network through MPLS WAN networks.
Calls between this site and other sites (to CDG site and SME) sites are made through the WAN with Annex M1 Inter Cluster Trunks. All the internal calls within the site are G.711 and all calls between sites are G.729.
Cisco Unity Connection server provides voice mail services to both Unified Communications Manager and remote users. Access to the PSTN for normal "off-Net" calls is provided by E1 ETSI PRI links to the PSTN.
The three remote sites are connected through a WAN link and they have location based CAC to the central site. PSTN access for these remote sites either have centralized breakout to the PSTN, or local PSTN breakout using E1 PRI, BRI, or FXO connections and are controlled by Unified Communications Manager using either MGCP, H.323, or SIP. Unified SRST is used in each remote site.
Some of the phones have security encryption. VG224 acts as dual-stack gateways and Cisco 2851 acts as analog SCCP gateway.
There is a central 3945 router which hosts the SRE module. Apart from that it acts as the Central PSTN gateway,SRST failover and RSVP agent as well.
The LAN infrastructure of this site includes CAT4500 as distribution/core switch and Cisco 3750 and Cisco 3560 as access switches and both of them are dual-stack components.
The MTP component provides media stream conversion from IPv4 to IPv6 and vice versa. The CE router and the MTP component share the same hardware—Cisco 3845.
The CE router and the remote ISRs provides IPv6 to IPv4 tunneling over the WAN. One of the SRST remote has been enabled with HSRPv6 (active-active) and DHCPv6.
The Medium Site Dual-stack Centralized with Unified SRST (Brussels-BRU) Site model has these design characteristics:
For BRU Central Site:
•Publisher (PUB - Located on the Cisco SRE), Subscriber (SUB), and Cisco Network Registrar (CNR)
•Dual Stack LAN Infrastructure: Cat4500 with Sup VI (Distribution/Core) along with Cisco 3750 and Cisco 3560 (Access).
•IPv4 Gateway: MGCP (Cisco 3945 Integrated Services Router)
•IPv6 Gateways: Analog SCCP GWs (ISR 2851), VG224
•Application [IPv4]: Cisco Unity Connection
•Security: sRTP/TLS on BRU site + remote (Not 100% of Phones)
•Legacy/DS phones and SCCP IPv4 video phone.
•CE Router + MTP [IPv4-IPv6] on the same ISR 3845 router.
•WAN IPv4: CE router supports IPv6 over IPv4 tunneling across WAN
•QSIG ICT and QoSIP ICT to CDG and Unified SME
For BRU Remote:
•Remote sites - H.323, MGCP and SIP IPv6 and provide location based CAC (No call counting) with different CODECs
•IPv6 remote site has dual homing [Active/Active]
•MGCP remote site to have CUE
•Legacy / DS phones + SCCP IPv4 video phone
•Security: sRTP/TLS (Not 100% of IP Phones)
Figure 9 shows the topology of the EUEM Small Site model.
Figure 9 Medium Site Dual-stack Centralized with Unified SRST Topology
Table 10 lists the hardware and software components used in the Medium Site Dual-Stack Centralized with Unified SRST model.
Small Site (MAD)
The Small Site model for Europe and Emerging Markets consists of one site called Madrid (MAD). In this model, a Cisco Unified Communications Manager cluster serves 750 phones in a single campus. A PBX that supports the ISO QSIG variant connects to this cluster through direct QSIG links.
Cisco Unity Connection connects to the cluster through the QSIG-enabled intercloster trunk via the LGW site and provide voice messaging functions to PBX users and to Cisco Unified Communications Manager users. PBX users have access to Cisco Unified Communications Manager through a QSIG trunk.
The Cluster connects to the rest of the network through MPLS WAN networks. Calls between this site and other sites in the network are made through the WAN with two Annex M1 intercluster trunks to the CDG and LGW sites.
Access to the PSTN as a backup route to other sites and for normal off-net calls is provided by two E1 ETSI PRI links to the PSTN.
The Small Site model has these design characteristics:
•Cisco Unified Communications Manager cluster for redundancy and system scaling
•Inline power to IP phone sets
•SIP and SCCP phones
•Cisco Unified Communications Integration™ for Microsoft Office Communicator with Microsoft OCS 2007 R2 version with Microsoft Office Communicator clients
•Quality of service from the desktop
•Cisco Unity Connection, with the server located remotely and connected through QSIG and intercluster trunk to Cisco Unified Communications Manager
•PBX connectivity to Cisco Unified Communications Manager, Cisco Unity Connection, and the rest of the network through Cisco Unified Communications Manager using a direct QSIG trunks
•PBXs that support the QSIG ISO and QSIG ECMA variants connect to this cluster through direct QSIG links.
•QSIG feature transparency between PBXs to PBX, PBX to Cisco Unified Communications Manager, Cisco Unified Communications Manager to PBX, and Cisco Unified Communications Manager to Cisco Unified Communications Manager clusters.
Figure 10 shows the topology of the EUEM Small Site model.
Figure 10 EUEM Small Site Topology
Table 11 lists the hardware and software components used in the EUEM Small Site model.
Cisco Unified Communications Manager Interoperability Site Centralized with Unified SRST
The Cisco Unified Communications Manager Interoperability Site model for EUEM consists of one site called London (LGW). In this model, a Cisco Unified Communications Manager cluster serves 2,000 phones in a single campus. A PBX that supports the ISO QSIG variant connects to this cluster through direct QSIG links.
The Cluster connects to the rest of the network through MPLS WAN networks. Calls between this site and other sites in the network are made through the WAN with two Annex M1 intercluster trunks to the CDG and MAD sites.
Some PBX and Cisco Unified Communications Manager users have voice messaging services provided by Cisco Unity Connection, which is connected to the cluster through an SCCP link. The PBX user access voice messages through QSIG trunks to Cisco Unified Communications Manager.
Other PBX and CCM users have access to voice messaging with Unity Connection located in the CDG Site via the Annex M1 Inter Cluster Trunk. MWI events and message store and retrieval for both the connected PBX and the CCM users is all passed Annex M1 between the sites.
Access to the PSTN as a backup route to other sites and for normal off-net calls is provided by 5 E1 ETSI PRI links to the PSTN. Access to the Cisco Unified Communications Manager network, and any non-directly connected clusters is provide through remotely located H.323 gatekeepers. Access to the SIP network is provided through a SIP trunk to a remotely located Cisco Unified SIP Proxy (CUSP). Operator console services are provided locally
The Cisco Unified Communications Manager Interoperability Site model has these design characteristics:
•Cisco Unified Communications Manager cluster for redundancy and system scaling
•Inline power to IP phones
•Quality of service from the desktop
•Cisco Unity Connection, with the server located remotely and connected through an SCCP link to Cisco Unified Communications Manager
•Cisco Unity Connection voice messaging located remotely, with access provided through Annex M1 intercluster trunk from the Large Multisite Centralized with Unified SRST cluster
•Cisco Unified Enterprise Attendant Console Windows 2003 Server on HP ProLiant DL320
•PBX connectivity to Cisco Unified Communications Manager and to Cisco Unity Connection through Cisco Unified Communications Manager using a direct QSIG trunks
•QSIG Feature transparency between PBXs to PBX, PBX to Cisco Unified Communications Manager, Cisco Unified Communications Manager to PBX, and Cisco Unified Communications Manager to Cisco Unified Communications Manager clusters.
Figure 11 shows the topology of the EUEM Cisco Unified Communications Manager Interoperability site model.
Figure 11 EUEM Cisco Unified Communications Manager Interoperability Site Topology
Table 12 lists the hardware and software components used in the EUEM Cisco Unified Communications Manager Interoperability Site model.
Cisco Unified Communications Manager Interoperability Site (Cisco SIP CME Site Aggregated by Cisco Unified SIP Proxy)
The Small Campus SIP only Multisite model consists of one site called Reykjavik (RKV). This model includes three Cisco Unified Communications Manager Express (Unified CME) sites aggregated by a Cisco Unified SIP Proxy (CUSP) module running on a Cisco 3825 gateway router. The Cisco Unified SIP Proxy is a high-performance, highly available stateless Session Initiation Protocol (SIP) server for centralized routing and SIP signaling normalization. Each Unified CME is connected to Cisco Unified SIP Proxy module through SIP trunks. The Cisco Unified SIP Proxy is connected to other Unified Communications Manager clusters in CDG and GVA sites through SIP trunks. SIP RSVP features are configured on the Unified CME routers for RSVP between Unified CME phones and Unified Communications Manager cluster phones.
The Small Campus SIP only Multisite model has these design characteristics:
•Inline power to IP phones
•Remote access to other Unified Communications Manager clusters (CDG and GVA) through SIP trunks
•RSVP between Unified CME phones and Unified Communications Manager cluster phones
Figure 12 shows the topology of the Non-Cisco Unified Communications Manager Interoperability Site model.
Figure 12 Non-Cisco Unified Communications Manager Interoperability Site Topology
Table 13 lists the hardware and software components used in the Non-Cisco Unified Communications Manager Interoperability Site model.
Small Campus Multisite H.323
The Small Campus Multisite H.323 site model consists of one site called Warsaw (WAW). This model includes 13 Cisco Unified Communications Manager Express sites connected to each other and to the rest of the network through H.323 gatekeepers. Each Cisco Unified Communications Manager cluster uses an IP-to-IP gateway and MTP to communicate with the Cisco Unified Communications Manager Express systems in this site.
Each Cisco Unified Communications Manager Express system has either Cisco Unity Express installed locally, or will access Cisco Unity Connection through an MWI relay gateway that is located in the GVA site.
The Small Campus Multisite H.323 model has these design characteristics:
•Inline power to IP phones
•Quality of service from the desktop
•Cisco Unity Connection, connected through MWI relay gateway
•Remote access through H.323 gatekeepers to other Cisco Unified Express clusters and servers
Figure 13 shows the topology of the Small Campus Multisite H.323 site model.
Figure 13 Small Campus Multisite H.323 Site Topology
Table 14 lists the hardware and software components used in the Small Campus Multisite H.323 model.
Mid-Market Multi-Site Centralized (Unified CMBE)
The Mid-Market Multi-Site Centralized cluster consists of one centralized site with five SRST remote sites called Manchester (MAN). This model includes Cisco Unified Communications Manager and Cisco Unity Connection running on co-resident deployment on a single Cisco MCS 7828 Unified Communications Manager Appliance server. A separate Windows 2008 server acts as the DNS server for both central and remote sites. DHCP is provided by the remote and central Cisco ISRs.
In this model, a Cisco Unified Communications Manager cluster serves 500 phone users in local and remote locations, with the Cisco Unity Connection in the central site providing the voice mail services. Operator console (CUBACS) is provided separately on a local server in the central site.
The Central site is connected to the remote SRST sites through MPLS WAN networks. All calls within central site or within remote sites are G.711 and calls between remote sites and central site are G.729a with 30 ms packetisation period. If the Unified Communications Manager in central site goes down, all central site phones will re-register to a SRST router in central site and all remote site phones will register to the corresponding remote site SRST routers.
Access to the PSTN for normal "off-Net" calls is provided by E1 ETSI PRI/BRI links to the PSTN. The five remote sites are connected through WAN network and have RSVP setup for CAC to the central site. PSTN access for these remote sites either have centralized breakout to the PSTN, or local PSTN breakout using E1 PRI, BRI, or FXO connections and are controlled by Unified Communications Manager using either H.323 or SIP.
Central site uses MGCP PRI for Central PSTN.
The Mid-Market-Multi-Site Centralized site model has these design characteristics:
•Cisco Unified Communications Manager Business edition (Unified CMBE)
•Inline power to IP phones
•Cisco Unified Contact Center Express (UCCX)
•Cisco Unified Presence Server 8.0
•Cisco Unified Personal Communicator 7.0 and 8.0 versions
•SIP end points and Video end points
•Microsoft OCS 2007 R2 server
•Cisco Unified Business Attendant Console Windows 2008 Server on MCS 7825 Unified Communications Manager
Figure 14 shows the topology of the Mid-Market-Multi-Site Centralized site model.
Figure 14 Mid-Market Multi-Site Centralized Site Topology
Table 15 lists the hardware and software components used in the Mid-Market Multi-Site Centralized site model.
Mid-Market Multi-Site Centralized (Unified CMBE 3000)
The Mid-Market Multi-Site Cisco Unified Call Manager Business Edition 3000 consists of one centralized site with two remote sites. This model includes Cisco Unified Call Manager Business Edition 3000 (Unified CMBE 3000) deployed in centralized site running on Cisco MCS 7890 with in-built internal gateway which supports dual T1/E1 interfaces, in addition to one CEN 2901 external Gateway with one E1 interface. A separate Windows 2008 server acts as the DNS server for both central site and remote site. DHCP is provided by the remote and central Cisco ISRs.
In this model, a Cisco Unified Call Manager Business Edition 3000 serves 300 users (400 phones) in Central and in two remote sites. The in-built Cisco Unity Connection and Auto-Attendant provides the voice mail services and auto-attendant services respectively to central and remote site users.
The Central site is connected to the remote sites through MPLS/WAN networks. All calls within central site or within remote sites are G.711 and calls between remote sites and central site are G.729. Transcoding and conference resources are provided by Unified CMBE 3000 internal resources, while there is no support on 2901 external gateways.
In central site, access to the PSTN is provided by Unified CMBE 3000 dual internal E1 ETSI PRI links and CEN 2901 GW E1 ETSI PRI link to the PSTN. The two remote sites are connected through WAN network. PSTN access for the remote site1 uses centralized breakout to the PSTN, since it doesn't have local PSTN Gateway, while Remote site2 uses local PSTN breakout using its own E1 PRI connections and/or it uses the centralized breakout to the PSTN using the Unified CMBE 3000 dual internal E1 ETSI PRI links and/or CEN 2901 Gateway E1 ETSI PRI link to the PSTN. These remote sites are controlled by Unified CMBE 3000 using SIP. Enabled Logical Partitioning across all the sites. Emergency calls are supported default with Unified CMBE 3000.
The Mid-Market-Multi-Site Centralized (Unified CMBE 3000) site model has these design characteristics:
•Cisco Unified Call Manager Business edition 3000
•External 2901 Gateways
•Inline power to IP phones
•Cisco Unified Communications Integration for RTX
•Cisco Unified IP Communicator
•Cisco Unified IP Phones
Figure 15 shows the topology of the Mid-Market-Multi-Site Centralized (Unified CMBE 3000) site model.
Figure 15 Mid-Market-Multi-Site Centralized (Unified CMBE 3000) site Topology
Table 16 lists the hardware and software components used in the Mid-Market Multi-Site Centralized (Unified CMBE 3000) site model.