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SES E-VPL Member Deployment for NJEDge.Net. Verizon Business Ethernet Solutions Presented By Joseph O’Leary Sales Engineer Higher Education segment for Verizon Business. Ethernet Services - Summary. Verizon Ethernet LAN (E-LAN) Service MP2MP EVC, designed for bridge or router CEs - PowerPoint PPT Presentation
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SES E-VPL Member Deployment for NJEDge.NetSES E-VPL Member Deployment for NJEDge.Net
Verizon Business Verizon Business Ethernet SolutionsEthernet Solutions
Presented By Joseph O’Leary Sales EngineerPresented By Joseph O’Leary Sales EngineerHigher Education segment for Verizon BusinessHigher Education segment for Verizon Business
Verizon Business Verizon Business Ethernet SolutionsEthernet Solutions
Presented By Joseph O’Leary Sales EngineerPresented By Joseph O’Leary Sales EngineerHigher Education segment for Verizon BusinessHigher Education segment for Verizon Business
Ethernet Services - SummaryEthernet Services - Summary
3
Verizon Switched Ethernet Service TypesVerizon Switched Ethernet Service Types
Verizon Ethernet Virtual Private Line (EVPL) Service
– P2P EVC, designed for router CEs– Non-transparent service– ‘Service Multiplexed’ UNI – one or more EVCs
per UNI– Service performance guarantees
E-UNICE(Router)
Verizon Ethernet LAN (E-LAN) Service
– MP2MP EVC, designed for bridge or router CEs
– Connectionless, any-to-any connectivity– Transparent (VLAN tag preservation, L2CP
tunneling) – ‘All-to-One Bundled’ UNIs– Service performance objectives
E-UNI
CE(Switch/Router)
4
EVPL Metro Switched Ethernet ServiceEVPL Metro Switched Ethernet Service
HQ LANHQ LANCPE NID
Verizon Metro Verizon Metro NetworkNetwork
NID
Customer’s Virtual Network
Ethernet Switch
Customer Site A
Dedicated Fiber Pair
Redundant Management Links
Data Services Network Operations( DSNOC)
NIDCustomer Site C
Customer Site B
10 M
100 M
GigE (1000 M)
CPE
LANLAN
CPELANLAN
Service Connection
Point
Customer Equipment (*MNS Opportunity)
Key Characteristics• QoS options available• Shared Ethernet switches• Backbone: Multiple GigE links• Dedicated fiber access• Network Interface Device (NID)• Customer virtual networks (VLAN)
IOFIOF
5
EVPL MetroSwitched Ethernet ServiceEVPL MetroSwitched Ethernet Service
Note: For EVC-2, switch looks at {VLAN_ID + CoS (p-bit)} of each incoming service frame - frames must be ‘tagged’
Customer network• Customer has three EVPL Premier UNIs and two EVCs, as shown below • EVC-1: single CoS <EVPL-B> = <70 Mbps> • EVC-2: multi-CoS <EVPL-RT, EVPL-PD> = <20Mbps, 50Mbps>
A3
A2
A1
SES NetworkE-UNI1G
CE
Switch port configured as ‘Premier Access Line, tagged’
NID
Switch port configured as ‘Premier Access Line, untagged’
E-UNI100M
E-UNI100M
All customer traffic is ‘untagged’
VLAN-ID=456
VLAN-ID=123 EVC-1
EVC-2
All customer traffic is ‘tagged’
6509
6509
6509
Marking & CoS with SES-EVPLMarking & CoS with SES-EVPL
7
IP Precedence and DiffServ Code PointsIP Precedence and DiffServ Code Points
• IPv4IPv4: Three most significant bits of ToS byte are called IP : Three most significant bits of ToS byte are called IP Precedence (IPP) - other bits unusedPrecedence (IPP) - other bits unused
• DiffServDiffServ: Six most significant bits of ToS byte are called DiffServ : Six most significant bits of ToS byte are called DiffServ Code Point (DSCP) - remaining two bits used for flow controlCode Point (DSCP) - remaining two bits used for flow control
• DSCP is backward-compatible with IP PrecedenceDSCP is backward-compatible with IP Precedence–DiffServ Class Selector (DSCS) also uses 3 most significant DiffServ Class Selector (DSCS) also uses 3 most significant bitsbits
77 66 55 44 33 22 11 00
ID Offset TTL Proto FCS IP SA IP DA DataLenVersionLength
ToSToSByteByte
DiffServ Code Point (DSCP)DiffServ Code Point (DSCP) IP ECN
IPv4 Packet
IP PrecedenceIP Precedence UnusedUnused Standard IPv4
DiffServ Extensions
Source: Cisco training material
8
EVPL ServicesEVPL Services
• Domain Domain – All UNIs in a given domain must be ‘Service Multiplexed’All UNIs in a given domain must be ‘Service Multiplexed’
• Service Multiplexed UNI Service Multiplexed UNI – Offered only for 100M and 1000M UNIs (not 10M)Offered only for 100M and 1000M UNIs (not 10M)– Two types: ‘Untagged’ Two types: ‘Untagged’ OROR ‘Tagged’ (can’t be both on same UNI) ‘Tagged’ (can’t be both on same UNI)– CAC rules apply to UNI...more on this later... CAC rules apply to UNI...more on this later...
• EVPL EVCs EVPL EVCs – Customer gets ability to order an EVC with up to three CoSCustomer gets ability to order an EVC with up to three CoS
» Separate speeds for each CoSSeparate speeds for each CoS– For EVC order requiring 1 CoS For EVC order requiring 1 CoS ‘VLAN ID’ is used to identify the CoS ‘VLAN ID’ is used to identify the CoS– For EVC order with 2 or 3 CoS For EVC order with 2 or 3 CoS 2 options 2 options
» ‘‘EVC+CoS’ (VLAN ID + p-bit value)EVC+CoS’ (VLAN ID + p-bit value)» ‘‘EVC+DSCP’ could be used to identify the CoS on the EVC (only for EVCs EVC+DSCP’ could be used to identify the CoS on the EVC (only for EVCs
connecting two untagged UNIs) connecting two untagged UNIs)
• L2CPs: All L2CPs are discarded at the UNIL2CPs: All L2CPs are discarded at the UNI
9
Local Enterprise, EVPL-EVC, Multiple CoSLocal Enterprise, EVPL-EVC, Multiple CoS
Note: For EVC-2, switch looks at {VLAN_ID + CoS (p-bit)} of each incoming service frame - frames must be ‘tagged’
Customer networkCustomer network• Customer has three EVPL Premier UNIs and two EVCs, as shown below Customer has three EVPL Premier UNIs and two EVCs, as shown below • EVC-1: single CoS EVC-1: single CoS <EVPL-B> = <70 Mbps><EVPL-B> = <70 Mbps> • EVC-2: multi-CoS EVC-2: multi-CoS <EVPL-RT, EVPL-PD> = <20Mbps, 50Mbps> <EVPL-RT, EVPL-PD> = <20Mbps, 50Mbps>
A3
A2
A1
SES NetworkE-UNI1G
CE
Service Multiplexed, tagged
NID
E-UNI100M
E-UNI100M
All customer traffic is ‘untagged’
VLAN-ID=456
VLAN-ID=123 EVC-1
EVC-2
All customer traffic is ‘tagged’
6509
6509
6509
Service Multiplexed, untagged
10
EVPL ConsiderationsEVPL Considerations
• EVPL is designed for customers using routers to access the EVPL is designed for customers using routers to access the service...service...Bridge CEsBridge CEs may not work correctly...may not work correctly...
• All traffic is All traffic is policedpoliced on these UNIs on these UNIs CE can’t burst to line rate CE can’t burst to line rate• CE CE must police/shapemust police/shape traffic to coordinate with the Bandwidth traffic to coordinate with the Bandwidth
Profile of the serviceProfile of the service– Traffic exceeding the BWP is Traffic exceeding the BWP is droppeddropped by the policer by the policer– More on this later...More on this later...
• Connection Admission Control (Connection Admission Control (CACCAC) rules limit the number of ) rules limit the number of EVCs and the aggregate bandwidth per CoS on a given UNIEVCs and the aggregate bandwidth per CoS on a given UNI– More on this later...More on this later...
11
SES EVPL CoS ID, Tagged UNISES EVPL CoS ID, Tagged UNI
Two CoS ID options per EVC
• EVC: a given EVC (VLAN ID) –single CoS
• EVC + CoS: a given CoS (p-bit value) on a given EVC – multiple CoS
• Note: CoS ID options per EVC are independent, i.e., both can coexist on same UNI – see right
Service multiplexed UNI, Premier Access Line, Tagged Service multiplexed UNI, Premier Access Line, Tagged
EVPL-RT or EVPL-PD or EVPL-B
EVPL-B
EVPL-RT
EVPL-PDEVC 2
EVC 1
CE-VLAN CoS 5,6
CE-VLAN CoS 2
CE-VLAN CoS 0
UNI
12
CoS Speeds SummaryCoS Speeds Summary
EVPL CoS Speeds • Low speed: 1 to 9 Mbps, in 1M steps• Medium speed: 10 to 90 Mbps, in 10M steps• High speed: 100-1000 Mbps, in 100M steps
Class of Service (CoS)
EVPL ServicesPremier Access Line
FE (100M) GE (1000M)
Real-time (RT) 1-50 Mbps 1-100 Mbps
Priority Data (PD) 1-50 Mbps 1-500 Mbps
Basic (B) 1-100 Mbps 1-1000 Mbps
Allowable CoS Speeds per EVC, by Service Type
13
UNI Connection Admission Control (CAC) RulesUNI Connection Admission Control (CAC) Rules
• UNI CAC rules are built into Provisioning SystemUNI CAC rules are built into Provisioning System• Service Multiplexed UNI - see table belowService Multiplexed UNI - see table below
CAC Rules for Service Multiplexed UNI
UNI speed Max # EVCs RT (50%) PD (85%) RT+PD (85%) Basic (500%)
100M 10 50 Mbps 85 Mbps 85 Mbps 500 Mbps
1G 75 500 Mbps 850 Mbps 850 Mbps 5000 Mbps
14
EVPL CoS ID ValuesEVPL CoS ID Values
EVPL-EVC Multi-Service ScenariosCustomer CoS (p-bit) Value
EVPL-RT EVPL-PD EVPL-B
{RT + PD + B} 5,6 2 0,1,3,4,7
{RT + PD} 5,6 0,1,2,3,4,7 N/A
{RT + B} 5,6 N/A 0,1,2,3,4,7
{PD + B} N/A 2 0,1,3,4,5,6,7
15
TYPICAL(SEGP): TODAYTYPICAL(SEGP): TODAY
PVC #1 /IP/VPN/ PVC #1 /IP/VPN/ “EXTRANET”“EXTRANET”
PVC #2PVC #2
Internet 1 (I1)Internet 1 (I1) XX
Member-to-Member DataMember-to-Member Data XX
Member-to-Member Member-to-Member VideoVideo
XX
Internet 2 (I2)Internet 2 (I2) XX
16
TYPICAL(SEGP): TOMORROWTYPICAL(SEGP): TOMORROW
EVC #1/EVC #1/
Best EffortBest Effort
CoSCoS
EVC #1/EVC #1/
Priority Data CoSPriority Data CoS
Internet 1 (I1)Internet 1 (I1) XX
Member-to-Member DataMember-to-Member Data XX
Member-to-Member Member-to-Member Prioritized VideoPrioritized Video
XX
Internet 2 (I2)Internet 2 (I2) XX
Member-to-Member Non-Member-to-Member Non-Prioritized VideoPrioritized Video
XX
17
SAMPLE EVC SizingSAMPLE EVC Sizing
• EXAMPLE 1:EXAMPLE 1:– Today: IP/VPN = 4 Mbps; Internet = 6 MbpsToday: IP/VPN = 4 Mbps; Internet = 6 Mbps– Tomorrow: EVC/BE= 10 Mbps; EVC/PD = 2 MbpsTomorrow: EVC/BE= 10 Mbps; EVC/PD = 2 Mbps
» Internet Contract: 6 MbpsInternet Contract: 6 Mbps
• EXAMPLE 2:EXAMPLE 2:– Today: IP/VPN = 10 Mbps; Internet = 10 MbpsToday: IP/VPN = 10 Mbps; Internet = 10 Mbps– Tomorrow: EVC/BE = 20 Mbps; EVC/PD = 6 MbpsTomorrow: EVC/BE = 20 Mbps; EVC/PD = 6 Mbps
» Internet Contract: 12 MbpsInternet Contract: 12 Mbps