JunosE 13.2.0 Release Notes

E120 and E320 System Maximums

The following tables provide system maximums for the E120 router and the E320 router.

General System Maximums

Table 8 lists some general system maximums for the E120 router and the E320 router. The following notes are referred to in Table 8:

1. The maximum number applies to any combination of VRs and VRFs. The number of VRs and VRFs that you can configure depends on your configuration. You cannot achieve the maximum number if each VR and VRF instance is running a routing protocol.
2. The maximum of 3000 VRs and VRFs can be achieved only with the SRP-120 and SRP-320 modules, which have 4 GB of memory. The limits cannot be achieved with the SRP-100 module, which has 2 GB of memory.

Table 8: General System Maximums 

Feature	E120	E320
Fabric size	120 Gbps	100 Gbps/320 Gbps
Chassis per 7-foot rack	6	3
NTP clients	1000	1000
NTP servers	300	300
Sessions per chassis (simultaneous Telnet + FTP + SSH, in any combination)	30	30
Virtual routers and VRFs per chassis, combined (See Notes 1 and 2 on page 74.)	3000	3000
Virtual routers and VRFs per line module, combined (See Notes 1 and 2 on page 74.)	3000	3000
ICR Partitions per chassis	640	640
ICR Partitions per line module	64	64

Physical and Logical Density Maximums

Table 9 lists physical and logical density maximums for the E120 router and the E320 router. The following notes are referred to in Table 9:

1. Wire rate indicates the port density that supports maximum (wire-rate) performance. Oversubscribed indicates the port density possible if you are willing to accept less than wire-rate performance by oversubscribing the available fabric bandwidth.
2. With a 120-Gbps configuration on the E120 router, you can install up to six combinations of ES2 10G Uplink LMs, ES2 10G LMs, or ES2 10G ADV LMs in slots numbered 0-5. You can install a maximum of six active ports and six redundant ports at any time.

With a 100-Gbps fabric configuration on the E320 router, you must install the ES2 10G Uplink LM or the ES2 10G LM in either of the E320 router turbo slots (2 and 4). When the ES2 10G Uplink LM or the ES2 10G LM is installed in slot 2 or slot 4, you cannot install another line module in slot 3 or slot 5. In this case, you can install the ES2 4G LM only in slots 0–1 and 6–11; therefore, the maximum number of ports and the forwarding performance per chassis is reduced for the IOAs that pair with the ES2 4G LM.

With a 320-Gbps fabric configuration on the E320 router, you can install up to 12 combinations of ES2 10G Uplink LMs, ES2 10G LMs, or ES2 10G ADV LMs in slots numbered 0-5 and 11-16. You can install a maximum of 12 active ports and 12 redundant ports at any time.

Table 9: Physical and Logical Density Maximums 

Feature	E120	E320
Physical density wire rate/oversubscribed (See Note 1 on page 75.)
10-Gigabit Ethernet ports per chassis (ES2-S1 10GE IOA)	6	12
10-Gigabit Ethernet ports per chassis (ES2-S2 10GE PR IOA) (See Note 2 on page 75.)	6 + 6	12 + 12
Gigabit Ethernet ports per chassis (ES2-S1 GE-4 IOAs)	24	48
Gigabit Ethernet ports per chassis (ES2-S1 GE-8 IOAs) (See Note 2 on page 75.)	96	192
Gigabit Ethernet ports per chassis (ES2-S3 GE-20 IOA) (See Note 2 on page 75.)	120	240
OC3/STM-1 ATM ports per chassis (ES2-S1 OC3-8 STM1 ATM IOAs)	96	192
OC12/STM-4 ATM ports per chassis (ES2-S1 OC12-2 STM4 ATM IOAs)	24	48
OC12/STM-4 POS ports per chassis (ES2-S1 OC12-2 STM4 POS IOAs)	24	48
OC48/STM16 ports per chassis (ES2-S1 OC48 STM16 POS IOAs)	6	12
Logical density per chassis
Logical OC3/STM1 per chassis	96	192
Logical OC12/STM4 per chassis	24	48
Logical OC48/STM16 per chassis	6	12

Link Layer Maximums

Table 10 lists link layer maximums for the E120 router and the E320 router. The following notes are referred to in Table 10:

1. On the ES2 10G LM, ES2 10G ADV LM, or ES2 10 G Uplink LM, you can have configurations with up to 100,000 static entries that support 100,000 DHCP relay proxy clients. You can have an additional 28,000 static or dynamic entries for network resources, such as RADIUS and DHCP servers. However, the total number of dynamic entries in the ARP table is still restricted to a maximum of 32,768 per line module.
2. On the E120 router, the SRP-120 and the SRP-320 support a maximum of 64,000 interfaces.

On the E320 router, the SRP-320 supports a maximum of 96,000 interfaces. The SRP-100 supports a maximum of 64,000 interfaces.

3. The E120 router supports a maximum of 64,000 interface columns of all types combined. The E320 router supports a maximum of 96,000 interface columns of all types combined. You can use all dynamic interfaces, or all static interfaces, or a combination of dynamic and static interfaces to achieve this maximum.

The JunosE Software supports up to 10,000 PPP interfaces with EAP authentication negotiation configured. Performance and scalability is unchanged when EAP is not configured.

4. The E120 router supports a maximum of 64,000 Ethernet subinterfaces that can be active at any one time. The E320 router supports a maximum of 96,000 Ethernet subinterfaces that can be active at any one time. Of this total, you can configure all single-tagged VLAN subinterfaces, all double-tagged S-VLAN subinterfaces, or a combination of both VLAN subinterfaces and S-VLAN subinterfaces to achieve this maximum.
5. The E120 router and the E320 router support 16,384 VLAN subinterfaces per slot on the ES2 4G LM and the ES2 10G LM, and 32,768 VLAN subinterfaces per slot on the ES2 10G ADV LM. On the E120 router, a maximum of 64,000 VLAN subinterfaces is supported per chassis. On the E320 router, a maximum of 96,000 VLAN subinterfaces is supported per chassis. You can use all dynamic interfaces, or all static interfaces, or a combination of dynamic and static interfaces to achieve this maximum.
6. For all LMs, no more than 16,384 S-VLANs are supported per port. The ES2 10G ADV LM supports 32,768 S-VLANs per module. All other LMs support only 16,384 S-VLANs per module.
7. For all LMs, no more than 4096 VLANs are supported per port. The ES2 10G ADV LM supports 32,768 VLANs per module. All other LMs support only 16,384 VLANs per module.
8. No more than 8192 VLAN major interfaces are supported per line module.

Table 10: Link Layer Maximums 

Feature	E120	E320
ARP entries per line module
Dynamic entries per LM	32,768	32,768
Static entries per ES2 4G LM	32,768	32,768
Static entries per ES2 10G LM, ES2 10G ADV LM, or ES2 10G Uplink LM (See Note 1 on page 77.)	128,000	128,000
Total entries per ES2 4G LM	32,768	32,768
Total entries per ES2 10G LM, ES2 10G ADV LM, or ES2 10G Uplink LM (See Note 1 on page 77.)	128,000	128,000
ATM bulk configuration VC ranges per chassis	300	1025
ATM bulk configuration VC ranges per line module	300	1025
ATM bulk configuration total VCs per chassis	192,000	384,000
ATM bulk configuration total VCs per line module
ES2 4G LM and OCx/STMx ATM IOA	32,000	32,000
ATM bulk configuration overriding profile assignments per chassis	100	100
ATM VCs per chassis (See Note 2 on page 77.)	64,000	96,000
ATM VCs per line module
ES2 4G LM and OCx/STMx ATM IOA	16,000	16,000
ATM VCs per port
ES2 4G LM and OCx/STMx ATM IOA	16,000	16,000
ATM VC classes per chassis	100	100
ATM VP/VC addresses per line module
ES2 4G LM and OCx/STMx ATM IOA	24-bit	24-bit
ATM VP tunnels per port, all supported modules	256	256
Bridged Ethernet interfaces per chassis (See Notes 2 and 3 on page 77.)	64,000	96,000
Bridged Ethernet interfaces per line module (OCx/STMx ATM)	16,000	16,000
Dynamic interfaces
Active autosensed dynamic interface columns per chassis over static or dynamic (bulk) ATM1483 subinterfaces (See Note 2 on page 77.)	64,000	96,000
Ethernet 802.3ad Link Aggregation
Links per LAG (bundle)	8	8
LAGs (bundles) per chassis	64	64
Ethernet S-VLANs per chassis (See Notes 2, 4, and 5 on page 77.)	64,000	96,000
Ethernet S-VLANs per IOA (See Note 6 on page 77.)
ES2-S1 GE-4 IOA (with ES2 4G LM)	16,384	16,384
ES2-S1 GE-8 IOA (with ES2 4G LM or ES2 10G LM)	16,384	16,384
ES2-S1 GE-8 IOA (with ES2 10G ADV LM)	32,768	32,768
ES2-S1 10GE IOA (with ES2 4G LM)	16,384	16,384
ES2-S2 10GE PR IOA (with ES2 10G LM or ES2 10G Uplink LM)	16,384	16,384
ES2-S2 10GE PR IOA (with ES2 10G ADV LM)	32,768	32,768
ES2-S3 GE-20 IOA (with ES2 10G LM)	16,384	16,384
ES2-S3 GE-20 IOA (with ES2 10G ADV LM)	32,768	32,768
Ethernet VLANs per chassis (See Notes 2, 4, and 5 on page 77.)	64,000	96,000
Ethernet VLANs per IOA (See Note 7 on page 77.)
ES2-S1 GE-4 IOA (with ES2 4G LM) (See Note 5 on page 77.)	16,384	16,384
ES2-S1 GE-8 IOA (with ES2 4G LM or ES2 10G LM) (See Note 5 on page 77.)	16,384	16,384
ES2-S1 GE-8 IOA (with ES2 10G ADV LM) (See Note 5 on page 77.)	32,768	32,768
ES2-S1 10GE IOA (with ES2 4G LM) (See Note 5 on page 77.)	16,384	16,384
ES2-S2 10GE PR IOA (with ES2 10G LM, ES2 10G ADV LM, or ES2 10G Uplink LM) (See Note 5 on page 77.)	4096	4096
ES2-S3 GE-20 IOA (with ES2 10G LM)	16,384	16,384
ES2-S3 GE-20 IOA (with ES2 10G ADV LM)	32,768	32,768
Ethernet VLAN major interfaces over Bridged Ethernet Interfaces, per IOA (See Note 8 on page 77.)
ES2-S1 GE-4 IOA (with ES2 4G LM)	8192	8192
ES2-S1 GE-8 IOA (with ES2 4G LM, ES2 10G LM, or ES2 10G ADV LM)	8192	8192
ES2-S1 10GE IOA (with ES2 4G LM)	8192	8192
ES2-S2 10GE PR IOA (with ES2 10G LM, ES2 10G ADV LM, or ES2 10G Uplink LM)	4096	4096
ES2-S3 GE-20 IOA (with ES2 10G LM or ES2 10G ADV LM)	8192	8192
Ethernet VLAN bulk configuration VLAN ranges per chassis	1000	1000
Ethernet VLAN bulk configuration VLAN ranges per line module	500	500
Ethernet VLAN overriding profile assignments per chassis	200	200
Ethernet VRRP VRIDs per line module	800	800
HDLC interfaces per chassis	24,000	24,000
HDLC interfaces per line module	8000	8000
MLPPP bundles per chassis	12,000	12,000
MLPPP bundles per line module	The maximum number of MLPPP bundles supported per line module is the lesser of the maximum number of MLPPP bundles supported per chassis or of the maximum number of interfaces supported on the line module. For more information, see the JunosE Link Layer Configuration Guide.
PPP major interfaces per chassis (See Notes 2 and 3 on page 77.)	64,000	96,000
PPP major interfaces per line module (ignoring physical interface constraints)
ES2 4G LM	16,000	16,000
ES2 10G LM	16,000	16,000
ES2 10G ADV LM	32,000	32,000
PPP subinterfaces per chassis (See Notes 2 and 3 on page 77.)	64,000	96,000
PPP subinterfaces per line module (ignoring physical interface constraints)
ES2 4G LM	16,000	16,000
ES2 10G LM	16,000	16,000
ES2 10G ADV LM	32,000	32,000
PPP packet logging
Aggregate dynamic and static PPP interfaces for which you can log PPP packets per chassis	32	32
PPPoE service name tables
PPPoE service name tables per chassis	16	16
Service name tags per PPPoE service name table (including one empty service name tag)	17	17
PPPoE subinterfaces per chassis (See Notes 2 and 3 on page 77.)	64,000	96,000
PPPoE subinterfaces per line module
ES2 4G LM	16,000	16,000
ES2 10G LM	16,000	16,000
ES2 10G ADV LM	32,000	32,000
Transparent bridging and VPLS
Bridge groups or VPLS instances per chassis	1024	1024
Bridge interfaces per line module in bridge groups or VPLS instances	8000	8000
Bridge interfaces per chassis in bridge groups or VPLS instances	32,000	32,000
Learned MAC address entries combined for all bridge groups and VPLS instances on a chassis	64,000	64,000

Routing Protocol Maximums

Table 11 lists routing protocol maximums for the E120 router and the E320 router. The following notes are referred to in Table 11:

1. The total set of FTEs can be shared by interfaces, next hops, ECMP sets, VRs, and VRFs. Next-hop FTEs identify the next hop on multiaccess media, such as ATM multipoint, Ethernet, or bridged Ethernet. Each VR or VRF consumes three entries. Each interface, next hop, and ECMP set consumes a single entry. One FTE is reserved for internal use, and the system software limits the number of FTEs used by interfaces to a maximum of 32,000. The remaining FTEs can be shared across the other types.
2. You can use either all dynamic interfaces or a combination of dynamic and static interfaces to achieve this maximum.
3. These values are subject to limitations on available SRP module memory, which varies according to your router configuration.
4. Depending on your configuration, the router may support more routing table entries or fewer routing table entries than this value. In any case, you can choose to limit the number of routes that can be added to the routing table on a per-VR or per-VRF basis by means of the maximum routes command.
5. The maximum number of ANCP adjacencies can be scaled over a maximum of 100 virtual routers. Fewer ANCP adjacencies can be scaled in configurations with more than 100 virtual routers.
6. On the E320 router, you can achieve 32,767 total Martini circuits only over Ethernet interfaces. For all routers, the total Martini circuits can be any combination of external inter-router circuits and internal circuits (local cross-connects).
7. There is no per-VR limit; all multicast routes can be on a single VR or present across multiple VRs.
8. The maximum number of interfaces can be achieved by any combination; for example, two streams each being replicated to 32,768 interfaces; 16,384 streams each being replicated four times; or any other combination.

Table 11: Routing Protocol Maximums 

Feature	E120	E320
BFD
Sessions per line module for ES2 4G LM	100	100
Sessions per line module for all modules other than ES2 4G LM	50	50
ECMP maximum paths to a destination
BGP, IS-IS, MPLS, OSPF, RIP	16	16
IPv4 forwarding table entries per chassis (See Note 1 on page 82.)	1,048,576	1,048,576
IP network interfaces (IPv4 and IPv6)
Per chassis (See Note 2 on page 82.)	96,001	96,001
Per ES2 4G LM	16,383	16,383
Per ES2 10G LM	16,383	16,383
Per ES2 10G ADV LM	32,767	32,767
Per ES2 10G Uplink LM	16,383	16,383
IPv4 routing protocol scaling and peering densities (See Note 3 on page 82.)
Routing table entries (See Note 4 on page 82.)	500,000	500,000
ANCP Adjacency Scaling (See Note 5 on page 82.)	5000	5000
BGP-4 peering sessions	3000	3000
BGP-4 routes (NLRI)	1,500,000	1,500,000
IP next hops (egress FECs); used to represent the IP addresses of next-hop routers on Ethernet interfaces	1,000,000	1,000,000
MPLS next hops (egress FECs) when graceful restart is not enabled for ES2 4G LM	500,000	500,000
MPLS next hops (egress FECs) when graceful restart is not enabled for all line modules other than ES2 4G LM	300,000	300,000
MPLS next hops (egress FECs) when graceful restart is enabled	250,000	250,000
MPLS forwarding entries when graceful restart is not enabled	64,000	64,000
MPLS forwarding entries when graceful restart is enabled	32,000	32,000
IS-IS adjacencies	150	150
IS-IS routes	20,000	20,000
MPLS LDP LSPs when graceful restart is not enabled	10,000	10,000
MPLS LDP LSPs when graceful restart is enabled	5000	5000i
MPLS RSVP-TE LSPs when graceful restart is not enabled	10,000	10,000
MPLS RSVP-TE LSPs when graceful restart is enabled	5000	5000
OSPF adjacencies	1000	1000
OSPF routes	25,000	25,000
IPv6 routing table entries (See Note 3 on page 82.)	100,000	100,000
J-Flow statistics
J-Flow–enabled VRs and VRFs, in any combination	16	16
Sampled interfaces per VR or VRF	32	32
Total sampled Interfaces per chassis	512	512
Martini circuits for layer 2 services over MPLS
Total Martini circuits per line module	16,000	16,000
Total Martini circuits per chassis (See Note 6 on page 82.)	16,000	32,767
External Martini circuits per chassis	16,000	32,767
Internal Martini circuits (local cross-connects) per chassis	16,000	32,767
Mobile IP bindings per chassis	–	96,000
Multicast routes (IPv4 and IPv6)
Forwarding entries [(S,G) pairs] per chassis (See Note 7 on page 82.)	16,384	16,384
Outgoing interfaces per chassis (See Note 8 on page 82.)	65,536	65,536
Response Time Reporter simultaneous operations per VR	500	500
Response Time Reporter maximum tests per chassis (SRP-100 or SRP-320)	–	500
Response Time Reporter maximum tests per virtual router (SRP-100 or SRP-320)	–	100
VRRP VRIDs per line module	See Ethernet VRRP VRIDs per line module on page 80.	See Ethernet VRRP VRIDs per line module on page 80.

Policy and QoS Maximums

Table 12 lists policy and QoS maximums for the E120 router and the E320 router. The following notes are referred to in Table 12:

1. For more information about system resource requirements for nodes, queues, and shadow nodes, see JunosE Quality of Service Configuration Guide, Chapter 15, QoS Profile Overview. QoS is supported on all E Series line modules except for the ES2 10G Uplink LM.
2. For all line modules the maximum number of IPv4 or IPv6 or VLAN policy attachments is determined by the maximum number of interfaces multiplied by the number of attachment resources that are currently used. Attachment resources are used only when you attach the policy.

The line modules support policy attachments based on the following considerations:

• IPv4—Up to 2 ingress policy attachments and 1 egress policy attachment
• IPv6—Up to 2 ingress policy attachments and 1 egress policy attachment
• IPv4 secure policy—The ES2 4G LM, the ES2 10G LM, and the ES2 10G ADV LM support up to 1 ingress policy attachment and 1 egress policy attachment
• IPv6 secure policy—The ES2 4G LM supports up to 1 ingress policy attachment and 1 egress policy attachment
• VLANs—Up to 1 ingress policy attachment and 1 egress policy attachment
3. Secure policies are not supported on the ES2 10G Uplink LM. IPv6 secure policies are not supported on the ES2 10G LM.
4. For each rule that is sent from the SRC server using COPS messages to the SRC client, which is a router running JunosE Software, an entry is created in the policy table of the SRC client. A portion of the memory on the SRC client is needed to hold these policy rule entries that are transmitted to the SRC client for enforcing the policy decisions that are sent from the SRC server. The maximum number of memory blocks that is allocated to the SRC client functioning on the router for the policy rules that are sent from the SRC server is 1,024,000.

Table 12: Policy and QoS Maximums 

Feature	E120	E320
QoS queues per line module (See Note 1 on page 85.)	128,000	128,000
QoS profiles configurable per chassis	1000	1000
QoS profile attachments per chassis	96,000	96,000
QoS profile attachments per line module
ES2 4G LM	16,000	16,000
ES2 10G LM	16,000	16,000
ES2 10G ADV LM	32,000	32,000
QoS scheduler nodes per line module	64,000	64,000
QoS shapers per line module	64,000	64,000
Classification rules per policy	512	512
Policy classification (CLACL) entries per line module
ES2 4G LM	256,000	256,000
ES2 10G LM	262,143	262,143
ES2 10G ADV LM	131, 071	131, 071
ES2 10G Uplink LM	131,071	131,071
Policy rules supported by the SRC client (See Note 4 on page 85.)	1,024,000	1,024,000
Policy egress interface attachments per line module (See Note 2 on page 85.)
ES2 4G LM combined IP and IPv6 interface attachments	16,383	16,383
ES2 4G LM combined ATM, GRE, L2TP (LAC only), MPLS, and VLAN interface attachments	16,383	16,383
ES2 10G LM combined IP and IPv6 interface attachments	16,383	16,383
ES2 10G LM VLAN interface attachments	16,383	16,383
ES2 10G ADV LM IP interface attachments	32,000	32,000
ES2 10G ADV LM VLAN interface attachments	32,000	32,000
ES2 10G Uplink LM combined IP and IPv6 interface attachments	16,383	16,383
ES2 10G Uplink LM VLAN interface attachments	8191	8191
Policy ingress interface attachments per line module (See Note 2 on page 85.)
ES2 4G LM combined IP and IPv6 interface attachments	32,767	32,767
ES2 4G LM combined ATM, GRE, L2TP (LAC only), MPLS, and VLAN interface attachments	16,383	16,383
ES2 10G LM IP interface attachments	16,383	16,383
ES2 10G LM combined IP and IPv6 interface attachments	16,383	16,383
ES2 10G LM VLAN interface attachments	16,383	16,383
ES2 10G ADV LM IP interface attachments	64,000	64,000
ES2 10G ADV LM VLAN interface attachments	32,000	32,000
ES2 10G Uplink LM IP interface attachments	16,383	16,383
ES2 10G Uplink LM combined IP and IPv6 interface attachments	16,383	16,383
ES2 10G Uplink LM VLAN interface attachments	8191	8191
Rate limiters (egress) per line module
ES2 4G LM	64,000	64,000
ES2 10G LM	64,000	64,000
ES2 10G ADV LM	64,000	64,000
ES2 10G Uplink LM	64,000	64,000
Rate limiters (ingress) per line module
ES2 4G LM	64,000	64,000
ES2 10G LM	64,000	64,000
ES2 10G ADV LM	64,000	64,000
ES2 10G Uplink LM	64,000	64,000
Policy statistics blocks (egress) per line module
ES2 4G LM	256,000	256,000
ES2 10G LM	256,000	256,000
ES2 10G ADV LM	512,000	512,000
ES2 10G Uplink LM	256,000	256,000
Policy statistics blocks (ingress) per line module
ES2 4G LM	256,000	256,000
ES2 10G LM	256,000	256,000
ES2 10G ADV LM	512,000	512,000
ES2 10G Uplink LM	256,000	256,000
Parent groups (egress) per line module
ES2 4G LM	49,151	49,151
ES2 10G LM (internal parent groups only)	8191	8191
ES2 10G ADV LM (internal parent groups only)	8191	8191
ES2 10G Uplink LM (internal parent groups only)	8191	8191
Parent groups (ingress) per line module
ES2 4G LM	49,151	49,151
ES2 10G LM (internal parent groups only)	8191	8191
ES2 10G ADV LM (internal parent groups only	8191	8191
ES2 10G Uplink LM (internal parent groups only)	8191	8191
Software lookup blocks per line module
ES2 4G LM	16,383	16,383
ES2 10G LM	16,383	16,383
ES2 10G ADV LM	32,000	32,000
ES2 10G Uplink LM	16,383	16,383
Secure policies (for packet mirroring)
Per chassis	2400	2400
Per line module (See Note 3 on page 85.)	1022	1022

Tunneling Maximums

Table 13 lists tunneling maximums for the E120 router and the E320 router. The following notes are referred to in Table 13:

1. The ES2-S1 Service IOA supports any combination of DVMRP, GRE, and L2TP tunnels up to a maximum of 8000 tunnels; however, no more than 4000 tunnels can be DVMRP or GRE tunnels in any combination.
2. For more information about supported L2TP sessions and tunnels, see JunosE Broadband Access Configuration Guide, Chapter 12, L2TP Overview.
   

   Table 13: Tunneling Maximums 

   Feature	E120	E320
   DVMRP (IP-in-IP) tunnels per chassis	4000	4000
   DVMRP (IP-in-IP) tunnels per line module with shared tunnel-server ports provisioned	4000	4000
   DVMRP (IP-in-IP) tunnels per ES2-S1 Service IOA (See Note 1 on page 89.)	4000	4000
   GRE tunnels per chassis	4000	4000
   GRE tunnels per line module with shared tunnel-server ports provisioned	4000	4000
   GRE tunnels per ES2-S1 Service IOA (See Note 1 on page 89.)	4000	4000
   L2TP sessions per chassis (See Note 2 on page 89.)	60,000	60,000
   L2TP sessions per line module with shared tunnel-server ports provisioned (See Note 2 on page 89.)	8000	8000
   L2TP sessions per ES2-S1 Service IOA (See Note 2 on page 89.)	16,000	16,000
   L2TP tunnels per chassis for SRP-100	16,000	16,000
   L2TP tunnels per chassis for SRP-320 with ES2 4G LM	32,000	32,000
   L2TP tunnels per line module with shared tunnel-server ports provisioned (See Note 2 on page 89.)	8000	8000
   L2TP tunnels per ES2-S1 Service IOA (See Note 1 and Note 2 on page 89.)	16,000	16,000

Subscriber Management Maximums

Table 14 lists subscriber management maximums for the E120 router and the E320 router. The following notes are referred to in Table 14:

1. DHCP relay proxy maintains a list of active DHCP clients up to a maximum of 100,000 clients per chassis for all virtual routers. DHCP relay does not maintain a list of DHCP clients.

DHCP relay proxy is notified of DHCP client deletions and subsequently deletes the client's host routes. In contrast, DHCP relay is not notified of DHCP client deletions, so the host routes for deleted clients remain in DHCP relay until you permanently delete them with the set dhcp relay discard-access-routes command. A maximum of 100,000 host routes for DHCP clients can be stored for all DHCP relay and DHCP relay proxy instances (that is, for all virtual routers).

2. On the E120 router, the SRP-120 and the SRP-320 support a maximum of 64,000 interfaces.

On the E320 router, the SRP-320 supports a maximum of 96,000 interfaces. The SRP-100 supports a maximum of 64,000 interfaces.

3. For DHCPv6 local server, up to 32,000 subscribers and clients are supported on PPP/ATM and PPPoE/ATM with dynamic interfaces. Interface flapping tests have been qualified for 8000 subscribers and interfaces.

Table 14: Subscriber Management Maximums 

Feature	E120	E320
DHCP external server clients (per chassis for all virtual routers; and per virtual router) (See Note 1 on page 91.)	100,000	100,000
DHCP local server (See Note 2 on page 91.)
Client bindings per chassis	96,000	96,000
Client interfaces per chassis	64,000	96,000
Local address pools per virtual router	4000	4000
IP addresses per local address pool	96,000	96,000
DHCPv6 local server
Clients (See Note 3 on page 91.)	32,000	32,000
DHCP relay and relay proxy client (See Notes 1 and 2 on page 91.)
DHCP client host routes for DHCP relay and DHCP relay proxy combined (per chassis for all virtual routers; and per virtual router)	100,000	100,000
DHCP relay proxy clients (per chassis for all virtual routers; and per virtual router)	100,000	100,000
Interfaces (per chassis for all virtual routers; and per virtual router)	64,000	96,000
RADIUS requests
Concurrent RADIUS authentication requests	32,000	32,000
Concurrent RADIUS accounting requests	32,000	96,000
RADIUS route-download server downloaded routes per chassis	64,000	96,000
Service Manager
Service definitions	2048	2048
Service sessions (active)	196,608	262,144
Active subscriber sessions	64,000	96,000
SRC Software and SDX Software
COPS client instances	200	200
SRC clients	200	200
SRC interfaces	48,000	96,000
Subscriber interfaces (See Note 2 on page 91.)
Dynamic subscriber interfaces per chassis	64,000	96,000
Dynamic subscriber interfaces per ES2 4G LM	16,000	16,000
Dynamic subscriber interfaces per ES2 10G LM	16,000	16,000
Dynamic subscriber interfaces per ES2 10G ADV LM	32,000	32,000
Static subscriber interfaces per chassis	64,000	96,000
Static subscriber interfaces per ES2 4G LM	16,000	16,000
Static subscriber interfaces per ES2 10G LM	16,000	16,000
Static subscriber interfaces per ES2 10G ADV LM	32,000	32,000

Informational Note: The system maximum and line card maximum values mentioned in the tables are for single dimension scaling only. We recommend that you test scenarios that require scaling of multiple features to the maximum values concurrently, before deploying. For example, on E320 routers, we support 96,000 PPP subscribers and 1, 500, 000 BGP 4 routes (NLRI). These values are independent of each other. We recommend that you test that the system can concurrently support 96,000 PPP subscribers and 1,500,000 BGP 4 routes (NLRI), before deploying.