Cisco Cisco ONS 15454 SONET Multiservice Provisioning Platform (MSPP) Notas de publicación
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Release Notes for Cisco ONS 15454 Release 4.0.1
OL-4470-01
New Features and Functionality
SR/STM64 IO 1310 cards in any high-speed slot, slot 5, 6, 12, or 13, on the ONS 15454 SDH. You can
provision this card as part of an BLSR, a path protection configuration, a linear configuration, or as a
regenerator for longer span reaches.
provision this card as part of an BLSR, a path protection configuration, a linear configuration, or as a
regenerator for longer span reaches.
The OC192 SR/STM64 IO 1310 port features a 1310-nm laser and contains a transmit and receive
connector (labeled) on the card faceplate. The card uses a dual SC connector for optical cable
termination. The card supports 1+1 unidirectional and bidirectional facility protection. It also supports
1:1 protection in four-fiber bidirectional line switched ring applications where both span switching and
ring switching might occur.
connector (labeled) on the card faceplate. The card uses a dual SC connector for optical cable
termination. The card supports 1+1 unidirectional and bidirectional facility protection. It also supports
1:1 protection in four-fiber bidirectional line switched ring applications where both span switching and
ring switching might occur.
The OC192 SR/STM64 IO 1310 card detects SF, LOS, or LOF conditions on the optical facility. Refer
to the “Cisco ONS 15454 Troubleshooting Guide” for a description of these conditions. The card also
counts section and line BIP errors from B1 and B2 byte registers in the section and line overhead.
to the “Cisco ONS 15454 Troubleshooting Guide” for a description of these conditions. The card also
counts section and line BIP errors from B1 and B2 byte registers in the section and line overhead.
For more specific details, consult the “Cisco ONS 15454 Reference Manual,” Release 4.0.
ML-series Cards
The ML-Series 10/100/Gigabit Ethernet cards provide high throughput, low latency packet transport of
Ethernet traffic (L2, IP and other L3 protocols), and a port based STS-48 backend for your SDH/SONET
network. With ML-Series cards, efficient Ethernet transport and TDM can coexist on same card, thus
enabling low cost interconnectivity for hubs and routers. The ML-Series works with Cisco IOS and takes
advantage of IOS’s IP rich features and reliability. The ML-Series functions as a Fast-Ethernet or
Gigabit-Ethernet extension, or, in an aggregation application, such as high-capacity customer LAN
traffic, Internet traffic, or VPN, with 1 Mbps and above bandwidth guaranteed traffic grooming. The
following summaries highlight ML-Series card features.
Ethernet traffic (L2, IP and other L3 protocols), and a port based STS-48 backend for your SDH/SONET
network. With ML-Series cards, efficient Ethernet transport and TDM can coexist on same card, thus
enabling low cost interconnectivity for hubs and routers. The ML-Series works with Cisco IOS and takes
advantage of IOS’s IP rich features and reliability. The ML-Series functions as a Fast-Ethernet or
Gigabit-Ethernet extension, or, in an aggregation application, such as high-capacity customer LAN
traffic, Internet traffic, or VPN, with 1 Mbps and above bandwidth guaranteed traffic grooming. The
following summaries highlight ML-Series card features.
For more specific details, consult the “Cisco ONS 15454 Reference Manual,” Release 4.0.
ML1000-2 Card
The ML1000-2 card provides two ports of IEEE-compliant, 1000-Mbps interfaces. Each interface
supports full-duplex operation for a maximum bandwidth of 2 Gbps per port and 4 Gbps per card. Each
port autoconfigures for full duplex and IEEE 802.3x flow control.
supports full-duplex operation for a maximum bandwidth of 2 Gbps per port and 4 Gbps per card. Each
port autoconfigures for full duplex and IEEE 802.3x flow control.
The ML1000-2 card works in any of the slots from 1 to 6 or 12 to 17 if you use the XC10G cross-connect
card.
card.
Two SFP modules are offered as separate orderable products for maximum customer flexibility: an IEEE
1000Base-SX compliant, 850-nm optical module and an IEEE 1000Base-LX-compliant, 1300-nm
optical module. The 850-nm SX optics are designed for multimode fiber and distances of up to 220
meters on 62.5 micron fiber and up to 550 meters on 50 micron fiber. The 1300-nm LX optics are
designed for single-mode fiber and distances of up to five kilometers. Other SFP modules for long-reach
1550-nm and twisted-pair copper will be offered for use with the E1000 card in a future release.
1000Base-SX compliant, 850-nm optical module and an IEEE 1000Base-LX-compliant, 1300-nm
optical module. The 850-nm SX optics are designed for multimode fiber and distances of up to 220
meters on 62.5 micron fiber and up to 550 meters on 50 micron fiber. The 1300-nm LX optics are
designed for single-mode fiber and distances of up to five kilometers. Other SFP modules for long-reach
1550-nm and twisted-pair copper will be offered for use with the E1000 card in a future release.
The ML1000-2 Gigabit Ethernet card provides high-throughput, low-latency packet switching of
Ethernet encapsulated traffic (IP and other Layer 3 protocols) across an SONET network while providing
a greater degree of reliability through SONET “self-healing” protection services. This enables network
operators to provide multiple 1000 Mbps access drops for high-capacity customer LAN interconnects,
Internet traffic, and cable modem traffic aggregation. Efficient transport and co-existence of traditional
TDM traffic with packet-switched data traffic is provided.
Ethernet encapsulated traffic (IP and other Layer 3 protocols) across an SONET network while providing
a greater degree of reliability through SONET “self-healing” protection services. This enables network
operators to provide multiple 1000 Mbps access drops for high-capacity customer LAN interconnects,
Internet traffic, and cable modem traffic aggregation. Efficient transport and co-existence of traditional
TDM traffic with packet-switched data traffic is provided.
The ML1000-2 card eliminates the need for external aggregation equipment such as Ethernet or ATM
switches at the customer site, remote headends, or distributed POPs.
switches at the customer site, remote headends, or distributed POPs.