Cisco IOS Profiled Release 12.0(26)S3 Testing
[with 12.1E, 12.2S, 12.3 & 12.3T]
for Service Provider MPLS Customers
Version History
Version Number
Date
Notes
1
July 25, 2004
This document was created. [The term “Safe Harbor”
was changed to “Profiled Release.”]
Executive Summary
The nEverest program is a quality initiative that focuses on satisfying customer requirements by
coordinating Cisco IOS release system-level and reliability testing under ‘real world’ conditions. The
nEverest testing uses the following five profiles, the designs of which are based solely on customer
requirements:
•
Enterprise Global
•
Enterprise Financial
•
Broadband
•
Service Provider/IP backbone
•
Service Provider/MPLS backbone (the current document)
Increasing demands on Service Providers from network subscribers, devices, and services have put
greater and greater loads on their network infrastructures. The testing program reported in this document
was set up to integrate, test, and validate leading MPLS VPN technologies in large-scale, full-service
network topologies for a specified set of platforms and software releases (Table 1) with particular
attention to security and Quality of Service (QoS) features. Our goal was to help Cisco Systems
customers to deploy highly scalable and resilient network services in large and demanding network
environments.
Note
The software versions listed in this document were tested using the procedures described in the “Test
Cases” section on page 32. All relevant unresolved defects found during testing are identified in the Test
Results Summary table (Table 4 on page 28). In addition to this report, we highly recommend that you
review the Release Notes issued with each IOS release, in order to see the latest list of open defects for
features not tested herein and for defects found after publication of this report.
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This document has the following sections:
•
About MPLS VPN with QoS and Security, page 9
– Testing Approach, page 9
– Features and Technology Sets Tested, page 13
– Limitations/Exclusions, page 21
– Traffic Tools and Definition, page 21
– Other Test Tools, page 22
– Topology Description, page 22
•
Test Results Summary, page 28
•
Test Cases, page 32
•
Supplementary Information, page 45
– Device Characteristics of Left@Albuquerque POP, page 45
– Device Characteristics of Boston POP, page 52
– Device Characteristics of Core, page 58
– Device Characteristics of Dallas POP, page 62
– Device Characteristics of Washington DC POP, page 72
– Device Characteristics of Denver POP, page 84
– Device Characteristics of the Network Service Points, page 87
– Device Characteristics of San Jose POP, page 89
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About MPLS VPN with QoS and Security
Testing Approach
The purpose of the SP-MPLS Profile was to expose new and existing Cisco products to a realistic
large-scale service provider MPLS/VPN-based environment. That environment was used to simulate
realistic SP conditions, including traffic levels, traffic mix, route aggregation, route flapping, and so
forth. Numerous areas of testing were executed, including a steady-state environment, a dynamic
environment, baseline measurement testing, and some scalability testing.
The network configuration that was tested consisted of a collection of representative Points of Presence
(POPs) peered with various core architectures (POS and ATM WAN backbones). Within each POP,
various PE devices supported MPLS/VPN infrastructure. Those PE devices peered with other PEs and
other POPs to create a large-scale VPN infrastructure, supporting thousands of VPNs. The test bed
included the following domains:
1.
“ISP1”- A POS core built on Cisco Series 7500 routers with POS OC-3c full-mesh topology
(Figure 4)
– Key Features: Supported connectivity to other domains.
2.
“ISP2” - A POS core built on Cisco Series 12400 routers and POS OC-48c and OC-192c links
(Figure 3)
– Core: Each core router had at least three connections to other core routers.
– POP Aggregation: By Cisco Series 12000, 10000, and 7600 routers with redundant Gigabit
Ethernet aggregation and redundant POS OC-48c/ChOC-48 links.
– Key Features: Carrier Supporting Carrier (CSC), Inter-Autonomous System (Inter-AS),
Quality of Service (QoS), dynamic routing VPNs, traffic engineering tunnels, security features
for MPLS VPN topologies (access control lists [ACLs], prefix filtering, TACACS+,
connectivity to other SP-MPLS profiles via network service points [NSPs]), and to other
domains.
3.
“ISP3” - An ATM core built on Cisco Series 7500 routers with ATM OC-3c full mesh topology, plus
WAN connections to a remote sub-domain named ISP3.1 (Figure 5):
– POP Aggregation: By Cisco Series 7500 and 7200 series routers, with redundant ATM OC-3c
links.
– Key Features: CSC, Inter-AS, QoS, and dynamic routing VPNs.
The profile was tested using the following progressive test stages:
1.
Functional Test: As each new feature belonging to a particular technology set—for example, the
feature VC Bundling belongs to the technology set Link Management [ page 15]—was added to
the existing test network, its ability to perform successfully with related features in that technology
set was verified. While the new feature was being integrated into the network, traffic loads were
maintained in order to emulate real-world production networks. After the integration and validation
of all new functions had been accomplished, the test environment was examined to ensure that all
technology sets were working together, and the functional test was then complete.
2.
System Test: This test focused on system stability of the network as a whole. Testing was performed
while the profile experienced amounts of traffic and stress seen typically in actual customer
environments. This included introducing errors that could lead to traffic loss, link failure, or node
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About MPLS VPN with QoS and Security
failure, and monitoring the network’s recovery from those errors. Traffic streams were measured,
and routers were polled continuously for numerous statistics, including routing table stability,
memory loads, CPU/processor loads, and tracebacks.
3.
Reliability Test: After the system test was completed, traffic was run continually through the
network for a minimum of 150 hours, to emulate one week of customer production. Errors and fault
groupings were introduced at the beginning and the end of the week-long run, with stress loads
added in the interim. Also near the end of the week, a maintenance window was executed. Items
measured throughout the week included memory utilization, CPU utilization, route table size, and
route table memory allocation.
The following table displays the devices and IOS trains tested in this Service Provider MPLS profile.
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Table 1
Operating system tested on each device, and the device’s role in the overall topology.
Device Role
Device Type
12000
Core Router &
P Router
12.0S
POP Aggregator
& Metro
Aggregator
12.0S
10000
7600
7500
7400
7304
12.0S
L3-POP
Aggregator
12.0S
3700/3600
2690
1760
12.1E
12.2S
12.0S
6500
12.0S,
12.2S
Route Reflector
Peering Point,
NSP
7200
12.0S
{NPE-G1}
12.2S
12.2S
12.0S
12.1E
L2-POP
Aggregator
12.1E
PE
12.0S
12.0S
12.1E
12.0S, 12.2S
12.2S,
12.3T
12.2S
12.0S
{NPE-G1}
12.2S
CE
12.0S
12.0S
12.1E
12.3T, 12.2S
12.3
12.2S
12.3T, 12.3
12.3T, 12.3 12.3T,
12.3
12.3T
The next table shows the link types and encapsulations included in this profile.
Table 2
Link Types and Encapsulations
Core
POP Metro Aggregation
Link Type
Encapsulation
POS OC-3c
HDLC
POS OC-48c
HDLC
POS ChOC-48
HDLC
POS OC-192c
HDLC
GE
ARPA
ATM OC-3c
AAL5snap
ATM OC-3c
AAL5snap
POS ChOC-48
HDLC
GE
ARPA, 802.1q
10 GE
802.1q
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Table 2
Link Types and Encapsulations (Continued)
PE-CE
Cisco IOS Release 12.0(26)S3
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Link Type
Encapsulation
Fast Serial
HDLC
HSSI
HDLC
T1
FR, HDLC
ChT1
FR, HDLC, PPP
E1
FR, HDLC
ChE1
FR, HDLC, PPP
T3/DS3
FR, HDLC
ChT3
FR, HDLC, PPP
E3
FR, HDLC, PPP
ChE3
FR, HDLC, PPP
ATM E3
AAL5snap
ATM T3
AAL5snap
ATM OC-3c
AAL5snap
ATM ChOC-3
AAL5snap
ATM OC-12c
AAL5snap
ATM ChOC-12
AAL5snap
POS OC-3c
FR, HDLC
POS ChOC-3
HDLC
POS OC-12c
FR, HDLC
POS ChOC-12
HDLC
FastEthernet
ARPA
GE
ARPA, 802.1q
About MPLS VPN with QoS and Security
Features and Technology Sets Tested
The features tested in this profile belong to the technology sets of IP Routing, Link Management, Link
Efficiency, Network Management, Quality of Service, Resiliency, and Security—each of which is now
described for you in greater detail.
IP Routing
Intermediate System to Intermediate System (IS-IS) was used as the internal gateway protocol (IGP) in
the ISP2 domain, its core defined as an IS-IS Level-2 area, and its POPs as an IS-IS Level-1 area
(Figure 1). Multi-area Open Shortest Path First (OSPF) was used as the IGP in the ISP3 (ATM-core)
domain (Figure 5) and in the ISP1 (smaller POS-core) domain (Figure 4).
Figure 1
IS-IS Topology in ISP2
GE
OC-192 (POS)
OC-48 (POS)
Boston
49.0002
NSP West
NSP East
12008
12008
12406
12406
San Jose
49.0001
DC
49.0003
Area ID
12416
ISIS
Level 1
12416
49.0000
ISIS
Level 2
12406
12406
Dallas
49.0004
82540
Denver
49.0005
Left @
Albuquerque
49.0006
As the external gateway protocol (EGP), all three ISPs used Border Gateway Protocol (BGP). Multipath
IS-IS and BGP were set to the maximum number of paths on all platforms (currently eight) in order to
load-balance traffic on as many paths as possible. The fully meshed ISP2 core could support as many as
200,000 routes. BGP peer-groups were set up in hierarchical groups. Route reflectors, core routers, POP
aggregation, and PEs were all in their own peer-groups (Figure 2).
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Figure 2
iBGP Topology and Peering in ISP2
eBGP peering
Peering
ISP
Peer Groups
SPCOREINTERNAL
SPPOPIPv4RR
Peering
ISP
Router
Tool
Router
Tool
NSP East
NSP West
SPPOPIPv4RRC
SPCOREeBGP
PE
PE
12008
12008
P
P
CORE
P
P
PE
Full Mesh iBGP
DC
PE
POP Agg
PE
P
RR
PE
PE
RR
Boston
PE
PE
POP Agg
POP Agg
All POP Agg routers are
RR clients of the centralized
route reflectors.
PE
All PE routers are
RR clients of their
respective POP
Agg routers.
P
POP Agg
PE
Metro Agg
PE
POP Agg
SJ
PE
Metro Agg
Left @
Albuquerque
PE
POP Agg
PE
POP Agg
POP Agg
PE
PE
POP Agg
PE
PE
Dallas
PE
PE
PE
PE
PE
Denver
PE
POP Agg
PE
PE
PE
PE
82539
PE
Data and control planes were isolated with respect to BGP routing by the use of redundant, centralized
BGP route reflectors (RRs). BGP/MP-BGP sessions were partitioned between two sets of redundant
route reflectors, providing for future scale and growth. One set consisted of four Cisco 7206VXR routers
with NPE-400 processors (two for IPv4 and two for VPNv4), located in the ISP2 San Jose POP to
support that POP, the ISP2 core, and the Dallas and Denver POPs. The other set consisted of four Cisco
7206 routers with NPE-G1 processors, located in ISP2’s Washington DC POP to support that POP plus
the Boston and Left@Albuquerque POPs.
Distributed Cisco Express Forwarding (dCEF) was enabled on all interfaces and platforms that support
it. MPLS Label Distribution Protocol (LDP) was enabled on all routers in the ISP2 core, POP and PE
roles.
On the NSP peering devices, route filters, prefix filters, and route maps were set up to block out unwanted
network advertisements from being sent or received.
VPNs were created on the PEs by defining a unique VPN routing and forwarding (VRF) instance with
unique route targets. MultiProtocol BGP (MP-BGP) was used along with BGP extended communities to
exchange VPN routes between PEs. Routing inside VPNs was accomplished mainly through static
routing on the CEs. Some VPNs used Open Shortest Path First (OSPF), eBGP, or RIPv.
While almost all VPNs were set up as an any-to-any architecture, there was also one HUB-SPOKE VPN.
Internet access was set up on a few VPNs via default route, second IP link, or hub CE. Inter-provider
VPN solutions included Inter-AS and CSC. Inter-AS was set up between ISP2 (POS core) and ISP3
(ATM core), using MPLS VPN Inter-AS-IPv4-BGP Label Distribution. CSC was set up using
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CSC+IPv4+Label. BGP Prefix Outbound Route Filtering was used in conjunction with CSC and
Inter-AS VPNs to limit which routing targets would be advertised from ISP2 to route reflectors in the
remote AS.
Link Management
Layer 2 signaling, Multilink Point-to-Point Protocol, and VC bundle management were deployed for link
management, as follows.
Layer 2 signaling, including the use of operations, administration, and maintenance cells (OAM), was
tested in the Dallas POP between two different routers, the Cisco 12008 and 3640, on ATM OC-3c
interfaces.
Multilink Point-to-Point Protocol (MLPPP) and VC bundle management were both implemented in the
Washington DC POP, with the following considerations:
•
MLPPP can increase the bandwidth of network links beyond that of a single T1/E1 line without the
user having to purchase a T3 line. That increase is achieved by bundling several T1s into a single
pipe, which then becomes capable of carrying both voice and different classes of data traffic in an
efficient manner. This was implemented across several low-speed serial links in the DC POP.
•
VC bundle management allows service providers to offer different levels of voice and data service
by making use of IP precedence, MPLS experimental bits, and QoS queuing in different virtual
circuits within the bundle.
Link Efficiency
On PE-CE links, Link Fragmentation and Interleaving (LFI) for MLPPP was applied to interactive traffic
that would be susceptible to increased latency, such as Telnet and VoIP, and on slower MLPPP links,
particularly on the ChT1, ChE1 and ChE3 links. LFI was used in conjunction with COS policy-maps on
MLPPP links configured as a single link per bundle, in order to ensure a predictable fragmentation delay
time during per-packet load-balancing.
Frame Relay Fragmentation Layer 2 (FRF12), which allows for real-time voice and non-real-time data
frames to be carried together on lower-speed links while preventing excessive delay from occurring to
the real-time traffic, was widely applied to serial interfaces for QoS VPNs, and was usually applied with
access links that had a bandwidth less than 2 Mbps.
Compressed Real Time Protocol (cRTP), which diminishes delay in multimedia RTP traffic by reducing
line overhead, was applied on any WAN interface where there was a high proportion of RTP traffic and
where link bandwidth was a concern. cRTP also was applied on serial links which had both voice and
data traffic—and that included all the QoS VPNs.
Network Management
All routers were configured with SNMP for network status monitoring. All devices in the network were
configured to report debugging level messages to a central Syslog server, which analyzed the logs daily,
and generated reports on errors and changes made by the devices. Network Time Protocol (NTP) was
also used on PE and CE routers, to achieve system-level synchronous timing.
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Quality of Service
There was a large deployment of QoS features (detailed below) on the following interface types in the
ISP2 (POS core) domain:
•
•
•
•
ATM DS-3
ATM OC-3c
Channelized E1
Channelized E3
•
•
•
•
Channelized T1
Channelized T3
FastEthernet
Fast Serial
•
•
•
Gigabit Ethernet
HSSI
POS OC-3c
The QoS features tested were those tested in Phase 2 of the nEverest SP-MPLS program (see
www.cisco.com/en/US/products/sw/iosswrel/ps1829/prod_system_test_report09186a0
0801932ee.html#1128535). This included classification, congestion management, congestion
avoidance, policing and shaping, as explained next.
Classification
Traffic was distinguished into four data classes—Real-Time, Premium, Business and Economy/Best
Effort—plus two classes for Routing Protocols and Network Management. Traffic was generated with
different precedence (TOS) values. CE routers then checked those values and set appropriate DSCP
values for each class. When the packets arrived at the PE level they were matched against the DSCP
value and appropriate MPLS values were then set. The whole classification process went reverse-way
when traffic flowed from the core to PE and CE.
Additionally, the Premier and Business classes had an out-of-profile classification: when either Premier
or Business traffic exceeded its capacity, it was marked as out-of-profile and was forwarded to the next
lower order queue for transmit.
When additions to Real-Time traffic would have exceeded that class’s specified capacity, such new
setups were dropped, thereby preserving the quality performance of the existing traffic.
Congestion Management
For congestion management, the following features were employed:
•
Priority Queuing (PQ) and Low-latency Queueing (LLQ) with Real-Time traffic
•
Class-based Weighted Fair Queuing (CBWFQ) with Premier, Business, and Economy/Best Effort
classes
•
Modified Deficit Round Robin (MDRR) on some Cisco Series 12000 platforms
Congestion Avoidance
For congestion avoidance, these features were employed:
Note
•
Tail-drop for default class of service
•
DiffServ-compliant Weighted Random Early Detection (WRED) for Premier and Business classes
•
Class-based WRED (CBWRED) using DSCP when traffic flowed towards WAN (PE-CE) links
For congestion avoidance, policing and shaping, the distributed version of each feature was employed
on Cisco Series 7500 and Series 12000 routers.
Policing and Shaping
Policing and shaping were implemented through these features:
•
Generic Traffic Shaping (GTS)
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•
Frame-Relay Traffic Shaping (FRTS)
•
Dual-layer policy map (hierarchical policies)
Summary Overview of QoS Traffic
Applying all the foregoing features yielded the following traffic classes, attributes and behaviors:
Traffic Class
Bandwidth
DSCP/TOS
MPLS Exp
Conform Action Exceed Action
Real-Time
Priority Queue
40/5
5
Transmit
Drop
30%
32/4
4
Transmit
DSCP=33
MPLS=4
Transmit
40%
16/2
2
Transmit
DSCP=17
MPLS=2
Transmit
3%
00/0
0
Transmit
Drop
Network
Management
1%
24/3
3
Transmit
Drop
Routing Protocols
1%
48/6
6
Transmit
Drop
(25% of access
bandwidth in Kbps)
Premium
(Bus-Latency)
Business
(Bus-Throughput)
Economy/Best Effort
(Class-Default)
Resiliency
Resiliency was introduced into the network by installing redundant hardware and links, and by
configuring redundant paths, as follows:
•
Dual route processors were utilized in most of the core routers, the San Jose metro aggregators and
model 12008 PE routers, and in the Dallas routers, configured with Route Processing Redundancy
(RPR+)
•
Full fabric configuration—that is, three Switch Fabric Cards (SFC) and two Clock Scheduler Cards
(CSC)—were utilized in most core routers, in the San Jose metro aggregators, and in the
Left@Albuquerque PE routers
•
Redundant power supplies were used in most of the core routers, in the San Jose metro aggregators,
and all model 7513 PE routers (but not in any CE routers)
•
Redundant links (POS OC-48c and GE) were established between all POP PE routers and the ISP2
core; and redundant ATM-OC3c links were configured between one ISP3 POP and its core
•
Hot Standby Router Protocol (HSRP) was applied in the two Boston POP aggregation routers,
configured for complete load-sharing between them. HSRP also was configured in the San Jose PE
routers for the eBGP VPN (CE routers there point to the shared virtual address as their default
gateway).
•
The Single Line Card Reload feature was present in all Cisco 7513 PE routers
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Security
The numerous security features tested can be grouped into three main categories: access security, routes
exchange security, and Layer 2 tunneling security.
•
Access security was implemented by the following features:
– Requiring the Enable Password on all routers
– Using Terminal Access Controller Access Control Server Plus (TACACS+) implementation of
authentication, authorization and accounting. Three different groups, each with a distinct
policy, were configured:
•
Guest Users proxy via corporate Active Directory with privilege show commands
•
Network Administrator with privilege level 15
•
Script/Tools Users with show commands, and controlled access to limited configuration
commands
– To cover the instance where the TACACS+ server might be down or can not respond, only one
local username-password was permitted for backup access
– Access Control Lists were required on vty lines, in order to limit Telnet access to certain
specified addresses.
•
Routes exchange security was accomplished through message digest authentication in OSPF, and
through MD-5 authentication in IS-IS and BGP:
– When teamed with IS-IS, MD5 authentication adds an HMAC-MD5 digest to each IS-IS
protocol data unit (PDU). That prevents unauthorized IS-IS routing messages from being
injected into the network routing domain. In this profile, IS-IS HMAC-MD5 authentication or
the clear text password authentication was applied to all five types of PDU. The authentication
was enabled on different IS-IS levels independently. The interface-related PDUs (LAN Hello,
Serial Hello, CSNP, and PSNP) were enabled with authentication on different interfaces, with
different levels and different passwords. IS-IS Level-2 with MD-5 and wide metrics was used
in the ISP2 core, and IS-IS Level-1 with MD-5 and wide metrics was used with all PEs in the
POPs.
– In the case of BGP, MD5 authentication occurs between BGP peers, meaning that each segment
sent on the TCP connection between the peers can be verified. When configuring this feature,
the same password is used on both peers in order to make sure the connection will be made.
Invoking authentication causes the Cisco IOS software to generate and check the MD5 digest
of every segment sent on the TCP connection. If a segment fails authentication, a message
appears on the console. In our profile, BGP with MD5 was used on the CE routers that were part
of the eBGP VPN.
•
Layer 2 tunneling security through IPSec and Layer 2 Tunneling Protocol (L2TP) was
implemented as follows:
– IPSec end-to-end: from Dial/Remote Access MPLS VPN clients through PPP/L2TP tunneling
to the PEs
– One PE router in the San Jose POP was configured for VRF plus L2TP and IPSec to validate
the functionality of L2TP w/IPSec in a Remote Access (ASWAN) type solution.
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Complete Feature List
All the features tested in this profile are listed in Table 3, along with the particular platforms on which
those features were running.
Table 3
Features and the platforms on which they were tested
Technology Set
Individual Feature
Platform
IP Routing
IS-IS with MD-5 Authentication
12000, 10000, 7600, 7500, 7200
OSPF
12000, 10000, 7600, 7500, 7400, 7300,
7200
BGP with MD-5 Authentication
12000, 10000, 7600, 7500, 7400, 7300,
7200
MPLS VPN - CSC - IPv4 BGP Label Distribution
12000, 7500
Label Distribution Protocol (LDP)
12000, 10000, 7500, 7400, 7300, 7200
eBGP+IPv4+Label
12000
MPLS VPN Inter-AS - IPv4
12000, 7500, 7400, 7200
BGP Prefix Outbound Route Filtering
12000, 7500, 7400, 7200
Tag Distribution Protocol (TDP)
12000, 10000, 7500, 7400, 7300, 7200
Number of BGP Peers on NPE-G1
7206VXR
MPLS Export route filtering
12000, 7500
CSM bridging
Cat6500
Server Load Balancing
Cat6500
8-way CEF/MPLS Load Balancing
12000 (containing Engine 4+)
BGP Routing Table on NPE-G1
7206VXR
Dedicated Route Reflectors with NPE-G1
7206VXR
Dedicated Route Reflectors
7401
Prefix Lists
12000, 7500, 7400, 7200
802.1q
12000, 10000, 7500, Cat7600,Cat6500
802.1w
Cat4000
1-port 10-Gigabit Ethernet Line Card
12400
Modular Gigabit Ethernet Line Card
12400
1-port OC-192c/
STM-64c POS/
SDH Enhanced Services Line Card
12400
4-Port OC-48c/
STM-16 POS/SDH Enhanced Services Line Card
12400
4-Port OC-12c/
STM-4c POS/SDH ISE Line Card
12000
Link Type/
Encapsulation
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Table 3
Features and the platforms on which they were tested
Technology Set
Individual Feature
Platform
Link Management
ATM / FR VC Bundling
10000, 7500
Layer 2 Signalling on 4-Port OC-3c/
STM-1c ATM Line Card with OAM
12000
3600
Multilink Point-to-Point Protocol (MLPPP)
10000, 7500
Link Fragmentation and Interleaving (LFI)
10000, 7500
Frame Relay Fragmentation Layer 2 (FRF12)
10000, 7500
Compressed Real Time Protocol (cRTP)
7500
SNMPv3
12000, 10000, 7600, 7500, 7400, 7300,
7200, 3600, 2600, 1700
Cat6500, Cat4000
ACL on 10GE
12400 (containing Engine 4+)
Syslog
12000, 10000, 7600, 7500, 7400, 7300,
7200, 3600, 2600, 1700
Cat6500, Cat4000
QOS on ATM VC bundles
10000, 7500
QOS on FR VC bundles
10000, 7500
QOS on MLPPP bundles
10000, 7500
CBWFQ over ATM / FR VC bundles
10000, 7500
dLFI
7500
WRED
10000, 7500, 7200, 3600, 2600, 1700
Single Line Card Reload
7500
RPR+
12000, 7500
Monitor Convergence Times
12000, 10000, 7500, 7200
ACL on CTY/VTY
12000, 10000, 7600, 7500, 7400, 7300,
7200, 3600, 2600, 1700
Cat6500, Cat4000
TACACS+
12000, 10000, 7600, 7500, 7400, 7300,
7200, 3600, 2600, 1700
Cat6500, Cat4000
ASWAN
7200, 1700
8-port Unchannelized E3/T3 Line Card
10000
24-Port Channelized E1/T1 Line Card
10000
VIP6-80
7500
RSP16
7500
PRP-1
12400
Customer Edge router
3700
Provider Edge router
7300
Route reflector
7400
Link Efficiency
Network
Management
QOS
Resiliency
Security
Other
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About MPLS VPN with QoS and Security
Limitations/Exclusions
This SP-MPLS profile:
•
did not test actual voice transmissions, although it did run and rigorously test Real-Time traffic in
the same way that voice traffic is managed and processed in a production environment.
•
did not test WAN-switching technologies directly, although it did utilize Cisco BPX and MGX
infrastructures to support ATM and FR connections.
•
did not test native IP Multicast nor MPLS multicast.
•
did not test wireless technology.
There was no variable length of traffic with variable patterns and rates. Instead, packets either were
transmitted with a fixed size of 128 bytes each, or they were sent in an IMIX (Internet Mix) ratio of 7:4:1
(using 64, 570, and 1500 bytes respectively).
Traffic Tools and Definition
IXIA tools created thousands of traffic streams across the test network, the source and destination points
of the traffic being at the lowest, that is, the CE layer. The largest number of traffic streams consisted of
TCP/IP packets (averaging 330b bytes per packet), running at a constant rate across the network. Traffic
streams generated within core end-points did not exceed 50% of capacity. Within the POPs, traffic
utilized approximately 50-70% of the PE-CE links’ bandwidth. Overall traffic in each POP aggregation
level came to between 1.5 GB and 2 GB. (The capacity of the POPs varied from 2GB to 5GB).
To support QoS, TCP/IP packets were generated with appropriately marked TOS bits, yielding the
several data and Real-Time classes. (Real-Time packet header compression was configured but not
tested).
A small amount of verified traffic was generated by a Pagent RVT/CVT tool, verified in order to reveal
any corruption of data or headers.
Full Mesh Internet Mix (IMIX) traffic was implemented in the POPs, using packets of three sizes: 64,
570, and 1500 bytes. These packets were transmitted across the network in the ratio of 7:4:1 respectively.
Flowing through the large set of VPNs, this traffic enabled the testing of various buffers within each PE
and throughout the network’s wide range of interface / line card / port adapter combinations.
Pagent’s HTTPSE tool created client/server traffic flows between clients in all VPNs with Internet
Access and the Boston POP’s Internet Data Center. That traffic consisted of HTTP GETs sent from the
clients, with 2kb HTML files and 100kb GIF files being returned by the servers.
Quantitatively, the test traffic achieved the following:
•
8000 IGP routes
•
200k IPv4 routes (learned via eBGP) distributed among 64 eBGP peers
•
1800 IPv4 routes (learned via iBGP) distributed among 180 iBGP peers (peering was to each IPv4
route reflector)
•
360k VPNv4 routes distributed among 180 peers and 2400 route distinguishers
•
30k-35k unique Autonomous System paths
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About MPLS VPN with QoS and Security
Other Test Tools
Internal and external routing protocols were emulated by the IXIA route generation tool, including
simulation of IP and VPNv4 routing tables and appropriately-sized IGP routing tables for IS-IS and
OSPF.
Proprietary automation tools created and applied large-scale configurations to the Cisco routers in the
test network.
Monitoring tools polled routers and reported continuously on the health of the network. The primary
tools were Cisco IOS ‘show’ commands, along with SNMP and MIB variables to track such key
behaviors as link utilization, queue utilization, packet drops and interface congestion. The polling
process used syslog and AAA messages sent to a TACACS+ server.
Topology Description
The test network was composed of three domains:
1.
The central domain, named “ISP2”, was a POS core built on Cisco Series 12400 routers, POS
OC-48c and OC-192c links, peered with six representative POPs. It is shown in Figure 3.
2.
Communicating through the “NSP East” network service point in ISP2 was a second POS core, this
one built on Cisco 7513 routers with POS OC-3c full-mesh topology (shown in Figure 4). This
smaller domain, which had no POPs, was named “ISP1”.
3.
A third domain, called “ISP3” was an ATM WAN backbone built on Cisco 7513 routers with ATM
OC-3c full mesh topology, and three representative POPs (shown in Figure 5). This ATM domain
communicated with the large POS-core domain “ISP2” through the network service point called
“NSP West”. Through that connection with ISP2, this WAN domain also connected remotely with a
satellite POP, called “ISP3.1” or “Bermuda” (used for the Carrier-Supporting-Carrier test).
Central Domain ‘ISP2’
Core
The core or backbone of ISP2 consisted of four Cisco 12416 routers and two Cisco 12406 routers,
interconnected by POS OC-48c links. Additionally, four of the core routers were connected by parallel
POS OC-192c links.
Each core router had at least three connections to its neighbor routers, which were either POP
aggregators, Metro aggregators, or Network Service Points (NSPs).
Each POP was served by a pair of core routers, making at least four connections between the POPs and
the core. (Only the Left@Albuquerque POP maintained just two links to the core). Three POPs were
connected to the core by redundant Gigabit Ethernet connections: the Boston, Washington DC, and
Denver POPs. Two other POPs were connected to the core by POS OC-48c links: the San Jose and
Left@Albuquerque POPs. And one POP—Dallas—was connected to the core through channelized
OC-48.
Each NSP consisted of a pair of Cisco 12008 routers connected to one another by a variety of links: POS
OC-3c, ATM OC-3c, ChOC-12, and E3. One router in each NSP was connected to the core through POS
OC-48c. The other router in each ISP was connected to a different ISP through OC-3c links: ‘NSP West’
was connected to ‘ISP3’ (the ATM WAN profile), and ‘NSP East’ was connected to ‘ISP1’ (the smaller
POS-core profile) and the remote ‘ISP3.1’ profile.
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About MPLS VPN with QoS and Security
San Jose POP
The San Jose POP consisted of five CE routers and six PE routers, the sixth PE being connected to an
ISDN dial access cloud through a Cisco Catalyst 5513 switch and a Cisco AS5850 router.
The CE and PE routers each included Cisco models 12008, 10008, 7609, 7513 and 7206. The CEs were
linked to the PEs via POS OC-12c, POS OC-3c, ATM OC-3c, ChT3, ChT1, ATM OC-12c, FastEthernet,
and Gigabit Ethernet.
Between the PE layer and the ISP2 domain’s backbone were first a POP aggregation layer and then a
metro aggregation layer. The POP aggregation routers were Cisco 12406 and 7609. The metro
aggregation routers were Cisco 12416 and 12016. Redundant GE links connected the PEs to the POP
aggregation routers and connected the POP aggregation routers to the metro aggregation routers. The
latter in turn were connected to the backbone through redundant POS OC-48c.
Connected to each metro aggregation router through Ethernet links were two Cisco 7206/NPE400 route
reflectors, one each for IPv4 and VPNv4, making a total of four route reflectors at the San Jose POP.
Also directly connected to one of the San Jose metro aggregation routers was a PE router (which thus
skipped the POP aggregation layer), using a POS OC-48c link.
Finally, a Cisco 7206 acted as a CE hub for the Hub-Spoke VPN, connected through a Fast Ethernet link
to the Cisco 12008 PE router.
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About MPLS VPN with QoS and Security
Figure 3
Central Domain ‘ISP2’ POS Core with Six Representative POPs
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About MPLS VPN with QoS and Security
Boston POP
Boston was a stub POP, meaning that it had just two PE routers to support all the needed features being
tested. Those two PE routers were a Cisco 12008 and a 12406. They connected to two CE routers (Cisco
12008) through Gigabit Ethernet, POS OC-12c, and ATM OC-12c links.
Infrastructure to support an Internet Data Center (IDC) was present in this POP, and HTTP client/server
traffic flows initiated and terminated into the IDC from the other POPs within the ISP2 domain.
Layer-2 networking was present in the form of two Catalyst 4006 switches at the CE level, connected in
a full-mesh configuration through GigE 802.1q links to two Catalyst 6009 switches at the PE level.
Layer-2 aggregation was accomplished through redundant GigE 802.1q links with VLAN trunking to
two Catalyst 6506 switches. Layer-3 POP aggregation was accomplished through redundant GigE
802.1q links to a Cisco 7609 and 12406 and through a single 10-GigE 802.1q link using VLAN trunking.
Finally, the two POP aggregation routers connected to the domain’s core through redundant GigE links
and one 10-GigE link. Routing protocol metrics were configured to utilize that 10-GE link over the GigE
links.
Washington DC POP
The Washington DC POP consisted of six PE and seven CE routers, two of the CEs (a Cisco
7206-NPE-G1 and a Cisco 3725) being connected to one PE, a Cisco 7206NG1. The remaining CEs and
PEs were, on each layer, a Cisco 12008, 10008, 7513, 7401 and 7304. Connections between the CEs and
PEs were GigE, FE, POS(OC-3c and OC-12c), ATM(OC-3c, T3 and E3), ChT3, T3, ChE3, E3 and E1.
POP aggregation was accomplished using three Cisco routers: a 12406, a 10005 and a 7606, connected
to the PEs via redundant GigE primary links, and via secondary OC-3c and ChT3 links.
Four route reflectors (Cisco 7206NG1s) were connected to the POP aggregation routers through Fast
Ethernet links, two reflectors to handle IPv4 and two to handle VPNv4.
Finally, the POP aggregation routers were connected to the backbone via redundant GigE links.
Left@Albuquerque POP
The Left@Albuquerque POP consisted of six CE routers connected to two PE routers, plus an additional
CE router connected to a BPX switch. The two PE routers were Cisco 7513, and the CE routers were
Cisco 7513, 3660, 3640 and 1760. The CE routers were connected to the PEs using HSSI, FastEthernet,
Ethernet, ChT1, ChT3, ATM E3 and Fast Serial interfaces.
Layer-2 aggregation was accomplished by two Cisco LS1010 switches, and Layer-3 POP aggregation by
two Cisco 12008 routers. The Cisco LS1010switches connected to the PEs via ATM OC-3c links. The
POP aggregation routers connected to the core via POS OC-48c links.
Dallas POP
The Dallas POP consisted of six CE and five PE routers, two of the CEs (a Cisco 3640 and a Cisco 12008)
being connected to one PE, a Cisco 12008. The remaining CEs and PEs were, on each layer, a Cisco
12008, 10005, 7609, 7513 and 7206. Connections between the CEs and PEs were GigE, FE, POS(OC-3c,
ChOC-12c and OC-48c), ATM OC-3c, ChT1, ChT3, ChE1, ChE3, and Fast Serial interfaces.
POP aggregation was accomplished using two Cisco routers: a 12406 and a 7609, connected to the PEs
via redundant GigE links. The POP aggregation routers, in turn, were connected to the core via
redundant channelized POS OC-48 links.
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About MPLS VPN with QoS and Security
Denver POP
The Denver POP consisted of a pair of Cisco 12008 routers acting as multiple PE-CE pairs, connected
via POS OC-12c, ATM OC-12c and Gigabit Ethernet.
POP aggregation was accomplished by two Cisco routers: a 12406 and a 7609, connected to the PE via
redundant GigE links. The POP aggregation routers, in turn, were connected to the core via redundant
GigE links.
Small POS Domain ‘ISP1’
The ISP1 domain consisted of four Cisco 7513 routers fully meshed through POS OC-3c connections,
functioning as one OSPF area (Figure 4). (The fifth 7513 router functioned as a Pagent traffic generator.)
This domain, ISP1, connected to the central domain, ISP2, through POS OC-3c links to ISP2’s “NSP
East” network service point.
Figure 4
Small POS-Core Domain, ‘ISP1’
7513
7513
OSPF Area 0
BGP - AS 1
PAGENT
7513
7513
7513
B G P - AS 1
NSP WEST
OC3 (POS)
ISP2
117471
CH-T1
BGP - AS 2
ATM WAN Domain ‘ISP3’
The ISP3 domain consisted of a seven-router backbone connected across an ATM-switch cloud, and four
POPs—three directly connected and one remotely connected(Figure 5).
ISP3 connected to the central domain, ISP2, via POS OC-3c links to ISP2’s “NSP West” network service
point, and to ISP3.1 through “NSP East”.
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About MPLS VPN with QoS and Security
Figure 5
ATM WAN Domain ‘ISP3’
Number of VPNs Supported
ISP2 supported 2,250 unique VPNs within its domain, a VPNv4 routing table size of 81,000 routes, and
as many as 1250 sites (CEs) within a single VPN. The ATM-based ISP3 supported 250 unique VPNs
within its domain, and up to 384 sites (CEs) within a single VPN. Additionally, the overall topology
maintained 30 inter-AS (Autonomous System) VPNs and 10 Carrier Supporting Carrier (CSC) VPNs.
Note
The maximum values achievable are even greater than the above numbers. Therefore, those values
should be understood as indicating guidelines for a typical setup with MPLS VPNs using 7206/NPE-400
and 7206/NPE-G1 devices as route reflectors. Many variations on this configuration can successfully
support greater amounts of the total number of unique VPNs and/or the total number of VPNv4 routes.
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Test Results Summary
Test Results Summary
The following table summarizes the results of the SP MPLS VPN testing. This table displays:
Table 4
•
the technology sets and features that were tested
•
the particular location within the profile where the tested feature was operating
•
the result of the test (pass, fail, or pass with exception)
•
any defect (“DDTS”) logged because of an exception.
nEverest SP MPLS Phase 3 Test Results Summary
KEY: PF= Passed Functional Test. PS=Passed System Test. PR=Passed Reliability Test.
EF, ES, ER = Passed the respective test but with an exception, whose ID number is given in the DDTS column.
Feature and Tests
Core
San Jose
Boston
Washington,
D.C.*
Left@
Dallas Denver
Albuquerque
IP Routing
Number of Peers
on NPE- G1
PF,
PS, PR
8-Way CEF Load
Balancing
PF,
PS, PR
Routing Table
on NPE-G1
PF,
PS, PR
Dedicated RRs w/7200
NPE-G1
PF,
PS, PR
PF, PS, PR
ISIS MD5
Authentication
PF, PS, PR PF, PS,
PR
PF, PS, PR
PF, PS, PR
PF,
PF, PS,
PS, PR PR
BGP MD5
Authentication
PF, PS, PR PF, PS,
PR
PF, PS, PR
PF, PS, PR
PF,
PF, PS,
PS, PR PR
TDP
PF, PS, PR
OSPF
PF, PS, PR
eBGP+IPv4+Label
PF,
PS, PR
MPLS VPN Inter-ASIPv4-BGP Label Distribution
PF,
PS, PR
Link Types and
Encapsulations
1-port OC-192c/
STM-64c POS/SDH
Enhanced Services
Line Card
PF,
PS, PR
4-Port OC-48c/ STM-16
POS/SDHb Enhanced
Services Line Card
PF,
PS, PR
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DDTS*
Test Results Summary
Table 4
nEverest SP MPLS Phase 3 Test Results Summary (Continued)
KEY: PF= Passed Functional Test. PS=Passed System Test. PR=Passed Reliability Test.
EF, ES, ER = Passed the respective test but with an exception, whose ID number is given in the DDTS column.
Feature and Tests
Core
San Jose
Boston
Washington,
D.C.*
4-Port OC-3c/ STM-1c
ATM Line Card
Left@
Dallas Denver
Albuquerque
DDTS*
PF, PS, PR
802.1q
PF, PS, PR PF, PS,
PR
802.1w
PF, PS,
PR
1-port 10-Gigabit
Ethernet Line Card
PF, PS,
PR
Modular Gigabit
Ethernet Line Card
PF, PS,
PR
Gigabit Ethernet Channel
Port Bundles
PF, PS,
PR
PF, PS, PR
PF,
PF, PS,
PS, PR PR
PF, PS,
PR
Link Efficiency
Link Fragmentation and
Interleaving (LFI)
PF, PS, PR
PF,
PS, PR
Frame Relay
Fragmentation Layer 2
(FRF12)
PF, PS, PR
PF, PS, PR
PF,
PS, PR
Compressed Real Time
Protocol (cRTP)
PF, PS, PR
PF, PS, PR
PF,
PS, PR
Link Management
ATM/FR VC Bundling
PF, ES, ER
Layer 2 Signaling on
4-Port OC-3c/STM-1c
ATM Line Card with
OAM
CSCec27199
PF,
PS, PR
Multilink Point-to-Point
Protocol (MLPPP)
PF, ES, PR
CSCee28332
Network Management
SNMPv3
PF, PS, PR PF, PS,
PR
PF, PS, PR
PF,
PF, PS,
PS, PR PR
Syslog
PF, PS, PR PF, PS,
PR
PF, PS, PR
PF,
PF, PS,
PS, PR PR
ACL on 10-GE
PF, PS,
PR
Quality of Service
QOS on ATM VC
bundles
PF, PS, PR
QOS on FR VC bundles
PF, PS, PR
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Test Results Summary
Table 4
nEverest SP MPLS Phase 3 Test Results Summary (Continued)
KEY: PF= Passed Functional Test. PS=Passed System Test. PR=Passed Reliability Test.
EF, ES, ER = Passed the respective test but with an exception, whose ID number is given in the DDTS column.
Feature and Tests
Core
San Jose
Boston
Washington,
D.C.*
QOS on MLPPP bundles
PF, PS, PR
CBWFQ over ATM / FR
VC bundles
PF, PS, PR
dLFI/dQOS
PF, PS, PR
Left@
Dallas Denver
Albuquerque
DDTS*
PF, PS, PR
Resiliency
CSCin54442
Single Line Card Reload
PF, PS, PR
PF, PR
PF, PR
RPR+
PF, PS, PR
PF, PS, PR
PF,
PS, PR
Monitor Convergence
Times
PF, PS, PR
PF,
PS, PR
CSCeb82510
Security
ACL on CTY/VTY
PF, PS, PR PF, PS,
PR
PF, PS, PR
PF, PS, PR
PF,
PF, PR
PS, PR
TACACS+
PF, PS, PR PF, PS,
PR
PF, PS, PR
PF, PS, PR
PF,
PF, PR
PS, PR
L2TP/IPsec
PF, PS, PR
ASWAN
PF, PS, PR
Other
24-Port Channelized
E1/T1 Line Card
PF, PS, PR
8-Port Unchannelized
E3/T3 Line Card
PF,
PS, PR
VIP6-80
PF, PS, PR
PRP-1
PF,
PF, PS, PR PF, PS,
PS, PR
PR
RSP-16
PF, PS, PR
NPE-G1
PF,
PS, PR
PF, PS, PR
PF, PS, PR
PF,
PS, PR
PF, PS, PR
PF, PS, PR
PF,
PS, PR
PF, PS, PR
3700 as CE
PF, PS, PR
7300 as PE
PF, PS, PR
CSCed80802
CSCec62678
Negative System Tests
Router Power Failure
PS, PR PS, PR
PS, PR
Single Line Card Reload
PS, PR PS, PR
PS, PR
Clear ip bgp *
PS, PR PS, PR
PS, PR
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PS, PR
PS, PR
PS, PR
PS, PR
PS, PR
Test Results Summary
Table 4
nEverest SP MPLS Phase 3 Test Results Summary (Continued)
KEY: PF= Passed Functional Test. PS=Passed System Test. PR=Passed Reliability Test.
EF, ES, ER = Passed the respective test but with an exception, whose ID number is given in the DDTS column.
Feature and Tests
Core
San Jose
Boston
Washington,
D.C.*
Left@
Dallas Denver
Albuquerque
Clear ip bgp peer-group
PS, PR PS, PR
PS, PR
PS, PR
PS, PR
Clear ip bgp neighbor
PS, PR PS, PR
PS, PR
PS, PR
PS, PR
Clear isis *
PS, PR PS, PR
PS, PR
Clear ip ospf process
PS, PR
PS, PR
Force Failover
PS, PR
Link Loss
PS, PR PS, PR
PS, PR
PS, PR
PS, PR
Link Flapping
PS, PR PS, PR
PS, PR
PS, PR
PS, PR
PS, PR
PE/CE Dynamic Routing
Instability
HSRP Failover
DDTS*
PS, PR
PS, PR
PS, PR
PS, PR
*During Test Case 3: Reliability Test, the ATM PA Helper process on one Washington CE router did not dismiss. That process
was not tied to any particular feature being tested in this profile. For more detail, please see the defect report numbered
CSCef03345.
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Test Cases
Test Cases
This profile was tested using the following progressive test stages:
•
Test Case 1: Functional Test
•
Test Case 2: System Test
•
Test Case 3: Reliability Test
Test Case 1: Functional Test
The Functional Test invoked each individual feature, and verified its performance.
IP Routing
IP Routing feature consisted of routing protocols and some security features integrated with them, as
detailed in the following Test Procedure section.
Test Procedure
To test IP Routing, the following steps were carried out:
Step 1
Invoke MD5 authentication between IS-IS peers; then verify.
Step 2
Invoke MD5 authentication between BGP peers; then verify.
Step 3
Configure MPLS VPN-CSC-IPv4-BGP label distribution; then verify.
Step 4
Configure eBGP+IPv4 label distribution; then verify.
Step 5
Configure Cisco 7206VXR routers as route reflectors; then verify.
Step 6
Configure MPLS VPN-InterAS-IPv4-BGP label distribution on the route reflectors of each service
provider, and on the ASBR routers between each service provider domain; then verify.
Step 7
Configure BGP prefix outbound route filtering; then verify.
Step 8
Configure Tag Distribution Protocol (TDP); then verify.
Step 9
Configure OSPF; then verify.
Step 10
Configure 150 peers on the Cisco 7206VXR routers that contain the NPE-G1 processor; then verify.
Step 11
Configure MPLS export route filtering; then verify.
Step 12
Verify that 8-way CEF load balancing (a default feature) is operating properly.
Step 13
Verify that the routing table on the NPE-G1 processor of each Cisco 7206VXR router is functioning
properly.
Expected Results
Routing protocols, tables, filtering, load balancing, and authentications would be established
successfully and would function accurately.
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Test Case 1: Functional Test
Results
Test
Result
IP Routing - Functional Test
Passed
Link Type/Encapsulation
This portion tested several advanced types of line cards and processors, as well as VLAN and Rapid
Spanning Tree Protocol.
Test Procedure
To test Link Type and Encapsulation, the following steps were carried out:
Step 1
Configure 802.1q VLANs; then verify.
Step 2
Configure 802.1w (Rapid Spanning Tree Protocol – RSTP); then verify.
Step 3
Configure 1-port 10-Gigabit Ethernet line cards on the Cisco Series 12400 routers; then verify.
Step 4
Configure modular Gigabit Ethernet line cards on the Cisco Series 12400 routers; then verify.
Step 5
Verify operation of the 1-port OC-192c/STM-64c POS/SDH enhanced services line cards on the Cisco
Series 12400 routers.
Step 6
Verify operation of the 4-port OC-48c/STM-16 POS/SDH enhanced services line cards on the Cisco
Series 12400 routers.
Step 7
Verify operation of the 4-port Gigabit Ethernet ISE (Internet Services Engine) line cards on the Cisco
Series 12000 and Series 12400 routers.
Step 8
Verify operation of the 4-port OC-12c/STM-4c POS/SDH ISE line cards on the Cisco Series 12000 and
Series 12400 routers.
Expected Results
Each line card, processor, and VLAN would perform well, as would RSTP.
Results
Test
Result
Link Type/Encapsulation - Functional Test
Passed
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Test Case 1: Functional Test
Link Efficiency
This tested link fragmentation and interleaving, Frame Relay fragmentation on Layer 2, and compressed
real-time protocol.
Test Procedure
To test Link Efficiency, the following steps were carried out:
Step 1
Configure Link Fragmentation and Interleaving (LFI) within the PPP configuration. Then verify that
packets were fragmented to the specified size in the traffic class to which LFI was applied.
Step 2
Configure fragment size within the Frame Relay map-class definition. Then verify that packets were
fragmented and reassembled on the opposite end of the link.
Step 3
Enable RTP compression for the desired traffic class within the MQC (Modular QoS CLI) policy maps.
Then verify that packets with RTP headers were compressed.
Expected Results
The link efficiency mechanisms would function to reduce latency and delay in the measured traffic.
Results
Test
Result
Link Efficiency - Functional Test
Passed
Link Management
This test examined virtual-circuit bundling on ATM and Frame Relay links, Multilink Point-to-Point
Protocol, and OAM on ATM.
Test Procedure
To test Link Management, the following steps were carried out:
Step 1
Configure ATM VC bundling; then verify.
Step 2
Configure Frame Relay VC bundling; then verify.
Step 3
Configure an MLPPP bundle with two or more interfaces. Then verify that all links configured for use
in the bundle were successfully established as part of the bundle.
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Test Case 1: Functional Test
Step 4
Configure OAM on the ATM interface/PVC, and then verify that OAM packets were sent and received
across the link.
Expected Results
VC bundling would function to make available different levels of service within QoS, as well as to
provide a flexible and dynamic means for increasing bandwidth.
MLPPP would increase the bandwidth of the targeted T1, channelized T1, and E1 lines.
OAM signalling would report on link status, assisting the maintenance of line quality.
Results
Test
Result
Link Management - Functional Test
Passed
Network Management
This tested SNMP (Version 3), syslog trapping, and the use of access control lists.
Test Procedure
To test Network Management, the following steps were carried out:
Step 1
Configure SNMPv3 on PE routers to pull MIBs from upstream links to POP aggregators; then verify.
Step 2
Configure NTP on all devices; then verify that router clocks have been synchronized to NTP servers.
Step 3
Configure access control lists on 1-port 10-Gigabit Ethernet Engine 4+ linecards in the Series Cisco
12400 routers; then verify.
Step 4
Configure syslog trapping; then verify that syslog messages were sent to the configured server.
Expected Results
The network reporting functions would perform well, and ACLs would be obeyed.
Results
Test
Result
Network Management - Functional Test
Passed
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Test Case 1: Functional Test
Quality of Service
The specific QoS features utilized were Priority Queuing, Low-latency Queuing, Class-based Weighted
Fair Queuing, Modified Deficit Round Robin, tail-drop for default class of service, DiffServ-compliant
Weighted Random Early Detection, Class-based WRED, IP precedence, Frame-Relay Traffic Shaping,
Distributed Traffic Shaping, and dual-layer policy map (hierarchical policies).
Test Procedure
To test Quality of Service, the following steps were carried out:
Step 1
Configure QoS on ATM VC bundles; then verify.
Step 2
Configure QoS on FR VC bundles; then verify.
Step 3
On Cisco Series 7500 routers, configure QoS on MLPPP bundles, using priority queuing, low latency
queuing, class-based weighted fair queuing, and weighted random early detection; then verify.
Step 4
Verify that distributed Link Fragmentation and Interleaving (dLFI) has been enabled by default on the
VIP linecards of Cisco 7500 routers.
Expected Results
Traffic would be successfully classified, queued, policed and shaped. (More details on the traffic classes
created and routed in this profile were given on page 16 through page 17).
Results
Test
Result
Quality of Service - Functional Test
Passed
Resiliency
This tested the recovery ability of linecards, and the operation of redundant links, power supplies, route
processors (with RPR+), fabric and scheduler cards. Additionally, Hot Standby Router Protocol was
tested on selected pairs of routers.
Test Procedure
To test Resiliency, the following steps were carried out:
Step 1
Configure single line card reload; then verify.
Step 2
Configure Route Processing Redundancy (RPR+) on Cisco Series 12000 and Series 7500 routers; then
verify.
Step 3
Introduce failures; then monitor convergence times until the network recovers.
Cisco IOS Release 12.0(26)S3
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Test Case 1: Functional Test
Expected Results
All functions would be restored quickly, without significant interruption of service to any flow of traffic.
Results
Test
Result
Resiliency - Functional Test
Passed
Security
This tested TACACS+, IPSec, and access control lists.
Test Procedure
To test Security, the following steps were carried out:
Step 1
Configure access control lists on CTY/VTY; then verify.
Step 2
Configure TACACS+; then verify.
Step 3
Configure ASWAN (the Cisco network-based IPSec VPN solution); then verify.
Step 4
Configure Layer 2 tunneling PPP with IPSec; then verify.
Expected Results
All security features would function reliably.
Results
Test
Result
Security - Functional Test
Passed
Other Functional Tests
Four types of hardware were also functionally tested:
•
8-port unchannelized E3/T3 line cards
•
24-port channelized E1/T1 line cards
•
Cisco 3700 routers in the role of CE
•
Cisco 7300 routers in the role of PE
And four advanced processors were tested: the VIP6-80 (Versatile Interface Processor), the PRP-1
(Performance Route Processor), the RSP16 (Route Switch Processor), and the NPE-G1 (Network
Processing Engine).
Cisco IOS Release 12.0(26)S3
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Test Case 1: Functional Test
Test Procedure
To test those additional devices, the following steps were carried out:
Step 1
Configure the 8-port unchannelized E3/T3 line card; then verify.
Step 2
Configure the 24-port channelized E1/T1 line card with IP, VRF, and associated QoS/MQC commands;
then verify.
Step 3
Configure the Cisco 3700 CE routers to complement interfaces found on their upstream PE
routers—including IP space, static routes and, where appropriate, MQC commands; then verify.
Step 4
Configure the Cisco 7300 PE routers; then verify
Step 5
Verify operation of the VIP6-80 (Versatile Interface Processor) line card on the Cisco Series 7500
routers.
Step 6
Verify operation of the PRP-1 (Performance Route Processor) on the Cisco Series 12000 routers.
Step 7
Verify operation of the RSP16 (Route Switch Processor) on the Cisco Series 7500 routers.
Step 8
Verify operation of the NPE-G1 processor on the Cisco 7206VXR routers.
Expected Results
Each of the eight devices would function as designed.
Results
Test
Result
Functional Test of:
•
8-port unchannelized E3/T3 line card
Passed
•
24-port channelized E1/T1 line card
Passed
•
Cisco 3700 routers in the role of CE
Passed
•
Cisco 7300 routers in the role of PE
Passed
•
VIP6-80 processor
Passed
•
PRP-1 processor
Passed
•
RSP16 processor
Passed
•
NPE-G1 processor
Passed
Cisco IOS Release 12.0(26)S3
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Test Case 2: System Test
Test Case 2: System Test
The System Test Case examined all the same features as the Functional Test, except that it ran those
features concurrently, to determine how well they all worked together. Additionally, features described
in the nEverest Phase 2 document, Service Provider MPLS System Tests for Cisco IOS Release
12.0(23)S3, were executed at the same time as these more recent (Phase 3) features.
Numerous negative tests were also run during this System Test, by removing links, clearing tables, and
toggling various processors and devices, in order to test the recovery ability of those devices, processors,
and the network as a whole.
Traffic streams were continuously monitored during this test and routers were polled daily, to measure
memory loads, CPU/processor loads, tracebacks, routing table stability, CEF and label table stability.
The pass criteria applied to this System Test Case are listed in the two Expected Results sections which
begin on page 39 and on page 42.
Expected Results
1.
No router or switch crash, reload, CPU hog, or any other significant error would occur, including a
memory allocation error or unexpected interface toggling.
2.
All P-to-P links, PE-to-CE links, and PE-to-POP Agg or POP Agg-to-Metro Agg connections would
function without significant packet loss or link failure.
3.
All VPN routes and traffic specific to each VPN would stay within the configured VPN.
4.
No site within a VPN would have a negative effect on any other site within that VPN.
5.
Traffic would be classified into the correct QoS classes.
6.
Routing protocol and real-time protocol packets would be successfully classified, and their service
would be guaranteed.
7.
Proper policing, shaping, and congestion control would occur.
8.
Routing databases on all routers in the backbone and in the POPs would converge correctly and
without major delay.
9.
If any path failed, traffic would flow through redundant paths.
Cisco IOS Release 12.0(26)S3
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Test Case 2: System Test
Results
System Test
Result
IP Routing
Passed
Link Type/Encapsulation
Passed
Link Efficiency
Passed
Link Management
Passed with Exceptions
Network Management
Passed
Quality of Service
Passed
Resiliency
Passed with Exception
Security
Passed with Exception
Other:
• 8-port unchannelized E3/T3 line card
• 24-port channelized E1/T1 line card
• Cisco 3700 routers in the role of CE
• Cisco 7300 routers in the role of PE
• VIP6-80 processor
• PRP-1 processor
• RSP16 processor
• NPE-G1 processor
Passed
Passed
Passed
Passed
Passed
Passed
Passed
Passed
Four Exceptions
Link Management
1.
The ATM VC Bundling feature encountered a problem on a Cisco Series 10008 PE router. Details
are given in the defect report numbered CSCec27199.
2.
The MLPPP feature misbehaved on one PE router after a CE router linked to that PE was reloaded
more than two times. Details are given in the defect report numbered CSCee28332.
Resiliency
3.
During OIR (Online Insertion & Removal) of the GEIP+ (Gigabit Ethernet Internet Processor +)
card on the Cisco Series 7500, the warning “SYS-2-NOBLOCK” appeared. Since that did not
indicate any actual malfunction of the router, you may ignore the message if it appears under those
circumstances. The relevant defect report is numbered CSCin54442.
Security
4.
Use of the command ip http authentication aaa during the System Test led to the HTTP server
using the login authentication and exec authorization method lists specified for the console instead
of the method lists specified for the vty lines —which had been the standard behavior in IOS versions
prior to 12.2(15)T. [The changeover from vty to console was made beginning with 12.2(15)T
because vty lines were no longer being used for HTTP connections].
Therefore, with 12.3(4)T4 you must use a common method list for HTTP and console; make sure
that the console is configured with that common method list. For further details, including
configuration examples, please refer to the defect report numbered CSCeb82510.
Cisco IOS Release 12.0(26)S3
40
Test Case 2: System Test
Negative Test Procedures
To conduct the negative tests, the following steps were carried out:
Step 1
Router Power Failure test:
a.
While the network is functioning, display and record summary reports of the status of BGP, IP
routes, and VPNs.
b.
Note the clock.
c.
Turn off power on selected active routers in the network; wait 60 seconds; then turn their power back
on.
d.
Observe the boot process for each power-cycled router and record the time each takes to come up.
e.
Watch for tracebacks or bad error messages.
f.
Display and record summary reports of BGP and IP route functioning. Record any differences
compared to the reports you generated before power-down.
g.
Record the BGP convergence time. Compare the table size with its size before power-down.
h.
Check the VPN routes summary for PE routers.
Step 2
Use the clear ip bgp * command to test convergence time of the BGP routing tables.
Step 3
Use the clear ip bgp peer-group command to test single peer-group recovery time.
Step 4
Use the clear ip bgp peer IP address command to test the recovery time of individual peers.
Step 5
Single Line Card Reload: remove the line card or VIP card from selected active routers in the network,
and observe any error messages or tracebacks.
Step 6
Use the clear isis * command to test convergence time of the IS-IS routing tables.
Step 7
Use the clear ospf * command to test convergence time of the OSPF routing tables.
Step 8
Force Failover test: observe the result of RPR+ / redundancy switchover from active to standby, and vice
versa, on dual RP or RSP-configured routers.
Step 9
Link Loss:
Step 10
Step 11
a.
Remove a single link in the network (where there are multiple paths); this will cause traffic to fall
below the baseline level.
b.
Measure the amount of time that transpires until traffic returns to the baseline level.
c.
Look for tracebacks on the routers being tested.
Link Flapping:
a.
Find a baseline level of traffic; then toggle a link (where there are multiple paths) between the link’s
up and down states. Traffic will fall below the baseline level.
b.
While continuing to bring the link up and down, measure the amount of time that it takes for the
traffic to return to the baseline level, and look for tracebacks on the router(s) being tested.
PE/CE Dynamic Routing Instability (testing the effect of routing protocol neighbor flapping):
a.
Ping from one CE to a remote CE’s interface
b.
Run the command, hw-module slot <slot-number> reload, on the PE to simulate link loss
c.
Watch for tracebacks on the PE-CE link
d.
Observe BGP activity in log messages
e.
Record the time it takes for BGP up/down and ping loss
Cisco IOS Release 12.0(26)S3
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Test Case 2: System Test
Step 12
HSRP Failover, to test the effect of shutting down an active HSRP interface:
a. Shut down a PE’s active interface while one CE linked to it pings an interface on a remote CE
b. Run the command, show standby, on the active PE router and on the standby PE router to see
if switchover occurs
c. Record the number of pings lost
d. Look for tracebacks on the routers being tested.
Expected Results of Negative Tests
1.
After the power cycle:
a. Routers should have a normal boot process and should function as they did before power down.
b. There should be no tracebacks.
c. IP routing convergence should be acceptable.
d. There should be no network connectivity failure.
2.
After clear ip bgp *: BGP table convergence should occur within 10-12 minutes; no tracebacks or
CPUHOG should occur during the BGP table recovery.
3.
After clear ip bgp peer-group and clear ip bgp peer IP address: BGP table convergence should
occur within 10-12 minutes; no tracebacks or CPUHOG should occur during the peer-group
recovery.
4.
After pulling line or VIP cards from individual routers: the router should not halt, crash or show
%RSP-3-RESTART: cbus complex error messages nor tracebacks. The router should have minimal
impact on the overall network.
5.
After clear isis *: IS-IS table convergence should occur within one minute; no tracebacks or
CPUHOG should occur during the IS-IS table recovery.
6.
After clear ospf *: OSPF table convergence should occur within one minute; no tracebacks or
CPUHOG should occur during the OSPF table recovery.
7.
After force failover: no VIPs or line cards should reset or reload; startup and running configurations
of the active and standby RPs should remain in sync; and no tracebacks should occur.
8.
After link loss: The loss of a single link should have negligible impact on the network.
9.
During link flap: traffic should move to other available active links in the network with negligible
impact on the network.
10. During PE/CE dynamic routing instability: the dynamic routing protocol and all routes should
recover with negligible impact on the network.
11. HSRP failover should trigger the standby interface to become active with negligible impact on the
network.
Cisco IOS Release 12.0(26)S3
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Test Case 2: System Test
Results
Test
Result
System Negative Tests
Passed with Exceptions
Two Exceptions
A CPUHOG occurred in two situations:
1.
When a 1-port OC12 POS interface on a Cisco 12008 router experienced link loss due to its
neighboring router being reloaded (including hardware module reloads): the CPUHOG ended within
4 seconds, and no memory leaks or subsequent CPUHOGs were observed. This is described in the
defect report numbered CSCed80802.
2.
At bootup time or while the command clear ip route * was being executed on the Engine-3 1-port
OC48 linecard (a period of about 2 seconds). No side effects were observed after bootup, nor after
the command completed. Details are available in the defect report numberedCSCec62678.
Cisco IOS Release 12.0(26)S3
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Test Case 3: Reliability Test
Test Case 3: Reliability Test
The Reliability Test utilized the same tests as the System Test Case, with the network running
continuously for a minimum of 150 hours, carrying realistic traffic loads. After the continuous run, the
Negative Tests described on page 41 were executed.
The criteria for assessment were the same as those listed in the System Test’s two Expected Results
sections, which begin on page 39 and on page 42.
Results
Test
Result
Reliability Test
Passed with Exceptions
Two Exceptions
1.
In one Customer Edge router within the Washington DC POP, the ATM PA Helper process did not
dismiss. The following error was seen every day in normal operation mode:
SPDC-7513-CE5 check logging test
Exception: -Traceback= 403B0EAC 402E501C 40303440 40303D08 40303554 402CF6A4 4027D0FC
402CC1B4 403E27EC 403E4DE8 403E4EDC 403E4A88 403E4C18 402C5360 404D1DB8 404C3EB4
Image text-base: 0x40010E80, data-base: 0x41252000
%SCHED-2-EDISMSCRIT: Critical/high priority process ATM PA Helper may not dismiss.
- Process= "ATM PA Helper", ipl= 0, pid= 61
- Traceback= 403B0EAC 402E501C 40303440 40303D08 40303554 402CF6A4 4027D0FC 402CC1B4
403E27EC 403E4DE8 403E4EDC 403E4A88 403E4C18 402C5360 404D1DB8 404C3EB4
Details are given in the defect report numbered CSCef03345.
2.
The ATM VC Bundling feature (a member of the Link Management technology set) encountered a
problem on a Cisco Series 10008 PE router. Details are given in the defect report numbered
CSCec27199.
Cisco IOS Release 12.0(26)S3
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Supplementary Information
Supplementary Information
Device Characteristics of Left@Albuquerque POP
Table 5 shows the device characteristics of the router named SPABQ-12008-POP1.
Table 5
Device Characteristics for SPABQ-12008-POP1
Hostname
SPABQ-12008-POP1
Platform
Cisco 12008
POP
Left@Albuquerque
Role/Function
Point-of-presence aggregator
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K bytes
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
2 Route Processor Cards
2 Clock Scheduler Cards
3 Switch Fabric Cards
1 Quad-port OC3c ATM controller (4 ATM).
2 OC48 POS E.D. controllers (2 POS).
2 OC48 POS controllers (2 POS).
1 Single Port Gigabit Ethernet/IEEE 802.3z controller (1 GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
1 GigabitEthernet/IEEE 802.3 interface(s)
4 ATM network interface(s)
4 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 6 shows the device characteristics of the router named SPABQ-12008-POP2.
Table 6
Device Characteristics for SPABQ-12008-POP2
Hostname
SPABQ-12008-POP2
Platform
Cisco 12008
POP
Left@Albuquerque
Role/Function
Point-of-presence aggregator
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K bytes
Cisco IOS Release 12.0(26)S3
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Supplementary Information
Table 6
Device Characteristics for SPABQ-12008-POP2
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
2 Route Processor Cards
2 Clock Scheduler Cards
3 Switch Fabric Cards
2 Quad-port OC3c ATM controllers (8 ATM).
1 OC48 POS E.D. controller (1 POS).
2 OC48 POS controllers (2 POS).
1 Ethernet/IEEE 802.3 interface(s)
8 ATM network interface(s)
3 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 7 shows the device characteristics of the router named SPABQ-1760-CE1-2.
Table 7
Device Characteristics for SPABQ-1760-CE1-2
Hostname
SPABQ-1760-CE1-2
Platform
Cisco 1760
POP
Left@Albuquerque
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
C1700-SV8Y7-M
Memory
61365K/4171K bytes
Hardware/Software
Cisco 1760 (MPC860P) processor (revision 0x200) with 61365K/4171K bytes of memory.
Processor board ID VMS06220F4W (3614485988), with hardware revision BB67
MPC860P processor: part number 5, mask 2
1 Ethernet interface
1 FastEthernet interface
2 Serial(sync/async) interfaces
32K bytes of NVRAM.
32768K bytes of processor board System flash (Read/Write)
Table 8 shows the device characteristics of the router named SPABQ-1760-CE1-3.
Table 8
Device Characteristics for SPABQ-1760-CE1-3
Hostname
SPABQ-1760-CE1-3
Platform
Cisco 1760
POP
Left@Albuquerque
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
C1700-SV8Y7-M
Cisco IOS Release 12.0(26)S3
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Supplementary Information
Table 8
Device Characteristics for SPABQ-1760-CE1-3
Memory
61409K/4127K bytes
Hardware/Software
Cisco 1760 (MPC860P) processor (revision 0x200) with 61409K/4127K bytes of memory.
Processor board ID VMS06220VRD (1098565786), with hardware revision BB67
MPC860P processor: part number 5, mask 2
1 Ethernet interface
1 FastEthernet interface
1 Serial interface
WIC T1-DSU
32K bytes of NVRAM.
32768K bytes of processor board System flash (Read/Write)
Table 9 shows the device characteristics of the router named SPABQ-3640-CE1-4.
Table 9
Device Characteristics for SPABQ-3640-CE1-4
Hostname
SPABQ-3640-CE1-4
Platform
Cisco 3640
POP
Left@Albuquerque
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
C3640-JS-M
Memory
98304K/32768K bytes
Hardware/Software
Cisco 3640 (R4700) processor (revision 0x00) with 98304K/32768K bytes of memory.
Processor board ID 28735934
R4700 CPU at 100Mhz, Implementation 33, Rev 1.0
4 FastEthernet interfaces
2 Serial interfaces
2 Serial(sync/async) interfaces
1 ATM interface
2 Channelized T1/PRI ports
DRAM configuration is 64 bits wide with parity disabled.
125K bytes of NVRAM.
32768K bytes of processor board System flash (Read/Write)
16384K bytes of processor board PCMCIA Slot0 flash (Read/Write)
Table 10 shows the device characteristics of the router named SPABQ-3660-CE2-2.
Table 10
Device Characteristics for SPABQ-3660-CE2-2
Hostname
SPABQ-3660-CE2-2
Platform
Cisco 3660
POP
Left@Albuquerque
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
C3660-JS-M
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Supplementary Information
Table 10
Device Characteristics for SPABQ-3660-CE2-2
Memory
249856K/12288K
Hardware/Software
Cisco 3660 (R527x) processor (revision 1.0) with 249856K/12288K bytes of memory.
Processor board ID JAB042985NZ
R527x CPU at 225Mhz, Implementation 40, Rev 10.0, 2048KB L2 Cache
3660 Chassis type: ENTERPRISE
2 Ethernet interfaces
2 FastEthernet interfaces
1 Serial interface
8 Channelized T1/PRI ports
1 Compression AIM
DRAM configuration is 64 bits wide with parity disabled.
125K bytes of NVRAM.
32768K bytes of processor board System flash (Read/Write)
16384K bytes of processor board PCMCIA Slot0 flash (Read/Write)
8192K bytes of processor board PCMCIA Slot1 flash (Read/Write)
Table 11 shows the device characteristics of the router named SPABQ-7206-CE2-3.
Table 11
Device Characteristics for SPABQ-7206-CE2-3
Hostname
SPABQ-7206-CE2-3
Platform
Cisco 7206VXR
POP
Left@Albuquerque
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
C7200-P-M
Memory
114688K/16384K
Hardware/Software
Cisco 7206VXR (NPE400) processor (revision A) with 114688K/16384K bytes of memory.
Processor board ID 28341875
R7000 CPU at 350Mhz, Implementation 39, Rev 3.3, 256KB L2, 4096KB L3 Cache
6 slot VXR midplane, Version 2.6
2 FastEthernet interfaces
1 ATM interface
125K bytes of NVRAM.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
125952K bytes of ATA PCMCIA card at slot 1 (Sector size 512 bytes).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 12 shows the device characteristics of the router named SPABQ-7513-CE1-1.
Table 12
Device Characteristics for SPABQ-7513-CE1-1
Hostname
SPABQ-7513-CE1-1
Platform
Cisco 7513
POP
Left@Albuquerque
Role/Function
Customer edge router
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Supplementary Information
Table 12
Device Characteristics for SPABQ-7513-CE1-1
IOS Version
12.3(4)T4
Image Name
RSP-PV-M
Memory
262144K/2072K
Hardware/Software
Cisco RSP4 (R5000) processor with 262144K/2072K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
Chassis Interface.
6 VIP2 R5K controllers (3 FastEthernet)(8 Ethernet)(8 Serial)(12 T1)(2 HSSI)(1 POS).
8 Ethernet interfaces
3 FastEthernet interfaces
10 Serial interfaces
2 HSSI interfaces
1 Packet over SONET interface
123K bytes of NVRAM.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
No slave installed in slot 7.
Table 13 shows the device characteristics of the router named SPABQ-7513-CE2-1.
Table 13
Device Characteristics for SPABQ-7513-CE2-1
Hostname
SPABQ-7513-CE2-1
Platform
Cisco 7513
POP
Left@Albuquerque
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
RSP-PV-M
Memory
262144K/2072K
Hardware/Software
Cisco RSP4 (R5000) processor with 262144K/2072K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
Chassis Interface.
6 VIP2 R5K controllers (3 FastEthernet)(8 Ethernet)(8 Serial)(12 T1)(2 HSSI)(1 POS).
8 Ethernet interfaces
3 FastEthernet interfaces
10 Serial interfaces
2 HSSI interfaces
1 Packet over SONET interface
123K bytes of NVRAM.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
No slave installed in slot 7.
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Supplementary Information
Table 14 shows the device characteristics of the router named SPABQ-7513-PE1.
Table 14
Device Characteristics for SPABQ-7513-PE1
Hostname
SPABQ-7513-PE1
Platform
Cisco 7513
POP
Left@Albuquerque
Role/Function
Provider edge router
IOS Version
12.3(4)T4
Image Name
RSP-PV-M
Memory
524288K/8216K
Hardware/Software
Cisco RSP16 (R7000A) processor with 524288K/8216K bytes of memory.
R7000 CPU at 400Mhz, Implementation 39, Rev 3.3, 256KB L2, 2048KB L3 Cache
Chassis Interface.
3 VIP6-80 RM7000B controllers (3 ATM).
6 VIP2 R5K controllers (1 FastEthernet)(8 Ethernet)(16 Serial)(8 E1)(16 T1)(2 HSSI).
2 VIP4-80 RM7000 controllers (1 Channelized T3)(1 Channelized E3).
8 Ethernet interfaces
1 FastEthernet interface
45 Serial interfaces
2 HSSI interfaces
3 ATM interfaces
1 Channelized T3 port
1 Channelized E3 port
2043K bytes of NVRAM.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
No slave installed in slot 6.
Table 15 shows the device characteristics of the router named SPABQ-7513-PE2.
Table 15
Device Characteristics for SPABQ-7513-PE2
Hostname
SPABQ-7513-PE2
Platform
Cisco 7513
POP
Left@Albuquerque
Role/Function
Provider edge router
IOS Version
12.3(4)T4
Image Name
RSP-PV-M
Memory
524288K/8216K
Cisco IOS Release 12.0(26)S3
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Supplementary Information
Table 15
Device Characteristics for SPABQ-7513-PE2
Hardware/Software
Cisco RSP16 (R7000A) processor with 524288K/8216K bytes of memory.
R7000 CPU at 400Mhz, Implementation 39, Rev 3.3, 256KB L2, 2048KB L3 Cache
Chassis Interface.
2 VIP6-80 RM7000B controllers (8 Ethernet)(1 ATM)(1 POS).
7 VIP2 R5K controllers (5 FastEthernet)(2 HSSI)(2 ATM)(1 POS).
1 VIP4-80 RM7000 controller (1 FastEthernet).
8 Ethernet interfaces
6 FastEthernet interfaces
2 HSSI interfaces
3 ATM interfaces
2 Packet over SONET interfaces
2043K bytes of NVRAM.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
No slave installed in slot 7.
Table 16 shows the device characteristics of the router named SPABQ-LS1010-POP3.
Table 16
Device Characteristics for SPABQ-LS1010-POP3
Hostname
SPABQ-LS1010-POP3
Platform
Cisco LS1010
POP
Left@Albuquerque
Role/Function
Layer 2 point-of-presence aggregator
IOS Version
12.3(4)T4
Image Name
LS1010-WP-M
Memory
65536K
Hardware/Software
Cisco LS1010 (R4600) processor with 65536K bytes of memory.
R4700 CPU at 100Mhz, Implementation 33, Rev 1.0
1 Ethernet interface
15 ATM interfaces
123K bytes of NVRAM.
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 17 shows the device characteristics of the router named SPABQ-LS1010-POP4.
Table 17
Device Characteristics for SPABQ-LS1010-POP4
Hostname
SPABQ-LS1010-POP4
Platform
Cisco LS1010
POP
Left@Albuquerque
Role/Function
Layer 2 point-of-presence aggregator
IOS Version
12.3(4)T4
Image Name
LS1010-WP-M
Memory
65536K
Cisco IOS Release 12.0(26)S3
51
Supplementary Information
Table 17
Device Characteristics for SPABQ-LS1010-POP4
Hardware/Software
Cisco LS1010 (R4600) processor with 65536K bytes of memory.
R4700 CPU at 100Mhz, Implementation 33, Rev 1.0
1 Ethernet interface
11 ATM interfaces
123K bytes of NVRAM.
8192K bytes of Flash internal SIMM (Sector size 256K).
Device Characteristics of Boston POP
Table 18 shows the device characteristics of the router named SPBOS-12008-CE1.
Table 18
Device Characteristics for SPBOS-12008-CE1
Hostname
SPBOS-12008-CE1
Platform
Cisco 12008
POP
Boston
Role/Function
Customer edge router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
1 Single-port OC12c ATM controller (1 ATM).
2 OC12 POS controllers (2 POS).
4 Three Port Gigabit Ethernet/IEEE 802.3z controllers (12 GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
12 GigabitEthernet/IEEE 802.3 interface(s)
1 ATM network interface(s)
2 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 19 shows the device characteristics of the router named SPBOS-12008-CE2.
Table 19
Device Characteristics for SPBOS-12008-CE2
Hostname
SPBOS-12008-CE2
Platform
Cisco 12008
Cisco IOS Release 12.0(26)S3
52
Supplementary Information
Table 19
Device Characteristics for SPBOS-12008-CE2
POP
Boston
Role/Function
Customer edge router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
262144K
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x05) with 262144K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
5 Three Port Gigabit Ethernet/IEEE 802.3z controllers (15 GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
15 GigabitEthernet/IEEE 802.3 interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 20 shows the device characteristics of the router named SPBOS-12008-PE1.
Table 20
Device Characteristics for SPBOS-12008-PE1
Hostname
SPBOS-12008-PE1
Platform
Cisco 12008
POP
Boston
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
C12KPRP-P-M
Memory
2097152K
Hardware/Software
Cisco 12008/PRP (MPC7450) processor (revision 0x00) with 2097152K bytes of memory.
MPC7450 CPU at 665Mhz, Rev 2.1, 256KB L2, 2048KB L3 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
1 Single-port OC12c ATM controller (1 ATM).
2 OC12 POS controllers (2 POS).
3 Three Port Gigabit Ethernet/IEEE 802.3z controllers (9 GigabitEthernet).
2 Ethernet/IEEE 802.3 interface(s)
9 GigabitEthernet/IEEE 802.3 interface(s)
1 ATM network interface(s)
2 Packet over SONET network interface(s)
2043K bytes of non-volatile configuration memory.
1000944K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
65536K bytes of Flash internal SIMM (Sector size 256K).
Cisco IOS Release 12.0(26)S3
53
Supplementary Information
Table 21 shows the device characteristics of the router named SPBOS-12406-PE2.
Table 21
Device Characteristics for SPBOS-12406-PE2
Hostname
SPBOS-12406-PE2
Platform
Cisco 12406
POP
Boston
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12406/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
2 Clock Scheduler Cards
3 Switch Fabric Cards
3 Single Port Gigabit Ethernet/IEEE 802.3z controllers (3 GigabitEthernet).
2 Modular Gigabit/Fast Ethernet/IEEE 802.3z controllers
1 Ethernet/IEEE 802.3 interface(s)
11 GigabitEthernet/IEEE 802.3 interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 22 shows the device characteristics of the router named SPBOS-12406-POP1.
Table 22
Device Characteristics for SPBOS-12406-POP1
Hostname
SPBOS-12406-POP1
Platform
Cisco 12406
POP
Boston
Role/Function
Point-of-presence aggregator
IOS Version
12.0(26)S3
Image Name
C12KPRP-P-M
Memory
524288K
Cisco IOS Release 12.0(26)S3
54
Supplementary Information
Table 22
Device Characteristics for SPBOS-12406-POP1
Hardware/Software
Cisco 12406/PRP (MPC7450) processor (revision 0x00) with 524288K bytes of memory.
MPC7450 CPU at 665Mhz, Rev 2.1, 256KB L2, 2048KB L3 Cache
2 Route Processor Cards
2 Clock Scheduler Cards
3 Switch Fabric Cards
1 Four Port Gigabit Ethernet/IEEE 802.3z controller (4 GigabitEthernet).
2 One Port 10Gigabit Ethernet/IEEE 802.3ae controllers (2 10GigabitEthernet).
1 Modular Gigabit/Fast Ethernet/IEEE 802.3z controller
2 Ethernet/IEEE 802.3 interface(s)
11 GigabitEthernet/IEEE 802.3 interface(s)
2 10GigabitEthernet/IEEE 802.3 interface(s)
2043K bytes of non-volatile configuration memory.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
65536K bytes of Flash internal SIMM (Sector size 256K).
Table 23 shows the device characteristics of the router named SPBOS-7609-POP2.
Table 23
Device Characteristics for SPBOS-7609-POP2
Hostname
SPBOS-7609-POP2
Platform
Cisco 7609
POP
Boston
Role/Function
Point-of-presence aggregator
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
Cisco OSR-7609 (R7000) processor (revision 3.1) with 458752K/65536K bytes of memory.
Processor board ID TBM06057535
R7000 CPU at 300Mhz, Implementation 39, Rev 2.1, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
2 GIGA-WAN controllers (8 GIGAWAN Ports).
1 Virtual Ethernet/IEEE 802.3 interface(s)
14 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
16384K bytes of Flash internal SIMM (Sector size 512K).
Table 24 shows the device characteristics of the router named SPBOS-6009-PE3.
Table 24
Device Characteristics for SPBOS-6009-PE3
Hostname
SPBOS-6009-PE3
Platform
Cisco 6009
POP
Boston
Role/Function
Layer 2 point-of-presence aggregator
IOS Version
12.1(20)E3
Cisco IOS Release 12.0(26)S3
55
Supplementary Information
Table 24
Device Characteristics for SPBOS-6009-PE3
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
Cisco WS-C6009 (R7000) processor (revision 1.0) with 458752K/65536K bytes of memory.
Processor board ID SCA032300A4
R7000 CPU at 300Mhz, Implementation 39, Rev 2.1, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
15 Virtual Ethernet/IEEE 802.3 interface(s)
48 FastEthernet/IEEE 802.3 interface(s)
22 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
16384K bytes of Flash internal SIMM (Sector size 512K).
Table 25 shows the device characteristics of the router named SPBOS-4006-CE3.
Table 25
Device Characteristics for SPBOS-4006-CE3
Hostname
SPBOS-4006-CE3
Platform
Catalyst 4006
POP
Boston
Role/Function
Customer edge router
IOS Version
12.1(20)EW1
Image Name
cat4000-15S-M
Memory
262144K
Hardware/Software
Cisco WS-C4006 (MPC8245) processor (revision 5) with 262144K bytes of memory.
Processor board ID FOX0525000L
1 Ethernet/IEEE 802.3 interface(s)
33 FastEthernet/IEEE 802.3 interface(s)
10 Gigabit Ethernet/IEEE 802.3 interface(s)
467K bytes of non-volatile configuration memory.
Table 26 shows the device characteristics of the router named SPBOS-6009-PE4.
Table 26
Device Characteristics for SPBOS-6009-PE4
Hostname
SPBOS-6009-PE4
Platform
Catalyst 6009
POP
Boston
Role/Function
Provider edge router
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Cisco IOS Release 12.0(26)S3
56
Supplementary Information
Table 26
Device Characteristics for SPBOS-6009-PE4
Hardware/Software
Cisco WS-C6009 (R7000) processor (revision 1.0) with 458752K/65536K bytes of memory.
Processor board ID SCA0321020C
R7000 CPU at 300Mhz, Implementation 39, Rev 2.1, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
12 Virtual Ethernet/IEEE 802.3 interface(s)
120 FastEthernet/IEEE 802.3 interface(s)
22 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
16384K bytes of Flash internal SIMM (Sector size 512K).
Table 27 shows the device characteristics of the router named SPBOS-6506-POP3.
Table 27
Device Characteristics for SPBOS-6506-POP3
Hostname
SPBOS-6506-POP3
Platform
Catalyst 6506
POP
Boston
Role/Function
Point-of-presence aggregator
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
Cisco WS-C6506 (R7000) processor (revision 3.0) with 458752K/65536K bytes of memory.
Processor board ID TBM05512804
R7000 CPU at 300Mhz, Implementation 39, Rev 2.1, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
1 Ethernet/IEEE 802.3 interface(s)
2 Virtual Ethernet/IEEE 802.3 interface(s)
18 Gigabit Ethernet/IEEE 802.3 interface(s)
1 Ten Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
16384K bytes of Flash internal SIMM (Sector size 512K).
Table 28 shows the device characteristics of the router named SPBOS-6506-POP4.
Table 28
Device Characteristics for SPBOS-6506-POP4
Hostname
SPBOS-6506-POP4
Platform
Catalyst 6506
POP
Boston
Role/Function
Point-of-presence aggregator
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Cisco IOS Release 12.0(26)S3
57
Supplementary Information
Table 28
Device Characteristics for SPBOS-6506-POP4
Memory
458752K/65536K
Hardware/Software
Cisco WS-C6506 (R7000) processor (revision 3.0) with 458752K/65536K bytes of memory.
Processor board ID TBM05512818
R7000 CPU at 300Mhz, Implementation 39, Rev 2.1, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
2 Virtual Ethernet/IEEE 802.3 interface(s)
34 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
16384K bytes of Flash internal SIMM (Sector size 512K).
Table 29 shows the device characteristics of the router named SPBOS-C4006-CE4.
Table 29
Device Characteristics for SPBOS-4006-CE4
Hostname
SPBOS-4006-POP4
Platform
Catalyst 4006
POP
Boston
Role/Function
Point-of-presence aggregator
IOS Version
12.1(20)EW1
Image Name
cat4000-15S-M
Memory
262144K
Hardware/Software
Cisco WS-C4006 (MPC8245) processor (revision 7) with 262144K bytes of memory.
Processor board ID FOX05210027
1 Ethernet/IEEE 802.3 interface(s)
49 FastEthernet/IEEE 802.3 interface(s)
8 Gigabit Ethernet/IEEE 802.3 interface(s)
467K bytes of non-volatile configuration memory.
Device Characteristics of Core
Table 30 shows the device characteristics of the router named SPCORE-12406-P1.
Table 30
Device Characteristics for SPCORE-12406-P1
Hostname
SPCORE-12406-P1
Platform
Cisco 12406
Role/Function
Provider core router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Cisco IOS Release 12.0(26)S3
58
Supplementary Information
Table 30
Device Characteristics for SPCORE-12406-P1
Hardware/Software
Cisco 12406/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
2 Clock Scheduler Cards
3 Switch Fabric Cards
2 four-port OC48 POS controllers (8 POS).
1 OC192 POS controller (1 POS).
1 Three Port Gigabit Ethernet/IEEE 802.3z controller (3 GigabitEthernet).
1 One Port 10Gigabit Ethernet/IEEE 802.3ae controller (1 10GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
3 GigabitEthernet/IEEE 802.3 interface(s)
1 10GigabitEthernet/IEEE 802.3 interface(s)
9 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 31 shows the device characteristics of the router named SPCORE-12406-P2.
Table 31
Device Characteristics for SPCORE-12406-P2
Hostname
SPCORE-12406-P2
Platform
Cisco 12406
POP
Core
Role/Function
Provider core router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12406/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
2 Clock Scheduler Cards
3 Switch Fabric Cards
2 four-port OC48 POS controllers (8 POS).
1 OC192 POS controller (1 POS).
1 Three Port Gigabit Ethernet/IEEE 802.3z controller (3 GigabitEthernet).
1 One Port 10Gigabit Ethernet/IEEE 802.3ae controller (1 10GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
3 GigabitEthernet/IEEE 802.3 interface(s)
1 10GigabitEthernet/IEEE 802.3 interface(s)
9 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Cisco IOS Release 12.0(26)S3
59
Supplementary Information
Table 32 shows the device characteristics of the router named SPCORE-12406-P5.
Table 32
Device Characteristics for SPCORE-12406-P5
Hostname
SPCORE-12406-P5
Platform
Cisco 12406
POP
Core
Role/Function
Provider core router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12406/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
2
1
3
1
1
2
Route Processor Cards
Clock Scheduler Card
Switch Fabric Cards
four-port OC48 POS controller (4 POS).
Three Port Gigabit Ethernet/IEEE 802.3z controller (3 GigabitEthernet).
OC48 channelized to STS-48c/STM-16, STS-12c/STM-4,
STS-3c/STM-1 or DS-3/E3 controllers
1 Ethernet/IEEE 802.3 interface(s)
3 GigabitEthernet/IEEE 802.3 interface(s)
6 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 33 shows the device characteristics of the router named SPCORE-12406-P6.
Table 33
Device Characteristics for SPCORE-12406-P6
Hostname
SPCORE-12406-P6
Platform
Cisco 12406
POP
Core
Role/Function
Provider core router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Cisco IOS Release 12.0(26)S3
60
Supplementary Information
Table 33
Device Characteristics for SPCORE-12406-P6
Hardware/Software
Cisco 12406/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1
1
3
1
1
1
2
Route Processor Card
Clock Scheduler Card
Switch Fabric Cards
OC48 POS controller (1 POS).
four-port OC48 POS controller (4 POS).
Three Port Gigabit Ethernet/IEEE 802.3z controller (3 GigabitEthernet).
OC48 channelized to STS-48c/STM-16, STS-12c/STM-4,
STS-3c/STM-1 or DS-3/E3 controllers
1 Ethernet/IEEE 802.3 interface(s)
3 GigabitEthernet/IEEE 802.3 interface(s)
7 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 34 shows the device characteristics of the router named SPCORE-12416-P3.
Table 34
Device Characteristics for SPCORE-12416-P3
Hostname
SPCORE-12416-P3
Platform
Cisco 12406
POP
Core
Role/Function
Provider core router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
5242288K
Hardware/Software
Cisco 12416/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
2 Route Processor Cards
2 Clock Scheduler Cards
3 Switch Fabric Cards
1 OC48 POS controller (1 POS).
2 four-port OC48 POS controllers (8 POS).
2 OC192 POS controllers (2 POS).
1 Ethernet/IEEE 802.3 interface(s)
11 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 35 shows the device characteristics of the router named SPCORE-12416-P4.
Table 35
Device Characteristics for SPCORE-12416-P4
Hostname
SPCORE-12416-P4
Platform
Cisco 12416
Cisco IOS Release 12.0(26)S3
61
Supplementary Information
Table 35
Device Characteristics for SPCORE-12416-P4
POP
Core
Role/Function
Provider core router
IOS Version
12.0(26)S3
Image Name
C12KPRP-P-M
Memory
2097152K
Hardware/Software
Cisco 12416/PRP (MPC7450) processor (revision 0x00) with 2097152K bytes of memory.
MPC7450 CPU at 665Mhz, Rev 2.1, 256KB L2, 2048KB L3 Cache
2 Route Processor Cards
1 Clock Scheduler Card
3 Switch Fabric Cards
2 four-port OC48 POS controllers (8 POS).
2 OC192 POS controllers (2 POS).
1 Modular Gigabit/Fast Ethernet/IEEE 802.3z controller
2 Ethernet/IEEE 802.3 interface(s)
4 GigabitEthernet/IEEE 802.3 interface(s)
10 Packet over SONET network interface(s)
2043K bytes of non-volatile configuration memory.
1000944K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
65536K bytes of Flash internal SIMM (Sector size 256K).
Device Characteristics of Dallas POP
Table 36 shows the device characteristics of the router named SPDAL-10005-CE4.
Table 36
Device Characteristics for SPDAL-10005-CE4
Hostname
SPBOS-10005-CE4
Platform
Cisco 10005
POP
Dallas
Role/Function
Customer edge router
IOS Version
12.0(26)S3
Image Name
C10K-P10-M
Memory
458751K/65536K
Cisco IOS Release 12.0(26)S3
62
Supplementary Information
Table 36
Device Characteristics for SPDAL-10005-CE4
Hardware/Software
Cisco C10005 (PRE1-RP) processor with 458751K/65536K bytes of memory.
R7000 CPU at 262Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
Backplane version 1.0, 5 slot
1 Ethernet/IEEE 802.3 interface(s)
1 FastEthernet/IEEE 802.3 interface(s)
2 GigabitEthernet/IEEE 802.3 interface(s)
578 Serial network interface(s)
6 Channelized T3 port(s)
1 OC12 Channelized to DS3 interface(s)
1 Channelized OC12 interface(s)
4 Channelized sonet port(s)
509K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
32768K bytes of Flash internal SIMM (Sector size 256KB).
Table 37 shows the device characteristics of the router named SPDAL-10005-PE.
Table 37
Device Characteristics for SPDAL-10005-PE4
Hostname
SPDAL-10005-PE4
Platform
Cisco 10005
POP
Dallas
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
C10K-P10-M
Memory
458751K/65536K
Hardware/Software
Cisco C10005 (PRE1-RP) processor with 458751K/65536K bytes of memory.
R7000 CPU at 262Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
Backplane version 1.0, 5 slot
1 Ethernet/IEEE 802.3 interface(s)
1 FastEthernet/IEEE 802.3 interface(s)
2 GigabitEthernet/IEEE 802.3 interface(s)
578 Serial network interface(s)
6 Channelized T3 port(s)
1 OC12 Channelized to DS3 interface(s)
1 Channelized OC12 interface(s)
4 Channelized sonet port(s)
509K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
32768K bytes of Flash internal SIMM (Sector size 256KB).
Table 38 shows the device characteristics of the router named SPDAL-12008-CE1.
Table 38
Device Characteristics for SPDAL-12008-CE1
Hostname
SPDAL-12008-CE1
Platform
Cisco 12008
POP
Dallas
Cisco IOS Release 12.0(26)S3
63
Supplementary Information
Table 38
Device Characteristics for SPDAL-12008-CE1
Role/Function
Customer edge router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
1 Quad-port OC3c ATM controller (4 ATM).
1 OC48 POS controller (1 POS).
1 twelve-port DS3 controller (12 DS3).
1 six-port E3 controller (6 E3).
1 OC12 Channelized to STS-3c POS controller (4 POS).
1 Three Port Gigabit Ethernet/IEEE 802.3z controller (3 GigabitEthernet).
1 eight-port FastEthernet/IEEE 802.3u controller (8 FastEthernet).
1 Ethernet/IEEE 802.3 interface(s)
8 FastEthernet/IEEE 802.3 interface(s)
3 GigabitEthernet/IEEE 802.3 interface(s)
4 ATM network interface(s)
5 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 39 shows the device characteristics of the router named SPDAL-12008-PE1.
Table 39
Device Characteristics for SPDAL-12008-PE1
Hostname
SPDAL-12008-PE1
Platform
Cisco 12008
POP
Dallas
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Cisco IOS Release 12.0(26)S3
64
Supplementary Information
Table 39
Device Characteristics for SPDAL-12008-PE1
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
1 Quad-port OC3c ATM controller (4 ATM).
1 Eight-port OC3c ATM controller (8 ATM).
1 OC48 POS controller (1 POS).
1 twelve-port DS3 controller (12 DS3).
1 six-port E3 controller (6 E3).
1 OC12 Channelized to STS-3c POS controller (4 POS).
1 Three Port Gigabit Ethernet/IEEE 802.3z controller (3 GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
3 GigabitEthernet/IEEE 802.3 interface(s)
12 ATM network interface(s)
5 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 40 shows the device characteristics of the router named SPDAL-12406-POP1.
Table 40
Device Characteristics for SPDAL-12406-POP1
Hostname
SPDAL-12406-POP1
Platform
Cisco 12406
POP
Dallas
Role/Function
Point-of-presence aggregator
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12406/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1
1
3
3
2
Route Processor Card
Clock Scheduler Card
Switch Fabric Cards
Three Port Gigabit Ethernet/IEEE 802.3z controllers (9 GigabitEthernet).
OC48 channelized to STS-48c/STM-16, STS-12c/STM-4,
STS-3c/STM-1 or DS-3/E3 controllers
1 Ethernet/IEEE 802.3 interface(s)
9 GigabitEthernet/IEEE 802.3 interface(s)
2 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Cisco IOS Release 12.0(26)S3
65
Supplementary Information
Table 41 shows the device characteristics of the router named SPDAL-2691-CE5-2.
Table 41
Device Characteristics for SPDAL-2691-CE5-2
Hostname
SPDAL-2691-CE5-2
Platform
Cisco 2691
POP
Dallas
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
C2691-JSX-M
Memory
223232K/38912K
Hardware/Software
Cisco 2691 (R7000) processor (revision 0.1) with 223232K/38912K bytes of memory.
Processor board ID JMX0625K87R
R7000 CPU at 160Mhz, Implementation 39, Rev 3.3, 256KB L2 Cache
2 FastEthernet interfaces
2 Serial(sync/async) interfaces
8 ATM interfaces
DRAM configuration is 64 bits wide with parity disabled.
55K bytes of NVRAM.
125184K bytes of ATA System CompactFlash (Read/Write)
Table 42 shows the device characteristics of the router named SPDAL-3640-CE1-2.
Table 42
Device Characteristics for SPDAL-3640-CE1-2
Hostname
SPDAL-3640-CE1-2
Platform
Cisco 3640
POP
Dallas
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
C3640-JS-M
Memory
119808K/1126412K
Hardware/Software
Cisco 3640 (R4700) processor (revision 0x00) with 119808K/11264K bytes of memory.
Processor board ID 28735940
R4700 CPU at 100Mhz, Implementation 33, Rev 1.0
4 FastEthernet interfaces
2 Serial(sync/async) interfaces
2 ATM interfaces
DRAM configuration is 64 bits wide with parity disabled.
125K bytes of NVRAM.
32768K bytes of processor board System flash (Read/Write)
16384K bytes of processor board PCMCIA Slot0 flash (Read/Write)
Table 43 shows the device characteristics of the router named SPDAL-7206-CE2.
Table 43
Hostname
Device Characteristics for SPDAL-7206-CE2
SPDAL-7206-CE2
Cisco IOS Release 12.0(26)S3
66
Supplementary Information
Table 43
Device Characteristics for SPDAL-7206-CE2
Platform
Cisco 7206VXR
POP
Dallas
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
C7200-P-M
Memory
393216K/131072K
Hardware/Software
Cisco 7206VXR (NPE400) processor (revision A) with 393216K/131072K bytes of memory.
Processor board ID 26788414
R7000 CPU at 350Mhz, Implementation 39, Rev 3.2, 256KB L2, 4096KB L3 Cache
6 slot VXR midplane, Version 2.6
8 Ethernet interfaces
3 FastEthernet interfaces
2 Gigabit Ethernet interfaces
82 Serial interfaces
1 ATM interface
8 Channelized T1/PRI ports
125K bytes of NVRAM.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 44 shows the device characteristics of the router named SPDAL-7206-PE2.
Table 44
Device Characteristics for SPDAL-7206-PE2
Hostname
SPDAL-7206-PE2
Platform
Cisco 7206VXR
POP
Dallas
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
C7200-P-M
Memory
491520K/32768K
Hardware/Software
Cisco 7206VXR (NPE400) processor with 491520K/32768K bytes of memory.
R7000 CPU at 350Mhz, Implementation 39, Rev 3.2, 256KB L2, 4096KB L3 Cache
6 slot VXR midplane, Version 2.6
X.25 software, Version 3.0.0.
Primary Rate ISDN software, Version 1.1.
3 FastEthernet/IEEE 802.3 interface(s)
2 GigabitEthernet/IEEE 802.3 interface(s)
82 Serial network interface(s)
1 ATM network interface(s)
8 Channelized T1/PRI port(s)
125K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
20480K bytes of Flash PCMCIA card at slot 1 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Cisco IOS Release 12.0(26)S3
67
Supplementary Information
Table 45 shows the device characteristics of the router named SPDAL-7513-CE5.
Table 45
Device Characteristics for SPDAL-7513-CE5
Hostname
SPDAL-7513-CE5
Platform
Cisco 7513
POP
Dallas
Role/Function
Customer edge router
IOS Version
12.3
Image Name
RSP-PV-M
Memory
262144K/8216K
Hardware/Software
Cisco RSP8 (R7000) processor with 262144K/8216K bytes of memory.
R7000 CPU at 250Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
Chassis Interface.
1 VIP2 R5K controller (2 FastEthernet).
9 VIP4-80 RM7000 controllers (2 FastEthernet)(2 GigabitEthernet)(24 Ethernet)(14
Serial)(8 E1)(8 T1)(1 ATM)(1 Channelized E3).
24 Ethernet interfaces
4 FastEthernet interfaces
2 Gigabit Ethernet interfaces
129 Serial interfaces
1 ATM interface
1 Channelized E3 port
2043K bytes of NVRAM.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
No slave installed in slot 7.
Table 46 shows the device characteristics of the router named SPDAL-7513-CE5.
Table 46
Device Characteristics for SPDAL-7513-CE5
Hostname
SPDAL-7513-CE5
Platform
Cisco 7513
POP
Dallas
Role/Function
Customer edge router
IOS Version
12.3
Image Name
RSP-PV-M
Memory
262144K/8216K
Cisco IOS Release 12.0(26)S3
68
Supplementary Information
Table 46
Device Characteristics for SPDAL-7513-CE5
Hardware/Software
Cisco RSP8 (R7000) processor with 262144K/8216K bytes of memory.
R7000 CPU at 250Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
Chassis Interface.
1 VIP2 R5K controller (2 FastEthernet).
9 VIP4-80 RM7000 controllers (2 FastEthernet)(2 GigabitEthernet)(24 Ethernet)
(14 Serial)(8 E1)(8 T1)(1 ATM)(1 Channelized E3).
24 Ethernet interfaces
4 FastEthernet interfaces
2 Gigabit Ethernet interfaces
129 Serial interfaces
1 ATM interface
1 Channelized E3 port
2043K bytes of NVRAM.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
No slave installed in slot 7.
Table 47 shows the device characteristics of the router named SPDAL-7513-PE5.
Table 47
Device Characteristics for SPDAL-7513-PE5
Hostname
SPDAL-7513-PE5
Platform
Cisco 7513
POP
Dallas
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
RSP-PV-M
Memory
524288K/8216K
Cisco IOS Release 12.0(26)S3
69
Supplementary Information
Table 47
Device Characteristics for SPDAL-7513-PE5
Hardware/Software
Cisco RSP16 (R7000A) processor with 524288K/8216K bytes of memory.
R7000 CPU at 400Mhz, Implementation 39, Rev 3.3, 256KB L2, 2048KB L3 Cache
G.703/E1 software, Version 1.0.
G.703/JT2 software, Version 1.0.
X.25 software, Version 3.0.0.
Primary Rate ISDN software, Version 1.1.
Channelized E1, Version 1.0.
Chassis Interface.
2 VIP6-80 RM7000B controllers (2 FastEthernet)(4 Serial)(0 E1)(0 T1).
8 VIP4-80 RM7000 controllers (2 FastEthernet)(2 GigabitEthernet)(4 Ethernet)
(10 Serial)(8 E1)(8 T1)(10 ATM)(1 Channelized E3).
4 Ethernet/IEEE 802.3 interface(s)
4 FastEthernet/IEEE 802.3 interface(s)
2 GigabitEthernet/IEEE 802.3 interface(s)
130 Serial network interface(s)
10 ATM network interface(s)
1 Channelized E3 port(s)
2043K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
Slave in slot 7.
Slave: Cisco RSP16 (R7000A) processor with 524288K bytes of memory.
Table 48 shows the device characteristics of the router named SPDAL-7606-CE3.
Table 48
Device Characteristics for SPDAL-7606-CE3
Hostname
SPDAL-7606-CE3
Platform
Cisco 7606
POP
Dallas
Role/Function
Customer Edge router
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
CISCO7606 (R7000) processor (revision 1.0) with 458752K/65536K bytes of memory.
Processor board ID TBM07230382
R7000 CPU at 300Mhz, Implementation 39, Rev 3.3, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
303 Virtual Ethernet/IEEE 802.3 interface(s)
48 FastEthernet/IEEE 802.3 interface(s)
18 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
32768K bytes of Flash internal SIMM (Sector size 512K).
Cisco IOS Release 12.0(26)S3
70
Supplementary Information
Table 49 shows the device characteristics of the router named SPDAL-7609-PE3.
Table 49
Device Characteristics for SPDAL-7609-PE3
Hostname
SPDAL-7609-PE3
Platform
Cisco 7609
POP
Dallas
Role/Function
Provider edge router
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
Cisco OSR-7609 (R7000) processor (revision 3.1) with 458752K/65536K bytes of memory.
Processor board ID TBA05520639
R7000 CPU at 300Mhz, Implementation 39, Rev 3.3, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
1 GIGA-WAN controller (4 GIGAWAN Ports).
1 Virtual Ethernet/IEEE 802.3 interface(s)
48 FastEthernet/IEEE 802.3 interface(s)
6 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
16384K bytes of Flash internal SIMM (Sector size 512K).
Table 50 shows the device characteristics of the router named SPDAL-7609-POP2.
Table 50
Device Characteristics for SPDAL-7609-POP2
Hostname
SPDAL-7609-POP2
Platform
Cisco 7609
POP
Dallas
Role/Function
Point-of-presence aggregator
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
Cisco OSR-7609 (R7000) processor (revision 3.1) with 458752K/65536K bytes of memory.
Processor board ID TBA05490493
R7000 CPU at 300Mhz, Implementation 39, Rev 2.1, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
3 GIGA-WAN controllers (12 GIGAWAN Ports).
2 1-port OC48 POS controllers (2 POS).
1 Virtual Ethernet/IEEE 802.3 interface(s)
22 Gigabit Ethernet/IEEE 802.3 interface(s)
2 Packet over SONET network interface(s)
381K bytes of non-volatile configuration memory.
16384K bytes of Flash internal SIMM (Sector size 512K).
Cisco IOS Release 12.0(26)S3
71
Supplementary Information
Device Characteristics of Washington DC POP
Table 51 shows the device characteristics of the router named SPDC-10005-POP3.
Table 51
Device Characteristics for SPDC-10005-POP3
Hostname
SPDC-10005-POP3
Platform
Cisco 10005
POP
Washington DC
Role/Function
Point-of-presence aggregator
IOS Version
12.0(26)S3
Image Name
C10K-P10-M
Memory
458751K/65536K
Hardware/Software
Cisco C10005 (PRE1-RP) processor with 458751K/65536K bytes of memory.
R7000 CPU at 262Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
Backplane version 1.0, 5 slot
1 Ethernet/IEEE 802.3 interface(s)
1 FastEthernet/IEEE 802.3 interface(s)
4 GigabitEthernet/IEEE 802.3 interface(s)
1 Serial network interface(s)
4 ATM network interface(s)
6 Channelized T3 port(s)
509K bytes of non-volatile configuration memory.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
32768K bytes of Flash internal SIMM (Sector size 256KB).
Table 52 shows the device characteristics of the router named SPDC-10008-CE4.
Table 52
Device Characteristics for SPDC-10008-CE4
Hostname
SPDC-10008-CE4
Platform
Cisco 10008
POP
Washington DC
Role/Function
Customer edge router
IOS Version
12.0(26)S3
Image Name
C10K-P10-M
Memory
458751K/65536K
Cisco IOS Release 12.0(26)S3
72
Supplementary Information
Table 52
Device Characteristics for SPDC-10008-CE4
Hardware/Software
Cisco C10008 (PRE1-RP) processor with 458751K/65536K bytes of memory.
R7000 CPU at 262Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
Backplane version 1.0, 8 slot
Channelized E1, Version 1.0.
1 Ethernet/IEEE 802.3 interface(s)
1 FastEthernet/IEEE 802.3 interface(s)
4 GigabitEthernet/IEEE 802.3 interface(s)
202 Serial network interface(s)
4 ATM network interface(s)
24 Channelized E1 port(s)
24 Channelized T1 port(s)
6 Channelized T3 port(s)
8 Subrate T3/E3 port(s)
509K bytes of non-volatile configuration memory.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
32768K bytes of Flash internal SIMM (Sector size 256KB).
Table 53 shows the device characteristics of the router named SPDC-10008-PE4.
Table 53
Device Characteristics for SPDC-10008-PE4
Hostname
SPDC-10008-PE4
Platform
Cisco 10008
POP
Washington DC
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
C10K-P10-M
Memory
458751K/65536K
Hardware/Software
Cisco C10008 (PRE1-RP) processor with 458751K/65536K bytes of memory.
R7000 CPU at 262Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
Backplane version 1.0, 8 slot
Channelized E1, Version 1.0.
1 Ethernet/IEEE 802.3 interface(s)
1 FastEthernet/IEEE 802.3 interface(s)
4 GigabitEthernet/IEEE 802.3 interface(s)
203 Serial network interface(s)
4 ATM network interface(s)
24 Channelized E1 port(s)
24 Channelized T1 port(s)
6 Channelized T3 port(s)
8 Subrate T3/E3 port(s)
509K bytes of non-volatile configuration memory.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
32768K bytes of Flash internal SIMM (Sector size 256KB).
Cisco IOS Release 12.0(26)S3
73
Supplementary Information
Table 54 shows the device characteristics of the router named SPDC-12008-CE1.
Table 54
Device Characteristics for SPDC-12008-CE1
Hostname
SPDC-12008-CE1
Platform
Cisco 12008
POP
Washington DC
Role/Function
Customer edge router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
262144K/
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x01) with 262144K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
3 OC12 POS controllers (3 POS).
4 Three Port Gigabit Ethernet/IEEE 802.3z controllers (12 GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
12 GigabitEthernet/IEEE 802.3 interface(s)
3 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 55 shows the device characteristics of the router named SPDC-12008-PE1.
Table 55
Device Characteristics for SPDC-12008-PE1
Hostname
SPDC-12008-PE1
Platform
Cisco 12008
POP
Washington DC
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
3 OC12 POS controllers (3 POS).
3 Three Port Gigabit Ethernet/IEEE 802.3z controllers (9 GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
9 GigabitEthernet/IEEE 802.3 interface(s)
3 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Cisco IOS Release 12.0(26)S3
74
Supplementary Information
Table 56 shows the device characteristics of the router named SPDC-12406-POP1.
Table 56
Device Characteristics for SPDC-12406-POP1
Hostname
SPDC-12406-POP1
Platform
Cisco 12406
POP
Washington DC
Role/Function
Point-of-presence aggregator
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12406/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
4 Three Port Gigabit Ethernet/IEEE 802.3z controllers (12 GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
12 GigabitEthernet/IEEE 802.3 interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 57 shows the device characteristics of the router named SPDC-3725-CE2-2.
Table 57
Device Characteristics for SPDC-3725-CE2-2
Hostname
SPDC-3725-CE2-2
Platform
Cisco 3725
POP
Washington DC
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
C3725-JSX-M
Memory
117760K/13312K
Hardware/Software
Cisco 3725 (R7000) processor (revision 0.1) with 117760K/13312K bytes of memory.
Processor board ID JMX0713L6E3
R7000 CPU at 240Mhz, Implementation 39, Rev 3.3, 256KB L2 Cache
4 FastEthernet interfaces
1 ATM interface
DRAM configuration is 64 bits wide with parity disabled.
55K bytes of NVRAM.
31744K bytes of ATA System CompactFlash (Read/Write)
Cisco IOS Release 12.0(26)S3
75
Supplementary Information
Table 58 shows the device characteristics of the router named SPDC-7206-CE2.
Table 58
Device Characteristics for SPDC-7206-CE2
Hostname
SPDC-7206-CE2
Platform
Cisco 7206VXR
POP
Washington DC
Role/Function
Customer edge router
IOS Version
12.2(18)S4
Image Name
C7200-P-M
Memory
229376K/32768K
Hardware/Software
Cisco 7206VXR (NPE-G1) processor (revision A) with 229376K/32768K bytes of memory.
Processor board ID 29354471
SB-1 CPU at 700Mhz, Implementation 1025, Rev 0.2, 512KB L2 Cache
6 slot VXR midplane, Version 2.7
X.25 software, Version 3.0.0.
Bridging software.
Primary Rate ISDN software, Version 1.1.
8 Ethernet/IEEE 802.3 interface(s)
4 Gigabit Ethernet/IEEE 802.3 interface(s)
56 Serial network interface(s)
2 Channelized T3 port(s)
509K bytes of non-volatile configuration memory.
62976K bytes of ATA PCMCIA card at slot 2 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
Table 59 shows the device characteristics of the router named SPDC-7206-IPRR1.
Table 59
Device Characteristics for SPDC-7206-IPRR1
Hostname
SPDC-7206-IPRR1
Platform
Cisco 7206VXR (NPE-G1)
POP
Washington DC
Role/Function
Route reflector
IOS Version
12.2(18)S4
Image Name
C7200-P-M
Memory
884736K/65536K
Cisco IOS Release 12.0(26)S3
76
Supplementary Information
Table 59
Device Characteristics for SPDC-7206-IPRR1
Hardware/Software
Cisco 7206VXR (NPE-G1) processor (revision A) with 884736K/65536K bytes of memory.
Processor board ID 29551144
SB-1 CPU at 700Mhz, Implementation 1025, Rev 0.2, 512KB L2 Cache
6 slot VXR midplane, Version 2.7
X.25 software, Version 3.0.0.
Bridging software.
2 FastEthernet/IEEE 802.3 interface(s)
3 Gigabit Ethernet/IEEE 802.3 interface(s)
509K bytes of non-volatile configuration memory.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
125952K bytes of ATA PCMCIA card at slot 2 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
Table 60 shows the device characteristics of the router named SPDC-7206-IPRR2.
Table 60
Device Characteristics for SPDC-7206-IPRR2
Hostname
SPDC-7206-IPRR2
Platform
Cisco 7206VXR (NPE-G1)
POP
Washington DC
Role/Function
Route reflector
IOS Version
12.2(18)S4
Image Name
C7200-P-M
Memory
884736K/65536K
Hardware/Software
Cisco 7206VXR (NPE-G1) processor (revision A) with 884736K/65536K bytes of memory.
Processor board ID 29498294
SB-1 CPU at 700Mhz, Implementation 1025, Rev 0.2, 512KB L2 Cache
6 slot VXR midplane, Version 2.7
X.25 software, Version 3.0.0.
Bridging software.
2 FastEthernet/IEEE 802.3 interface(s)
3 Gigabit Ethernet/IEEE 802.3 interface(s)
509K bytes of non-volatile configuration memory.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
125952K bytes of ATA PCMCIA card at slot 2 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
Table 61 shows the device characteristics of the router named SPDC-7206-PE2.
Table 61
Device Characteristics for SPDC-7206-PE2
Hostname
SPDC-7206-PE2
Platform
Cisco 7206VXR (NPE-G1)
POP
Washington DC
Role/Function
Provider edge router
Cisco IOS Release 12.0(26)S3
77
Supplementary Information
Table 61
Device Characteristics for SPDC-7206-PE2
IOS Version
12.2(18)S4
Image Name
C7200-P-M
Memory
229376K/32768K
Hardware/Software
Cisco 7206VXR (NPE-G1) processor (revision A) with 229376K/32768K bytes of memory.
Processor board ID 29497152
SB-1 CPU at 700Mhz, Implementation 1025, Rev 0.2, 512KB L2 Cache
6 slot VXR midplane, Version 2.7
X.25 software, Version 3.0.0.
Bridging software.
Primary Rate ISDN software, Version 1.1.
2 FastEthernet/IEEE 802.3 interface(s)
4 Gigabit Ethernet/IEEE 802.3 interface(s)
56 Serial network interface(s)
1 ATM network interface(s)
2 Channelized T3 port(s)
509K bytes of non-volatile configuration memory.
62976K bytes of ATA PCMCIA card at slot 2 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
Table 62 shows the device characteristics of the router named SPDC-7206-VPNRR1.
Table 62
Device Characteristics for SPDC-7206-VPNRR1
Hostname
SPDC-7206-VPNRR1
Platform
Cisco 7206VXR (NPE-G1)
POP
Washington DC
Role/Function
Route reflector
IOS Version
12.2(18)S4
Image Name
C7200-P-M
Memory
884736K/65536K
Hardware/Software
Cisco 7206VXR (NPE-G1) processor (revision A) with 884736K/65536K bytes of memory.
Processor board ID 29497916
SB-1 CPU at 700Mhz, Implementation 1025, Rev 0.2, 512KB L2 Cache
6 slot VXR midplane, Version 2.7
X.25 software, Version 3.0.0.
Bridging software.
2 FastEthernet/IEEE 802.3 interface(s)
3 Gigabit Ethernet/IEEE 802.3 interface(s)
509K bytes of non-volatile configuration memory.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
125952K bytes of ATA PCMCIA card at slot 2 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
Cisco IOS Release 12.0(26)S3
78
Supplementary Information
Table 63 shows the device characteristics of the router named SPDC-7206-VPNRR2.
Table 63
Device Characteristics for SPDC-7206-VPNRR2
Hostname
SPDC-7206-VPNRR2
Platform
Cisco 7206VXR (NPE-G1)
POP
Washington DC
Role/Function
Route reflector
IOS Version
12.2(18)S4
Image Name
C7200-P-M
Memory
884736K/65536K
Hardware/Software
Cisco 7206VXR (NPE-G1) processor (revision A) with 884736K/65536K bytes of memory.
Processor board ID 29497841
SB-1 CPU at 700Mhz, Implementation 1025, Rev 0.2, 512KB L2 Cache
6 slot VXR midplane, Version 2.7
X.25 software, Version 3.0.0.
Bridging software.
2 FastEthernet/IEEE 802.3 interface(s)
3 Gigabit Ethernet/IEEE 802.3 interface(s)
509K bytes of non-volatile configuration memory.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
125952K bytes of ATA PCMCIA card at slot 2 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
Table 64 shows the device characteristics of the router named SPDC-7304-CE3.
Table 64
Device Characteristics for SPDC-7304-CE3
Hostname
SPDC-7304-CE3
Platform
Cisco 7304
POP
Washington DC
Role/Function
Customer edge router
IOS Version
12.2(20)S2
Image Name
C7300-P-M
Memory
229376K/32768K
Cisco IOS Release 12.0(26)S3
79
Supplementary Information
Table 64
Device Characteristics for SPDC-7304-CE3
Hardware/Software
Cisco 7300 (NSE100) processor (revision E) with 229376K/32768K bytes of memory.
Processor board ID SCA070400DG
R7000 CPU at 350Mhz, Implementation 39, Rev 3.3, 256KB L2, 1024KB L3 Cache
4 slot midplane, Version 67.49
X.25 software, Version 3.0.0.
Bridging software.
1 FastEthernet/IEEE 802.3 interface(s)
2 Gigabit Ethernet/IEEE 802.3 interface(s)
6 Serial network interface(s)
2 ATM network interface(s)
6 Packet over SONET network interface(s)
509K bytes of non-volatile configuration memory.
31360K bytes of ATA compact flash in bootdisk (Sector size 512 bytes).
125440K bytes of ATA compact flash in disk0 (Sector size 512 bytes).
Table 65 shows the device characteristics of the router named SPDC-7304-PE3.
Table 65
Device Characteristics for SPDC-7304-PE3
Hostname
SPDC-7304-PE3
Platform
Cisco 7304
POP
Washington DC
Role/Function
Provider edge router
IOS Version
12.2(20)S2
Image Name
C7300-P-M
Memory
458752K/65536K
Hardware/Software
Cisco 7300 (NSE100) processor (revision E) with 458752K/65536K bytes of memory.
Processor board ID SCA071300F8
R7000 CPU at 350Mhz, Implementation 39, Rev 3.3, 256KB L2, 1024KB L3 Cache
4 slot midplane, Version 67.49
X.25 software, Version 3.0.0.
Bridging software.
1 FastEthernet/IEEE 802.3 interface(s)
2 Gigabit Ethernet/IEEE 802.3 interface(s)
6 Serial network interface(s)
2 ATM network interface(s)
6 Packet over SONET network interface(s)
509K bytes of non-volatile configuration memory.
31360K bytes of ATA compact flash in bootdisk (Sector size 512 bytes).
62976K bytes of ATA compact flash in disk0 (Sector size 512 bytes).
Table 66 shows the device characteristics of the router named SPDC-7401-CE6.
Table 66
Device Characteristics for SPDC-7401-CE6
Hostname
SPDC-7401-CE6
Platform
Cisco 7401
Cisco IOS Release 12.0(26)S3
80
Supplementary Information
Table 66
Device Characteristics for SPDC-7401-CE6
POP
Washington DC
Role/Function
Customer edge router
IOS Version
12.2(14)S8
Image Name
C7400-P-M
Memory
491520K/32768K
Hardware/Software
Cisco 7401ASR (NSE) processor (revision A) with 491520K/32768K bytes of memory.
Processor board ID 74999631
R7000 CPU at 375Mhz, Implementation 39, Rev 3.3, 256KB L2 Cache
1 slot ASR midplane, Version 2.0
X.25 software, Version 3.0.0.
Bridging software.
2 Gigabit Ethernet/IEEE 802.3 interface(s)
1 ATM network interface(s)
509K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 67 shows the device characteristics of the router named SPDC-7401-PE6.
Table 67
Device Characteristics for SPDC-7401-PE6
Hostname
SPDC-7401-PE6
Platform
Cisco 7401
POP
Washington DC
Role/Function
Provider edge router
IOS Version
12.2(14)S8
Image Name
C7400-P-M
Memory
491520K/32768K
Hardware/Software
Cisco 7401ASR (NSE) processor (revision A) with 491520K/32768K bytes of memory.
Processor board ID 74999630
R7000 CPU at 375Mhz, Implementation 39, Rev 3.3, 256KB L2 Cache
1 slot ASR midplane, Version 2.0
X.25 software, Version 3.0.0.
Bridging software.
2 Gigabit Ethernet/IEEE 802.3 interface(s)
1 ATM network interface(s)
509K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
8192K bytes of Flash internal SIMM (Sector size 256K).
Cisco IOS Release 12.0(26)S3
81
Supplementary Information
Table 68 shows the device characteristics of the router named SPDC-7513-CE5.
Table 68
Device Characteristics for SPDC-7513-CE5
Hostname
SPDC-7513-CE5
Platform
Cisco 7513
POP
Washington DC
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
RSP-PV-M
Memory
524288K/8216K
Hardware/Software
Cisco RSP16 (R7000A) processor with 524288K/8216K bytes of memory.
R7000 CPU at 400Mhz, Implementation 39, Rev 3.3, 256KB L2, 2048KB L3 Cache
Chassis Interface.
4 VIP6-80 RM7000B controllers (8 Ethernet)(3 ATM)(1 Channelized E3)(1 Channelized
OC3/STM-1).
2 VIP4-80 RM7000 controllers (2 GigabitEthernet).
8 Ethernet interfaces
2 Gigabit Ethernet interfaces
82 Serial interfaces
3 ATM interfaces
1 Channelized E3 port
1 Channelized STM-1 port
2043K bytes of NVRAM.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
No slave installed in slot 7.
Table 69 shows the device characteristics of the router named SPDC-7513-PE5.
Table 69
Device Characteristics for SPDC-7513-PE5
Hostname
SPDC-7513-PE5
Platform
Cisco 7513
POP
Washington DC
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
RSP-PV-M
Memory
524288K/8216K
Cisco IOS Release 12.0(26)S3
82
Supplementary Information
Table 69
Device Characteristics for SPDC-7513-PE5
Hardware/Software
Cisco RSP16 (R7000A) processor with 524288K/8216K bytes of memory.
R7000 CPU at 400Mhz, Implementation 39, Rev 3.3, 256KB L2, 2048KB L3 Cache
G.703/E1 software, Version 1.0.
G.703/JT2 software, Version 1.0.
X.25 software, Version 3.0.0.
Primary Rate ISDN software, Version 1.1.
Chassis Interface.
4 VIP6-80 RM7000B controllers (4 Ethernet)(3 ATM)(1 Channelized E3)(1 Channelized
STM-1).
2 VIP4-80 RM7000 controllers (2 GigabitEthernet).
4 Ethernet/IEEE 802.3 interface(s)
2 GigabitEthernet/IEEE 802.3 interface(s)
81 Serial network interface(s)
3 ATM network interface(s)
1 Channelized E3 port(s)
1 Channelized STM-1 port(s)
2043K bytes of non-volatile configuration memory.
125952K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
No slave installed in slot 7.
Table 70 shows the device characteristics of the router named SPDC-7606-POP2.
Table 70
Device Characteristics for SPDC-7606-POP2
Hostname
SPDC-7606-POP2
Platform
Cisco 7606
POP
Washington DC
Role/Function
Point-of-presence aggregator
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
Cisco CISCO7606 (R7000) processor (revision 1.0) with 458752K/65536K bytes of
memory.
Processor board ID TBM06415253
R7000 CPU at 300Mhz, Implementation 39, Rev 3.3, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
3 GIGA-WAN controllers (12 GIGAWAN Ports).
36 Virtual Ethernet/IEEE 802.3 interface(s)
48 FastEthernet/IEEE 802.3 interface(s)
32 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
32768K bytes of Flash internal SIMM (Sector size 512K).
Cisco IOS Release 12.0(26)S3
83
Supplementary Information
Device Characteristics of Denver POP
Table 71 shows the device characteristics of the router named SPDEN-7606-POP2.
Table 71
Device Characteristics for SPDEN-7606-POP2
Hostname
SPDEN-7606-POP2
Platform
Cisco 7606
POP
Washington DC
Role/Function
Point-of-presence aggregator
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
Cisco CISCO7606 (R7000) processor (revision 1.0) with 458752K/65536K bytes of
memory.
Processor board ID TBM06415253
R7000 CPU at 300Mhz, Implementation 39, Rev 3.3, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
3 GIGA-WAN controllers (12 GIGAWAN Ports).
36 Virtual Ethernet/IEEE 802.3 interface(s)
48 FastEthernet/IEEE 802.3 interface(s)
32 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
32768K bytes of Flash internal SIMM (Sector size 512K).
Table 72 shows the device characteristics of the router named SPDEN-12008-CE1.
Table 72
Device Characteristics for SPDEN-12008-CE1
Hostname
SPDEN-12008-CE1
Platform
Cisco 12008
POP
Denver
Role/Function
Customer edge router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
262144K
Cisco IOS Release 12.0(26)S3
84
Supplementary Information
Table 72
Device Characteristics for SPDEN-12008-CE1
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x01) with 262144K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
1 Single-port OC12c ATM controller (1 ATM).
2 OC12 POS controllers (2 POS).
4 Three Port Gigabit Ethernet/IEEE 802.3z controllers (12 GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
12 GigabitEthernet/IEEE 802.3 interface(s)
1 ATM network interface(s)
2 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
16384K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 73 shows the device characteristics of the router named SPDEN-12008-PE1.
Table 73
Device Characteristics for SPDEN-12008-PE1
Hostname
SPDEN-12008-PE1
Platform
Cisco 12008
POP
Denver
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
C12KPRP-P-M
Memory
2097152K
Hardware/Software
Cisco 12008/PRP (MPC7450) processor (revision 0x00) with 2097152K bytes of memory.
MPC7450 CPU at 665Mhz, Rev 2.1, 256KB L2, 2048KB L3 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
1 Single-port OC12c ATM controller (1 ATM).
2 OC12 POS controllers (2 POS).
4 Three Port Gigabit Ethernet/IEEE 802.3z controllers (12 GigabitEthernet).
2 Ethernet/IEEE 802.3 interface(s)
12 GigabitEthernet/IEEE 802.3 interface(s)
1 ATM network interface(s)
2 Packet over SONET network interface(s)
2043K bytes of non-volatile configuration memory.
1000944K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
20480K bytes of Flash PCMCIA card at slot 1 (Sector size 128K).
65536K bytes of Flash internal SIMM (Sector size 256K).
Table 74 shows the device characteristics of the router named SPDEN-12406-POP1.
Table 74
Hostname
Device Characteristics for SPDEN-12406-POP1
SPDEN-12406-POP1
Cisco IOS Release 12.0(26)S3
85
Supplementary Information
Table 74
Device Characteristics for SPDEN-12406-POP1
Platform
Cisco 12406
POP
Denver
Role/Function
Point-of-presence aggregator
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12406/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
2 Clock Scheduler Cards
3 Switch Fabric Cards
2 Three Port Gigabit Ethernet/IEEE 802.3z controllers (6 GigabitEthernet).
1 eight-port FastEthernet/IEEE 802.3u controller (8 FastEthernet).
1 Ethernet/IEEE 802.3 interface(s)
8 FastEthernet/IEEE 802.3 interface(s)
6 GigabitEthernet/IEEE 802.3 interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 75 shows the device characteristics of the router named SPDEN-7609-POP2.
Table 75
Device Characteristics for SPDEN-7609-POP2
Hostname
SPDEN-7609-POP2
Platform
Cisco 7609
POP
Denver
Role/Function
Point-of-presence aggregator
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
Cisco OSR-7609 (R7000) processor (revision 3.1) with 458752K/65536K bytes of memory.
Processor board ID TBA05520768
R7000 CPU at 300Mhz, Implementation 39, Rev 3.3, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
3 GIGA-WAN controllers (12 GIGAWAN Ports).
1 Virtual Ethernet/IEEE 802.3 interface(s)
16 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
16384K bytes of Flash internal SIMM (Sector size 512K).
Cisco IOS Release 12.0(26)S3
86
Supplementary Information
Table 76 shows the device characteristics of the router named SPDEN-7609-POP2.
Table 76
Device Characteristics for SPDEN-7609-POP2
Hostname
SPDEN-7609-POP2
Platform
Cisco 7609
POP
Denver
Role/Function
Point-of-presence aggregator
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
Cisco OSR-7609 (R7000) processor (revision 3.1) with 458752K/65536K bytes of memory.
Processor board ID TBA05520768
R7000 CPU at 300Mhz, Implementation 39, Rev 3.3, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
3 GIGA-WAN controllers (12 GIGAWAN Ports).
1 Virtual Ethernet/IEEE 802.3 interface(s)
16 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
16384K bytes of Flash internal SIMM (Sector size 512K).
Device Characteristics of the Network Service Points
Table 77 shows the device characteristics of the router named spNSPEast-12008-peer1.
Table 77
Device Characteristics for spNSPEast-12008-peer1
Hostname
spNSPEast-12008-peer1
Platform
Cisco 12008
POP
NSP East
Role/Function
Network service point
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Cisco IOS Release 12.0(26)S3
87
Supplementary Information
Table 77
Device Characteristics for spNSPEast-12008-peer1
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
1 Quad-port OC3c ATM controller (4 ATM).
2 four-port OC3 POS controllers (8 POS).
2 OC48 POS controllers (2 POS).
1 OC12 Channelized to DS3 controller (1 OC12_CH_DS3)
1 six-port E3 controller (6 E3).
1 Ethernet/IEEE 802.3 interface(s)
12 Serial network interface(s)
4 ATM network interface(s)
10 Packet over SONET network interface(s)
1 OC12 Channelized to DS3 interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 78 shows the device characteristics of the router named spNSPWest-12008-peer1.
Table 78
Device Characteristics for spNSPWest-12008-peer1
Hostname
spNSPWest-12008-peer1
Platform
Cisco 12008
POP
NSP West
Role/Function
Network service point
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
1 Quad-port OC3c ATM controller (4 ATM).
2 four-port OC3 POS controllers (8 POS).
2 OC48 POS controllers (2 POS).
1 OC12 Channelized to DS3 controller (1 OC12_CH_DS3)
1 six-port E3 controller (6 E3).
1 Ethernet/IEEE 802.3 interface(s)
12 Serial network interface(s)
4 ATM network interface(s)
10 Packet over SONET network interface(s)
1 OC12 Channelized to DS3 interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Cisco IOS Release 12.0(26)S3
88
Supplementary Information
Device Characteristics of San Jose POP
Table 79 shows the device characteristics of the router named SPSJ-10K-CE4.
Table 79
Device Characteristics for SPSJ-10K-CE4
Hostname
SPSJ-10K-CE4
Platform
Cisco 10008
POP
San Jose
Role/Function
Customer edge router
IOS Version
12.0(26)S3
Image Name
C10K-P10-M
Memory
458751K/65536K
Hardware/Software
Cisco C10008 (PRE1-RP) processor with 458751K/65536K bytes of memory.
R7000 CPU at 262Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
Backplane version 1.0, 8 slot
1 OC12 POS controller (1 POS)
1 Ethernet/IEEE 802.3 interface(s)
1 FastEthernet/IEEE 802.3 interface(s)
3 GigabitEthernet/IEEE 802.3 interface(s)
101 Serial network interface(s)
5 ATM network interface(s)
1 Packet over SONET network interface(s)
6 Channelized T3 port(s)
509K bytes of non-volatile configuration memory.
47040K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
32768K bytes of Flash internal SIMM (Sector size 256KB).
Table 80 shows the device characteristics of the router named SPSJ-10K-PE4.
Table 80
Device Characteristics for SPSJ-10K-PE4
Hostname
SPSJ-10K-PE4
Platform
Cisco 10008
POP
San Jose
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
C10K-P10-M
Memory
458751K/65536K
Cisco IOS Release 12.0(26)S3
89
Supplementary Information
Table 80
Device Characteristics for SPSJ-10K-PE4
Hardware/Software
Cisco C10008 (PRE1-RP) processor with 458751K/65536K bytes of memory.
R7000 CPU at 262Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
Backplane version 1.0, 8 slot
1 OC12 POS controller (1 POS)
1 Ethernet/IEEE 802.3 interface(s)
1 FastEthernet/IEEE 802.3 interface(s)
3 GigabitEthernet/IEEE 802.3 interface(s)
101 Serial network interface(s)
5 ATM network interface(s)
1 Packet over SONET network interface(s)
6 Channelized T3 port(s)
509K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
32768K bytes of Flash internal SIMM (Sector size 256KB).
Table 81 shows the device characteristics of the router named SPSJ-12008-CE1.
Table 81
Device Characteristics for SPSJ-12008-CE1
Hostname
SPSJ-12008-CE1
Platform
Cisco 12008
POP
San Jose
Role/Function
Customer edge router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
458751K/65536K
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x01) with 262144K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
2 OC12 POS controllers (2 POS).
1 Three Port Gigabit Ethernet/IEEE 802.3z controller (3 GigabitEthernet).
1 Four Port Gigabit Ethernet/IEEE 802.3z controller (4 GigabitEthernet).
2 eight-port FastEthernet/IEEE 802.3u controllers (16 FastEthernet).
4 OC12 channelized to STS-12c/STM-4, STS-3c/STM-1 or DS-3/E3 controllers
1 Ethernet/IEEE 802.3 interface(s)
16 FastEthernet/IEEE 802.3 interface(s)
7 GigabitEthernet/IEEE 802.3 interface(s)
1 Serial network interface(s)
3 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
16384K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Cisco IOS Release 12.0(26)S3
90
Supplementary Information
Table 82 shows the device characteristics of the router named SPSJ-12008-PE1.
Table 82
Device Characteristics for SPSJ-12008-PE1
Hostname
SPSJ-12008-PE1
Platform
Cisco 12008
POP
San Jose
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12008/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
1 Clock Scheduler Card
3 Switch Fabric Cards
2 OC12 POS controllers (2 POS).
1 OC48 POS controller (1 POS).
1 Three Port Gigabit Ethernet/IEEE 802.3z controller (3 GigabitEthernet).
1 Four Port Gigabit Ethernet/IEEE 802.3z controller (4 GigabitEthernet).
1 eight-port FastEthernet/IEEE 802.3u controller (8 FastEthernet).
4 OC12 channelized to STS-12c/STM-4, STS-3c/STM-1 or DS-3/E3 controllers
1 Ethernet/IEEE 802.3 interface(s)
8 FastEthernet/IEEE 802.3 interface(s)
7 GigabitEthernet/IEEE 802.3 interface(s)
1 Serial network interface(s)
4 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
16384K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
20480K bytes of Flash PCMCIA card at slot 1 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 83 shows the device characteristics of the router named SPSJ-12016-METRO2.
Table 83
Device Characteristics for SPSJ-12016-METRO2
Hostname
SPSJ-12016-METRO2
Platform
Cisco 12016
POP
San Jose
Role/Function
Metro aggregation router
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Cisco IOS Release 12.0(26)S3
91
Supplementary Information
Table 83
Device Characteristics for SPSJ-12016-METRO2
Hardware/Software
Cisco 12016/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
1 Route Processor Card
2 Clock Scheduler Cards
3 Switch Fabric Cards
3 OC48 POS controllers (3 POS).
1 Three Port Gigabit Ethernet/IEEE 802.3z controller (3 GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
3 GigabitEthernet/IEEE 802.3 interface(s)
3 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 84 shows the device characteristics of the router named SPSJ-12406-POP1.
Table 84
Device Characteristics for SPSJ-12406-POP1
Hostname
SPSJ-12406-POP1
Platform
Cisco 12406
POP
San Jose
Role/Function
Point-of-presence aggregator
IOS Version
12.0(26)S3
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12406/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
2 Route Processor Cards
1 Clock Scheduler Card
3 Switch Fabric Cards
3 Three Port Gigabit Ethernet/IEEE 802.3z controllers (9 GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
9 GigabitEthernet/IEEE 802.3 interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 85 shows the device characteristics of the router named SPSJ-12416-METRO1.
Table 85
Device Characteristics for SPSJ-12416-METRO1
Hostname
SPSJ-12416-METRO1
Platform
Cisco 12416
POP
San Jose
Role/Function
Metro aggregation router
IOS Version
12.0(26)S3
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Supplementary Information
Table 85
Device Characteristics for SPSJ-12416-METRO1
Image Name
GSR-P-M
Memory
524288K
Hardware/Software
Cisco 12416/GRP (R5000) processor (revision 0x05) with 524288K bytes of memory.
R5000 CPU at 200Mhz, Implementation 35, Rev 2.1, 512KB L2 Cache
2 Route Processor Cards
2 Clock Scheduler Cards
3 Switch Fabric Cards
1 OC48 POS controller (1 POS).
2 four-port OC48 POS controllers (8 POS).
1 Single Port Gigabit Ethernet/IEEE 802.3z controller (1 GigabitEthernet).
1 Three Port Gigabit Ethernet/IEEE 802.3z controller (3 GigabitEthernet).
1 Ethernet/IEEE 802.3 interface(s)
4 GigabitEthernet/IEEE 802.3 interface(s)
9 Packet over SONET network interface(s)
507K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 86 shows the device characteristics of the router named SPSJ-5300-RA3.
Table 86
Device Characteristics for SPSJ-5300-RA3
Hostname
SPSJ-5300-RA3
Platform
Cisco 5300
POP
San Jose
Role/Function
Broadband L2TP Access Concentrator (LAC)
IOS Version
12.2(15)T5
Image Name
C5300-JK8S-M
Memory
65536K/16384K
Hardware/Software
Cisco AS5300 (R4K) processor (revision A.32) with 65536K/16384K bytes of memory.
Processor board ID 09366935
R4700 CPU at 150Mhz, Implementation 33, Rev 1.0, 512KB L2 Cache
Bridging software.
X.25 software, Version 3.0.0.
SuperLAT software (copyright 1990 by Meridian Technology Corp).
TN3270 Emulation software.
Primary Rate ISDN software, Version 1.1.
Backplane revision 2
Manufacture Cookie Info:
EEPROM Type 0x0001, EEPROM Version 0x01, Board ID 0x30,
Board Hardware Version 3.1, Item Number 73-2414-05,
Board Revision D0, Serial Number 09366935,
PLD/ISP Version <unset>, Manufacture Date 14-Jul-1998.
1 Ethernet/IEEE 802.3 interface(s)
1 FastEthernet/IEEE 802.3 interface(s)
196 Serial network interface(s)
108 terminal line(s)
8 Channelized T1/PRI port(s)
128K bytes of non-volatile configuration memory.
16384K bytes of processor board System flash (Read/Write)
8192K bytes of processor board Boot flash (Read/Write)
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Supplementary Information
Table 87 shows the device characteristics of the router named SPSJ-5850-RA1.
Table 87
Device Characteristics for SPSJ-5850-RA1
Hostname
SPSJ-5850-RA1
Platform
Cisco 5850
POP
San Jose
Role/Function
Broadband L2TP Access Concentrator (LAC)
IOS Version
12.3(4)T4
Image Name
C5850-K9P9-M
Memory
458752K/65536K
Hardware/Software
Cisco c5850 (R7K) processor (revision 0.12) with bytes of memory.
Processor board ID SAA04489094
R7000 CPU at 259Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
1 FastEthernet interface
2 Gigabit Ethernet interfaces
1344 Serial interfaces
756 terminal lines
56 Channelized T1/PRI ports
2 Channelized T3 ports
507K bytes of NVRAM.
31360K bytes of Compact Flash card at slot 0 (Sector size 512).
16384K bytes of Flash internal SIMM (Sector size 256k).
Table 88 shows the device characteristics of the router named SPSJ-5850-RA2.
Table 88
Device Characteristics for SPSJ-5850-RA2
Hostname
SPSJ-5850-RA2
Platform
Cisco 5850
POP
San Jose
Role/Function
Broadband L2TP Access Concentrator (LAC)
IOS Version
12.3(4)T4
Image Name
C5850-K9P9-M
Memory
458752K/65536K
Hardware/Software
Cisco c5850 (R7K) processor (revision 0.12) with 458752K/65536K bytes of memory.
Processor board ID SAA04489094
R7000 CPU at 259Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
1 FastEthernet interface
2 Gigabit Ethernet interfaces
672 Serial interfaces
756 terminal lines
28 Channelized T1/PRI ports
2 Channelized T3 ports
507K bytes of NVRAM.
31360K bytes of Compact Flash card at slot 0 (Sector size 512).
16384K bytes of Flash internal SIMM (Sector size 256k).
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Supplementary Information
Table 89 shows the device characteristics of the router named SPSJ-7206-CE1HS.
Table 89
Device Characteristics for SPSJ-7206-CE1HS
Hostname
SPSJ-7206-CE1HS
Platform
Cisco 7206
POP
San Jose
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
C7200-P-M
Memory
114688K/16384K
Hardware/Software
Cisco 7206 (NPE150) processor (revision B) with 114688K/16384K bytes of memory.
Processor board ID 3651258
R4700 CPU at 150Mhz, Implementation 33, Rev 1.0, 512KB L2 Cache
6 slot midplane, Version 1.3
Number of Fast PAs = 3
Number of Fast+Medium PAs = 4
8 Ethernet interfaces
3 FastEthernet interfaces
125K bytes of NVRAM.
1024K bytes of packet SRAM memory.
16384K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
20480K bytes of Flash PCMCIA card at slot 1 (Sector size 128K).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 90 shows the device characteristics of the router named SPSJ-7206-CE2.
Table 90
Device Characteristics for SPSJ-7206-CE2
Hostname
SPSJ-7206-CE2
Platform
Cisco 7206VXR(NPE400)
POP
San Jose
Role/Function
Customer edge router
IOS Version
12.3(4)T4
Image Name
C7200-P-M
Memory
491520K/32768K
Hardware/Software
Cisco 7206VXR (NPE400) processor (revision A) with 491520K/32768K bytes of memory.
Processor board ID 28341751
R7000 CPU at 350Mhz, Implementation 39, Rev 3.3, 256KB L2, 4096KB L3 Cache
6 slot VXR midplane, Version 2.6
8 Ethernet interfaces
3 FastEthernet interfaces
2 Packet over SONET interfaces
125K bytes of NVRAM.
47040K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
8192K bytes of Flash internal SIMM (Sector size 256K).
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Supplementary Information
Table 91 shows the device characteristics of the router named SPSJ-7206-IPv4RR1.
Table 91
Device Characteristics for SPSJ-7206-IPv4RR1
Hostname
SPSJ-7206-IPv4RR1
Platform
Cisco 7206VXR(NPE400)
POP
San Jose
Role/Function
Route reflector
IOS Version
12.0(26)S3
Image Name
C7200-P-M
Memory
491520K/32768K
Hardware/Software
Cisco 7206VXR (NPE400) processor with 491520K/32768K bytes of memory.
R7000 CPU at 350Mhz, Implementation 39, Rev 3.2, 256KB L2, 4096KB L3 Cache
6 slot VXR midplane, Version 2.6
X.25 software, Version 3.0.0.
8 Ethernet/IEEE 802.3 interface(s)
2 FastEthernet/IEEE 802.3 interface(s)
125K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
4096K bytes of Flash internal SIMM (Sector size 256K).
Table 92 shows the device characteristics of the router named SPSJ-7206-IPv4RR2.
Table 92
Device Characteristics for SPSJ-7206-IPv4RR2
Hostname
SPSJ-7206-IPv4RR2
Platform
Cisco 7206VXR(NPE400)
POP
San Jose
Role/Function
Route reflector
IOS Version
12.0(26)S3
Image Name
C7200-P-M
Memory
491520K/32768K
Hardware/Software
Cisco 7206VXR (NPE400) processor with 491520K/32768K bytes of memory.
R7000 CPU at 350Mhz, Implementation 39, Rev 3.2, 256KB L2, 4096KB L3 Cache
6 slot VXR midplane, Version 2.6
X.25 software, Version 3.0.0.
8 Ethernet/IEEE 802.3 interface(s)
2 FastEthernet/IEEE 802.3 interface(s)
125K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
4096K bytes of Flash internal SIMM (Sector size 256K).
Table 93 shows the device characteristics of the router named SPSJ-7206-PE2.
Table 93
Hostname
Device Characteristics for SPSJ-7206-PE2
SPSJ-7206-PE2
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Supplementary Information
Table 93
Device Characteristics for SPSJ-7206-PE2
Platform
Cisco 7206VXR(NPE400)
POP
San Jose
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
C7200-P-M
Memory
491520K/32768K
Hardware/Software
Cisco 7206VXR (NPE400) processor with 491520K/32768K bytes of memory.
R7000 CPU at 350Mhz, Implementation 39, Rev 3.2, 256KB L2, 4096KB L3 Cache
6 slot VXR midplane, Version 2.0
X.25 software, Version 3.0.0.
1 FastEthernet/IEEE 802.3 interface(s)
2 GigabitEthernet/IEEE 802.3 interface(s)
2 Packet over SONET network interface(s)
125K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
4096K bytes of Flash internal SIMM (Sector size 256K).
Table 94 shows the device characteristics of the router named SPSJ-7206-PE6.
Table 94
Device Characteristics for SPSJ-7206-PE6
Hostname
SPSJ-7206-PE6
Platform
Cisco 7206VXR(NPE400)
POP
San Jose
Role/Function
Provider edge router
IOS Version
12.3(4)T4
Image Name
C7200-JK9S-M
Memory
491520K/32768K
Hardware/Software
Cisco 7206VXR (NPE400) processor (revision A) with 491520K/32768K bytes of memory.
Processor board ID 23676063
R7000 CPU at 350Mhz, Implementation 39, Rev 3.3, 256KB L2, 4096KB L3 Cache
6 slot VXR midplane, Version 2.1
6 FastEthernet interfaces
2 Gigabit Ethernet interfaces
125K bytes of NVRAM.
46976K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
8192K bytes of Flash internal SIMM (Sector size 256K).
Table 95 shows the device characteristics of the router named SPSJ-7206-VPNv4RR1.
Table 95
Device Characteristics for SPSJ-7206-VPNv4RR1
Hostname
SPSJ-7206-VPNv4RR1
Platform
Cisco 7206VXR(NPE400)
POP
San Jose
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Supplementary Information
Table 95
Device Characteristics for SPSJ-7206-VPNv4RR1
Role/Function
Route reflector
IOS Version
12.0(26)S3
Image Name
C7200-P-M
Memory
491520K/32768K
Hardware/Software
Cisco 7206VXR (NPE400) processor with 491520K/32768K bytes of memory.
R7000 CPU at 350Mhz, Implementation 39, Rev 3.2, 256KB L2, 4096KB L3 Cache
6 slot VXR midplane, Version 2.6
X.25 software, Version 3.0.0.
8 Ethernet/IEEE 802.3 interface(s)
1 FastEthernet/IEEE 802.3 interface(s)
125K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
4096K bytes of Flash internal SIMM (Sector size 256K).
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Supplementary Information
Table 96 shows the device characteristics of the router named SPSJ-7206-VPNv4RR2.
Table 96
Device Characteristics for SPSJ-7206-VPNv4RR2
Hostname
SPSJ-7206-VPNv4RR2
Platform
Cisco 7206VXR(NPE400)
POP
San Jose
Role/Function
Route reflector
IOS Version
12.0(26)S3
Image Name
C7200-P-M
Memory
491520K/32768K
Hardware/Software
Cisco 7206VXR (NPE400) processor with 491520K/32768K bytes of memory.
R7000 CPU at 350Mhz, Implementation 39, Rev 3.2, 256KB L2, 4096KB L3 Cache
6 slot VXR midplane, Version 2.6
X.25 software, Version 3.0.0.
8 Ethernet/IEEE 802.3 interface(s)
1 FastEthernet/IEEE 802.3 interface(s)
125K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
4096K bytes of Flash internal SIMM (Sector size 256K).
Table 97 shows the device characteristics of the router named SPSJ-7513-CE5.
Table 97
Device Characteristics for SPSJ-7513-CE5
Hostname
SPSJ-7513-CE5
Platform
Cisco 7513
POP
San Jose
Role/Function
Customer edge router
IOS Version
12.0(26)S3
Image Name
RSP-PV-M
Memory
262144K/8216K
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Supplementary Information
Table 97
Device Characteristics for SPSJ-7513-CE5
Hardware/Software
Cisco RSP8 (R7000) processor with 262144K/8216K bytes of memory.
R7000 CPU at 250Mhz, Implementation 39, Rev 2.1, 256KB L2, 2048KB L3 Cache
G.703/E1 software, Version 1.0.
G.703/JT2 software, Version 1.0.
Channelized E1, Version 1.0.
X.25 software, Version 3.0.0.
Primary Rate ISDN software, Version 1.1.
Chassis Interface.
2 GEIP controllers (2 GigabitEthernet)(0 E1)(0 T1).
1 VIP2 R5K controller (3 FastEthernet)(0 E1)(0 T1).
6 VIP4-80 RM7000 controllers (4 FastEthernet)(8 Ethernet)(4 Serial)(8 E1)(8 T1)
(2 ATM)(2 Channelized T3)(1 Channelized E3).
8 Ethernet/IEEE 802.3 interface(s)
7 FastEthernet/IEEE 802.3 interface(s)
2 GigabitEthernet/IEEE 802.3 interface(s)
293 Serial network interface(s)
2 ATM network interface(s)
2 Channelized T3 port(s)
1 Channelized E3 port(s)
2043K bytes of non-volatile configuration memory.
20480K bytes of Flash PCMCIA card at slot 0 (Sector size 128K).
125440K bytes of ATA PCMCIA card at slot 1 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
No slave installed in slot 7.
Table 98 shows the device characteristics of the router named SPSJ-7513-PE5.
Table 98
Device Characteristics for SPSJ-7513-PE5
Hostname
SPSJ-7513-PE5
Platform
Cisco 7513
POP
San Jose
Role/Function
Provider edge router
IOS Version
12.0(26)S3
Image Name
RSP-PV-M
Memory
524288K/8216K
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Supplementary Information
Table 98
Device Characteristics for SPSJ-7513-PE5
Hardware/Software
Cisco RSP16 (R7000A) processor with 524288K/8216K bytes of memory.
R7000 CPU at 400Mhz, Implementation 39, Rev 3.3, 256KB L2, 2048KB L3 Cache
G.703/E1 software, Version 1.0.
G.703/JT2 software, Version 1.0.
Channelized E1, Version 1.0.
X.25 software, Version 3.0.0.
Primary Rate ISDN software, Version 1.1.
Chassis Interface.
1 VIP6-80 RM7000B controller (1 FastEthernet)(4 Serial)(0 E1)(0 T1).
7 VIP4-80 RM7000 controllers (2 FastEthernet)(2 GigabitEthernet)(8 Ethernet)(8 E1)(8
T1)(2 ATM)(2 Channelized T3)(1 Channelized E3).
8 Ethernet/IEEE 802.3 interface(s)
3 FastEthernet/IEEE 802.3 interface(s)
2 GigabitEthernet/IEEE 802.3 interface(s)
293 Serial network interface(s)
2 ATM network interface(s)
2 Channelized T3 port(s)
1 Channelized E3 port(s)
2043K bytes of non-volatile configuration memory.
125440K bytes of ATA PCMCIA card at slot 0 (Sector size 512 bytes).
16384K bytes of Flash internal SIMM (Sector size 256K).
Slave in slot 7
Slave: Cisco RSP16 (R7000A) processor with 524288K bytes of memory.
Table 99 shows the device characteristics of the router named SPSJ-7606-CE3.
Table 99
Device Characteristics for SPSJ-7606-CE3
Hostname
SPSJ-7606-CE3
Platform
Cisco 7606
POP
San Jose
Role/Function
Customer edge router
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
524288K/8216K
Hardware/Software
Cisco CISCO7606 (R7000) processor (revision 1.0) with 458752K/65536K bytes of
memory.
Processor board ID TBM07230319
R7000 CPU at 300Mhz, Implementation 39, Rev 3.3, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
303 Virtual Ethernet/IEEE 802.3 interface(s)
48 FastEthernet/IEEE 802.3 interface(s)
18 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
32768K bytes of Flash internal SIMM (Sector size 512K).
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Supplementary Information
Table 100 shows the device characteristics of the router named SPSJ-7609-PE3.
Table 100
Device Characteristics for SPSJ-7609-PE3
Hostname
SPSJ-7609-PE3
Platform
Cisco 7609
POP
San Jose
Role/Function
Provider edge router
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
Cisco OSR-7609 (R7000) processor (revision 3.1) with 458752K/65536K bytes of memory.
Processor board ID TBA05302036
R7000 CPU at 300Mhz, Implementation 39, Rev 2.1, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
2 GIGA-WAN controllers (8 GIGAWAN Ports).
1 Virtual Ethernet/IEEE 802.3 interface(s)
48 FastEthernet/IEEE 802.3 interface(s)
10 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
16384K bytes of Flash internal SIMM (Sector size 512K).
Table 101 shows the device characteristics of the router named SPSJ-7609-POP2.
Table 101
Device Characteristics for SPSJ-7609-POP2
Hostname
SPSJ-7609-POP2
Platform
Cisco 7609
POP
San Jose
Role/Function
Point-of-presence aggregator
IOS Version
12.1(20)E2
Image Name
c6sup2_rp-PSV-M
Memory
458752K/65536K
Hardware/Software
Cisco OSR-7609 (R7000) processor (revision 3.1) with 458752K/65536K bytes of memory.
Processor board ID TBA05520682
R7000 CPU at 300Mhz, Implementation 39, Rev 3.3, 256KB L2, 1024KB L3 Cache
X.25 software, Version 3.0.0.
Bridging software.
4 GIGA-WAN controllers (16 GIGAWAN Ports).
1 Virtual Ethernet/IEEE 802.3 interface(s)
48 FastEthernet/IEEE 802.3 interface(s)
20 Gigabit Ethernet/IEEE 802.3 interface(s)
381K bytes of non-volatile configuration memory.
32768K bytes of Flash internal SIMM (Sector size 512K).
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Supplementary Information
CCIP, CCSP, the Cisco Arrow logo, the Cisco Powered Network mark, Cisco Unity, Follow Me Browsing, FormShare, and StackWise are
trademarks of Cisco Systems, Inc.; Changing the Way We Work, Live, Play, and Learn, and iQuick Study are service marks of Cisco Systems, Inc.;
and Aironet, ASIST, BPX, Catalyst, CCDA, CCDP, CCIE, CCNA, CCNP, Cisco, the Cisco Certified Internetwork Expert logo, Cisco IOS, the Cisco
IOS logo, Cisco Press, Cisco Systems, Cisco Systems Capital, the Cisco Systems logo, Empowering the Internet Generation, Enterprise/Solver,
EtherChannel, EtherSwitch, Fast Step, GigaStack, Internet Quotient, IOS, IP/TV, iQ Expertise, the iQ logo, iQ Net Readiness Scorecard,
LightStream, Linksys, MGX, MICA, the Networkers logo, Networking Academy, Network Registrar, Packet, PIX, Post-Routing, Pre-Routing,
RateMUX, Registrar, ScriptShare, SlideCast, SMARTnet, StrataView Plus, Stratm, SwitchProbe, TeleRouter, The Fastest Way to Increase Your
Internet Quotient, TransPath, and VCO are registered trademarks of Cisco Systems, Inc. and/or its affiliates in the United States and certain other
countries.
All other trademarks mentioned in this document or Website are the property of their respective owners. The use of the word partner does not imply
a partnership relationship between Cisco and any other company. (0402R)
Copyright © 2004 Cisco Systems, Inc. All rights reserved.
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Supplementary Information
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