This presentation discusses market trends and its impact on Network infrastructure, Cisco carrier Ethernet Transport Architecture, Cisco carrier Ethernet portfolio and TCO Leadership.
- 1. The NGN Carrier Ethernet System:Technologies, Architecture
and Deployment Models Biren Mehta Sr. Marketing Manager
2. Agenda Market Trends and its Impact on Network Infrastructure
Cisco Carrier Ethernet Transport Architecture Cisco Carrier
Ethernet Portfolio TCO Leadership Closing Remarks 3. Market
Dynamics & TrendsAffecting Next Generation InternetTraffic
DeviceEmergence ofGrowthProliferationCloud 4X volume growth
(2010-2015) 12 Billion IP Video capable devices by 2015 $43 Billion
cloud services revenue by 2013 80.5 Exabyte per month in 2015 ~ 1
mobile device per capita (7.2B) by 2015 Midmarket firms are more
likely to migrate 90%+ will be video 3 Billion IPv6 ready mobile
devices by 2014 to the cloud 4. Shifting Revenue &
TrafficAffecting Next Generation Internet90+%2011 2013 2016IP
Traffic Private LinePrivate Line Private LineTDM/OTN
TDM/OTNTDM/OTNTraffic TrafficTraffic~50-70%* 20-30%
010%CircuitPacketPrivate/Public Private/Public Private/PublicIP
Traffic IP TrafficIP Traffic Packet Legacy TDM~30-50%70-80%
90+%Traffic SP revenue shifting from circuits to packet services**
5 yrs ~80% revenue derived from packet services Packet traffic
increasing at 34% CAGR***, Mobile traffic at 78% CAGR**** Massive
change in SP traffic make-up in next 5 years**ACG Research 2011, **
Cisco Research 2010, ***Cisco VNI 2011, ****Cisco Mobile VNI 2012
5. Traditional Carrier Ethernet ArchitectureBusiness Ethernet
Services Overlay on IP Service NetworkSP ServicesThird Party
Content Single-Service Ethernet TransportCore Single-Path Business
Business Edge Single-AccessAccessFiber Access BusinessBusiness 6.
Next Generation Carrier Ethernet ArchitectureConverged
Infrastructure for Any Service to Any Access SPThird-PartyAny
Service ContentContentConsumer, Business, Wholesale, Mobile,
CloudNational IP CoreNationalAny Path Data Center/Data Center/
Cloud/VHO Cloud/VHOClient to Client Business to Business Cloud to
Cloud Regional Regional Data EdgeDataCenter/VSO Center/VSOAny
Access UnifiedEthernet , PON, Cable, DSL, Access WirelessBusiness
Home 7. Trends Posing Network ChallengesSP Services/Third-Party
Services/ ContentContent The Challenges? Challenges?National Data
Center/ CoreIncreasing ComplexityNational Data Center/ do I cost
efficiently scale to meet How Cloud/VHO Cloud/VHO current and
future network demandsRegionalDataEdge RegionalRising Costs Data
Center/VSOHowcan I cost economically offer Center/VSO business,
residential, mobile services overa converged infrastructureMetro
(Access/Agg)Limited FlexibilityHow can I simplify the network
whileMulti-point improving network economics? BusinessRequiring
Carrier Ethernet Networks to Evolve 8. Packet Vs. TDM
TransportChart from Infonetics, Text from DTTDM transport of
packets is no longer economicallyviable, lacks statistical
multiplexing which makes it veryexpensiveFull transformation to NGN
needsto occur from core to customerLong term vision is critical,
this will be the network for thenext decadeWhat is the most
effectivetechnology choice that will: Minimize CapEx and OpEx?
Provide carrier class service delivery? Maximize service agility?
Carriers want the deterministic attributes of transport networks
with the flexibility of the internet 9. NGN Carrier Ethernet
Transport Direction CharacteristicSONETOptical Electrical PBB-TE
MPLS-TPIP/MPLS OTNOTN/ (ROADMs) SDH Eline (10GE) Eline (sub
10GE)Ethernet E-Tree E-LANCisco focuses on IP/MPLS for the
F/RCarrier Ethernet TransportLegacy ATMarchitecture. TDM L3VPNCisco
targets MPLS-TP for the L3 Unicast POTS and Access Networks whileIP
L3 Multicastsupporting already Ethernet Bridged Content Traffic
EngineeringAccess 50ms restorationCisco also addresses MPLS to the
Multiplexing TechnologyTime Wave Division Time Division Statistical
Statistical StatisticalGeneral Division access with Unified MPLS
UNI processingLimitedNoneNone Typically rich Typically rich
Typically rich GranularityVC-4 Lambda ODUVariable Variable Variable
Technology Maturity 10. L2 TransportTechnology Review Two
technologies for L2 transport over MPLS: Ethernet over MPLS
(EoMPLS) Used for L2 point-to-point link over MPLS cloud No MAC
learning involved Virtual Private LAN Services (VPLS) Used for
multipoint L2 connections Collection of pseudowires tied together
by a Virtual ForwardingInterface (VFI) MAC addresses learned on VFI
Traffic forwarding based on destination MAC addresses H-VPLS, an
extension of VPLS11 11. EoMPLSTechnology ReviewTunnelEthernet VC
label labelPDUPseudowire Ethernet Ethernet PDU PDU MPLSAttachment
CircuitAttachment CircuitLDP P LDPAggregationP Aggregation
NodeNodeAccess Node Access Node Targeted LDP FTTB CPEFTTB CPE MPLS
in the aggregation network and core Targeted LDP session between
PEs to exchange VC label Tunnel label is used to forward packet
from PE to P to PE VC label is used to identify L2VPN circuit
Attachment Circuit (AC) can be port-based or VLAN-based (or
Ethernet Flow Point based, see later)12 12. VPLSTechnology
ReviewMPLS AggregationAggregation Access NodeAccess Node NodeCore
NodeVFIVFIAttachmentCircuitAggregationVirtual Forwarding VFI
Instance Ethernet PortNode or VLAN Eompls Virtual
Circuit(Pseudowire) Attachment Circuit (AC)Connection to
Aggregation using an Ethernet VLAN Virtual Circuit
(Pseudowire)EoMPLS tunnel between PEs using a full mesh Virtual
Forwarding Instance (VFI)A virtual L2 bridge instance that connects
ACs to VCs (PWs); VFI=VLAN=broadcast domain Enhanced with BGP based
Autodiscovery (RFC607) Scalability issues almost solved via H-VPLS
and state-of-the-art NPU technology (2M MAC address/chip) 13 13.
What is MPLS-TP? MPLS-TP MPLS Transport Profile Subset and
extension of current MPLS functions Connection-oriented transport
based on MPLS protocols combined with transport style OAM and
protectionmechanismsData Plane Control Plane Standard MPLS
Forwarding NMS provisioning option Bidirectional P2P and P2MP LSPs
GMPLS control plane option No LSP merging PW control plane option
PHP optional Standard PW (SS-PW, MS-PW)OAMResiliency In-band OAM
channel (GACH) Sub-50ms protection switch over Connectivity Check
(CC): proactive (BFD) 1:1, 1+1, 1:N path protection Connectivity
Verification (CV): reactive (BFD) Linear protection Alarm
Suppression and Fault Indication with AIS (new tool), RDI Ring
protection(BFD), and Client Fault Indication (CFI) Performance
monitoring, proactive and reactive (new tools) 14. Business
Services ArchitectureOptimal Edge and Access Independence
Centralised Service Edge MPLS/Multicast VPN EoMPLSPWEoMPLS
Pseudowire EVPN or VPLS Ethernet, TDM, ATM UNI FR, HDLC, PPP, ATM
IP interworking AToMDistributed Service EdgeMPLS/Multicast VPN MPLS
PWE3EVPN or VPLS Ethernet, TDM, ATM UNI FR, HDLC, PPP, ATM IP
interworking AToMEfficient Large Scale Multiservice Access Network
Aggregation NetworkCore Network TR101 MLSService Edge Node* Access
Node VPWS, VPLS, VPLS LSMMPLS/IPService Edge Node Core Node Access
NodeAggregation Node xDSL, xPON, Ethernet MPLS/IP over DWDMPPP, IP,
MPLS MPLS 15. Residential Services ArchitectureOptimal Service Edge
PlacementCentralised Service Edge, HSI, VoIP, Video unicast
TransportEoMPLS EoMPLS PWPseudowireMPLS/IP (PIM or
mLDP)MPLS/Multicast VPN (mLDP)MVRVPLS LSM: P2MP PW, mLDP LSP IP,
PPPoE SessionsVFIVFI with IGMP snooping, MVR, IGMP Admission
ControlIPTV Transport Access Node UNI: Non Trunk, N:1 or 1:1
VLAN;IP PIM, MLDP or mLPD VPN may be used if no
wholesaleDistributed Service Edge3play Unicast PWE3MPLS/IP (PIM or
mLDP)PWE3 IP, PPPoE Sessions MPLS/Multicast VPN (mLDP)VFIIP TV
EfficientLarge ScaleMultiserviceAccess NetworkAggregation
NetworkCore Network TR101 MLS Service Edge Node* Access Node VPWS,
VPLS, VPLS LSMMPLS/IP Service Edge NodeCore NodeAccess
NodeAggregation NodexDSL, xPON, EthernetMPLS/IP over DWDMPPP, IP,
MPLSMPLS 16. Mobile Transport Services ArchitectureSimplified,
Scalable, and OptimizedBSCATM RNCTDM BTS, ATM NodeBATM or TDMS1-U
SAE GatewayIP eNB Mobile Transport Gateway MME V4 or v6 MPLS VPN
S1-C X2-C, X2-U Mobile Transport GatewaySAE Gateway Access
NetworkAggregation NetworkCore Network Mobile Transport Gateway
ASR9000 IP/MPLS TransportIP/MPLS TransportIP/MPLS TransportCell
Site GatewayAggregation NodeAggregation Node Core Node Core
NodeFiber or uWave Link, RingDWDM, Fiber Rings, H&S,
Hierarchical Topology DWDM, Fiber Rings, Mesh Topology 17.
Architecture ComparisonsWhich one to choose? The architectures
options can be evaluated against the following criteria Capital
Expenditures Scalability (Bandwidth / Subscriber, Transport, Policy
Control) Operational Complexity (Troubleshooting, QoS) Reuse of
existing Operations procedures Availability Traffic Patterns
Economically serving areas of differing subscriber density Service
Flexibility Operational Flexibility 18 18. Cisco Carrier Ethernet
PortfolioIntelligent, Scalable, Reliable, and Lowest TCO Cell
RouterAggregationMobile Edge IP Core Flexible scalability: network
virtualized (nV), any service, any transport Proven performance and
reliability: Superior voice & video quality with service
assurance Operational excellence: Unified management, lower OpEx,
and lower power consumption1 0 0 Ti m e s t he C a pa c i t y f or
a Fr a c t i on of C ur r e nt C os t 19. ASR 9000Future Proof Edge
PortfolioASR 9922 Cisco Prime IP NGN48Tb Per Chassis 20 linecard
slots 44 RU N:1 Switch Fabric Redundancy 11+1 DC Power Module
Option 8+8 AC Power Module Option A to Z management 71 Integrated
Services ModulenV TechnologyIntegrates multiple platforms62into a
single virtual system Offer virtualized applications 24x10GE ASR
9000v5 380g Capacity 4x10GE Uplinks 44x1GE Downlinks4Redundant
-24v/48v DC Single AC power feedLinerate 10GE2x100GE Industrys
First 2x100GE for Edge 20. ASR 9000 System nV Technology ASR
9001ASR 9006ASR 9010 ASR 9922 2 RU6 slots ( rack)10 slots ( rack)22
slots (full rack)LC / Chassis Up to 12x10GE 4 LC + 2 RSP8 LC + 2
RSP 20 LCBW / Chassis 120 Gb 240 Gb 3.2 Tb 6.4 Tb 6.4 Tb 12.8 Tb 48
Tb 96 TbnV Technology Availability CY12 CY12 CY12CY12 Double your
system capacity by upgrading any ASR 9000 product to an ASR 9000
System 21. ASR 9000 System BenefitsPowered by nV
technologyMulti-DimensionalScale 96 Tb capacity184,320 GigE
ports1,920 10 GigE ports480 100 GigE portsSimplifyServiceOperations
Single management entity: Edge to AccessVelocity Zero touch
configuration Network virtualization: Edge to Access Integrated
Traffic analyticsSingle click upgrade 22. Expanding the ASR Family
2G,3G,4G ReadyUnifiedMPLSUnifiedEthernetExtending nV to the Access
Architectu reAccess Pre-Aggregation 3RU, 360G Switching Capacity
(Unified Ethernet Access) Fully Redundant (RSP,PSU, FANs) SyncE,
1588 300mm, Environmentally Hardened ASR 903SP Edge Cell Site
Router(Small Deployments) (2G, 3G, 4G Ready) 2RU, 120G Switching
Capacity1RU, 16G System CapacitynVASR 901 4 Fixed 10GEASR 54W
GE+TDM, 38W GE MPAs: 20x1GE, 2x10GE 9001 Enabled SyncE, 1588 SyncE,
1588300mm, Environmentally HardenedSimplify, Unify, Virtualize
Access/Aggregation Infrastructure 23. ASR 9000 nV Technology
Overview SP Services/ Third-Party Content Services/Before: nV
Technology Content After: nV Technology Cisco Prime IP NGNEach
device managedEdge and aggregation separately. Core managed as one
virtualsystem through Cisco Prime IP NGN. Inconsistent
featuresbetween edge and EdgenV Cluster Single release vehicle
aggregation. offering feature consistency.Siloed service domains.
Residential Converged BusinessnVOffers up to 71% reduction in OPEX
over 6 years vs competitors. Aggregation Inconsistent service nV
SatelliteReduced protocol outages upon device complexity between
edgeand aggregation failure.AccessUp to 84,480 GE ports Port scale
limited to managed through a single chassis. virtual system 24.
Network Dual-HomingTodays Solution: Protocol based approach
CellsiteMLP Router Bundle DACSCR dual- IP/Service Edgehoming
(MR-APS) IP/MPLSL2 Ethernet
Ring(MST/REP-AG,G.8032)Ethernetspoke-and-hub(MC-LAG) L2/L3 service
resiliency protocols HSRP/VRRP, 1-way & 2-way PW redundancy,
BGP PICAccess dual-homing protocols L3 Router
dual-MST/REP/G.8032/MSService state sync homing (L3 T-AGbetween two
nodes: ECMP)MC-LAGDHCP, IGMP, IGMPMR-APSsnooping, ANCP,L3 IGP/BGP
ARP, etc state sync 25. Network Dual-HomingTomorrows Solution:
Self-Protected ServiceCellsiteMLPReplace two nodes with one single
virtual nodeRouter Bundle simplify dual-homing to be
single-homingDACSASR 9000 ClusterCR dual-IP/Service Edgehoming
(MR-APS) IP/MPLSL2 Ethernet
Ring(MST/REP-AG,G.8032)Ethernetspoke-and-hub(MC-LAG)No need for
L2/L3 service resiliencyprotocols: L2/L3 service resiliency
protocolsIt is a single Virtual Node. NO need! Its SINGLE virtual
node Access single-homingL3 Router dual-Regular LAGhoming (L3Single
Router APSNo need to sync Service state betweentwo
nodes:ECMP)Single routing AdjacencyAll L2 and L3 state are syncd
naturally via control plane extension 26. Network Virtualization
(nV)Deployment Scenarios L2VPN SP 3Play and L2 Business VPN DCI
(data center inter-connect) (both enterprise and SP DCI) Ethernet
exchange Wireline Aggregation L3 termination, no IP session BNG
(distributed or centralized) Wireless Back haul L3 CPE aggregation
27. Network Virtualization (nV)Deployment Example L2VPN
ServiceActive/standby MC-LAG AA bandwidth inefficiency Active PW 4
PWs with 3 standby control plane overheadActive Active PW failover
time depends onthe number of PWs Standby PW slow convergence LACP
SS LACP Require additional statesync (for example, IGMPSnooping
table) to speed upStandbyStandbyservice convergenceSolution1:
MC-LAG + 2-way PW redundancy complex(Currently the best solution in
the market)Active/active regular LAGSingle PWLink/Node failure
isprotected by LAG, PW iseven not aware superfast convergence State
sync naturallySolution 2: ASR 9000 Cluster Simple, fast solution
28. Network Virtualization (nV)Deployment Example L3 Service CE
dual homing to two PE routers. It has 2separated L3 interface, and
run separatedIGP/BGP session with two PE routers Traffic load
balance over the two ECMPpaths When link or node failure,
IGP/BGPTwo Routing adjacency goes down. Protocol
re-converge.Adjacency BGP PIC edge feature is used for fast
BGPconvergence No state sync between two PE routers CE dual homing
to one virtual PE. Singlerouting adjacency over the link bundle
Traffic load balance over the link bundle When link or node
failure, bundle remainsup, so upper layer protocol is even not
aware super fast convergence, and simpleSingle RoutingAdjacency
State sync naturally 29. Whats nV Satellite ?Satellite Discovery
and Control ProtocolSatellite access Satellite access port isport
represented by the virtual nvEthernet interface on the
HOSTSatellite Fabric links One ASR 9000 nV SystemASR 9000 Host
Install special satellite image on the selected access device to
make it ASR 9000 satellite Running satellite auto discovery and
control protocol to make satellite as virtual line card of the ASR
9000 Host From end user point of view, its single virtual system
ASR 9000 nV System. All management, configuration are done on the
Host chassis Satellite and Host could co-locate or in different
location. There is no distance limit between satellite and Host
Satellite have zero touch configuration** If satellite is connected
to Host via L1 link 30. First Satellite HardwareASR 9000v Field
Replaceable Fan TrayPower Feeds Redundant Fans Redundant -48vDC 1
RU ANSI & ETSI ToD/PSS OutputPower FeedsCompliant Bits Out
Single AC powerfeedLEDs 4x10G SFP+44x10/100/1000 MbpsPluggables
Initially used as Fabric Ports ONLY (could be used as access port
in the Full Line Rate Packet Processing future)and Traffic
Management Plug-n-Play In-Band Management Automatic Discovery and
Provisioning Co-Located or Remote Distribution Environmentally
Hardened 31. Satellite Connection ModelsL1 Connection Hub &
Spoke Satellite Single home Single home with uplink Satellite
bundleASR 9000Cluster Dual home to cluster (or Satellite two
HOSTs)ASR 9000Cluster Satellite Dual home to cluster (or two HOSTs)
with uplink bundle3 32. FTTB Case StudyCluster + Satellite
Deployment Models 17 individual devices (12 sites) to manage 5
ASR9000 nV Systems to manage Different platform and OS in small and
big POP sites Common SW feature set Same operation complexity in
small or big POP sites Satellite is configured and managed on the
nV Host.Minimal operation on the small POP site rapidservice
deployment 5 ASR 9000 nV Systems Small POP site Big POP site
(10-80Gbps)nV satellite for the small POP(>80G)site or for small
box in the bigsite 33. Mobile Aggregation Case StudyCluster +
Satellite Deployment Models ~nx1000 GE portsGE for cell site
routers aggregation unlimited backhaul capacity for growth and for
localGE ports for local devicesdevicesLimited GE density per
box9000v9000v CO LTE Core9000v MME VRF Voice SGWGE port percell
site router VRF RANMSCRNCVRF MGMT Mgmt CDMA CoreCell Site
Routers9000v 9000v 9000vCisco Confidential 34 34. FTTH Case
Aggregation/AccessCluster + Satellite Deployment Models One nV
system to manage, with ~nx1000 GE ports fan Dozens of
pre-aggregation/access boxes to outmanage Simplify the
access/aggregation dual-homing by link Complex network resiliency
solutionsbundle: active/active forwardingclusterSatellite Satellite
Satellite SatelliteTraditional wireline GEaggregation via L2
switchOne ASR 9000 nV System 35. Managing Cell Site RoutersCluster
+ Satellite Deployment Models Cell site router become ASR 9000
satellite nx1000 cell site Routers to manage Single ASR 9000 nV
system for management, Complex L3 routing, BFD, even L3VPN or L2VPN
configuration on the cell site Routers configuration and image
upgrade Zero (or minimal) touch on ASR 9000 satellite. Minimal
feature on satellite CO satellite LTE Core satellite MME satellite
VRF Voice satellite SGW satellite satellite VRF RANMSC satellite
satelliteRNCVRF MGMT MgmtCell Site RoutersCDMA Core Satellite*One
ASR 9000 nV System * It could use different hardware as ASR 9000
satellite for the cell siteCisco Confidential 36 router instead of
the existing ASR 9000v 36. Virtualized TransportValue Propositions
Virtual router is always on Towards 50msec failure protectionwith
very high service scale Simplify network protocol
basedHighresiliency to be internal system control Resiliencyplane
based Leverage ASR9K HOSTultra-high MD control planeLowscale and
feature set, removeCostcomplex feature from satellite low cost
satellite hardware Operational One network element to manage a
network cloudSavings simple service provisioning, image upgrading,
configuration, etc Rapid service deployment plug-and-play, self-
managed access 37. Cisco Packet TransportValue
PropositionsMobileCPT 600 Backhaul CPT 200 MPLS-TP
EthernetEthernetServices6 slots (480G) 2 slots (160G)OTNDWDMUp to
352 ports CPT 50Up to 176 portsCPT 50CPT 50FTTX & CPT 50 TDM
Fixed config satellite44xGE, 4x10GE HardwareSoftware Unique
satellite architecture MPLS-TP, 802.1ad, H-QoS, E-OAM, HA: SSO,
ISSU, MDRMPLS OAM, Sync-E, 1588, LAG, REP, Active-Standby Control
PlaneMVR,IGMPv3Industrys first, standards-based, unifying packet
transport Cisco Confidential 38 38. Cisco Packet
TransportExceptional Power SavingsEthernet + TDM Switching29.75
10.5Transponder inchesinchesCPTROADM Over 60% Reduction in Rack
SpaceOver 65% Reduction in Power ConsumptionCalculations based on
480G capacity Powerful Yet Green and Optimized 39. POT-S in
MetroDeployment Scenario IP & MPLSRoutersIP &
MPLSPoint-to-point& multipointIPoDWDMCarrier EthernetCarrier
EthernetPrivate LinesPrivate LinesEth & TDM Eth & TDM
Point-to-point OTN DWDM SwitchingPOT-S TDMTDM POT-S and IPoDWDM
complementary 40. MPLS from Core to AccessReducing OpEx, CapEx via
simplification NationalData Center/Cloud/VHO IP/MPLS CRSSingleCore
ForwardingRich set of connections Mechanism(mesh), P2P / P2MP /
Regional Data Center/ VSOIP/MPLSMP2MPSingle ControlEdgeASR
PlaneXaaSContent 9000 CacheMPLS-TP
SingleMobileManagementAggregation MPLS-TPSystem
Connection-oriented, P2P / P2MP In-band OAM
MECPTAccessSatelliteInterop Tested Business Transport Trust +
Packet Efficiency = 20% OpEx Savings 41. Scaling MPLS ServicesWith
Converged Infrastructure Scale - Interconnect 100k Access nodes
through an MPLS domain Resilience - < 50msec convergence as
often as possible Simplicity - Operation of big MPLS networks is
often considered difficultReference ModelPE11 PE2ABR11 ABR21
Distribution1 Distribution / / Core and EdgeAggregation Aggregation
DSLAM1DSLAM2PE12 PE2ABR12 ABR22 2 1k Nodes / Core10k Nodes /
Aggregation 100k Nodes / Access 42. Solution - Unified MPLSCarrier
Ethernet Transport Architecture Cloud Virtualized Functions
Consumer Apps Video Processing Billing Compute Core Svc Delivery
Origin Server EncryptionData Transcode Center Device MgmtStorage
SwitchEdge UnifiedMPLS Converged: Any Service, Any AggregationPath,
Any Access Operationally Simple: SingleControl Plane Client Carrier
Class: Fast Reroute andDevicesNetwork ConvergenceConsumer Business
Mobile 43. Assess Solution Business ValueCarrier Ethernet Transport
Architecture ASR 9000 SystemSingle Management EntityHow does the
total solutionTranslate to business value? Zero Touch (ASR 9001,
ASR 903, ASR 901) (nV ) ConfigurationIntegratedTraffic
AnalyticsMulti-SimplifyService 44. Competitive TCO AnalysisInput
Various TCO Parameters Average Sales Price (ASP)CAPEX Engineering,
Furnishing and Installation (EF&I) CAPEX Mobile PowerRes TCO
OPEXBiz Cooling Floor Space Network Care (provisioning, fault
management, 3 YearOPEX performance management) Period Software
upgrades Vendor maintenance 45. Requirements &
AssumptionsComparable ArchitecturesInfrastructure
ConvergenceNetwork Assumptions over(Converging Network Siloed
Domains in the access) 3 Years 13,500,000 residences in metro
area=with Video, VoIP and Internet.50,000 business establishments
inOperation Simplification metro area with L2 VPN, L3 VPN
and(Integrated Traffic Analytics, Zero Touch Configuration,
Optimized Power) Internet.2 7,000,000 mobile customers in metro
area with Voice, Data and SMS.Infrastructure Redundancy(Route
Processors, Power Supplies & Fans) 3Competing Architectures 46.
Breaking the Backhaul OpEX BarriersLowest Power Consumption in the
Industry Only 2.375 W/Gbps at cell, 2.5W/Gbps at pre-Agg (ASR
901-12C-F-D 38W, 16 Gbps) 5 year cell-site power savings NPV is
$20+ Million 1 year savings by removing dedicated T1 timing is $48
Million i.e., Verizon 40,000, Bharti 40,000 cell sites $100/month
for E1/T1 47. Cisco Carrier Ethernet ArchitectureBusiness
Differentiators Solutions Payback from Cisco Converged
ASR90005System with nVCost reduction from 68 Cisco Ethernet Energy
Savings TCO reduction from 70Cisco ASR9000 System with nV 48.
Q&A#CiscoPlusCA 49. We value your feedback.Please be sure to
complete the Evaluation Form for this session. Access todays
presentations at cisco.com/ca/plus Follow @CiscoCanada and join the
#CiscoPlusCA conversation 50. NMS for Network Managementor Dynamic
Control PlaneWorking LSP Client node PEPEClient nodeProtect
LSPMPLS-TP LSP (Static or Dynamic) Pseudowire with e2e andSection
Section segment OAMClient SignalConnection Oriented, pre-determined
working path and protect pathTransport Tunnel 1:1 protection,
switching triggered by in-band OAM,Options with NMS for static
provisioning, or dynamic control plane for routing and signaling51
51 51. ASR 9000 Virtual Chassis Overview Control Plane EOBC
Extension (L1 or L2 connection)Special external EOBC 1G/10G Single
control and One or two 10G/1G from each RSP port s on RSP (new
RSP)management plane,distributed dataplane one virtualchassis 01
Control plane EOBCActive RSP Standby RSP ActiveRSP Standby
RSPInternalextension is throughEOBCspecial RSPonboard 1G or
10Gports Data plane LCLC LC LC LCLC LCLCextension is throughregular
LC ports (itcan even mix regulardata ports and Inter-chassis data
link (L1Regular 10G or 100G datavirtual chassis data
connection)ports (Current or future line plane ports on the 10G or
100 G bundle (up to 32 ports) card) same LC), doesntrequire
fabricchassis flexibledeployment 5 52. Scale, Simplify,
VirtualizesExtending Cisco ASR 9000 System to Access & Mobile
Networks ASR 9000 SystemSP BenefitsASR 9922 ASR 9010
Multi-SimplifyServiceASR 9006Dimensional Operations Velocity ASR
9001Scale ASR 903 ASR9000v Single 96 Tb IPv6 System ASR 901 36x
More Capacity than the Closest Competitive Platform
