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SOLUTION DESCRIPTION
EDA 1200 4.0
2
Introduction
Broadband access is known to be the fastest growing
technology in the telecommunications history.
With the EDA broadband access concept, Ericsson has
for several years demonstrated technology leadership
on the broadband market — First, by introducing the
world’s first Ethernet-based IP DSLAM, then by
constantly adding new and innovative features to secure
an optimal end-to-end solution.
Now Ericsson takes the next step by introducing a cost-
efficient, environmentally hardened VDSL2 solution.
Ideal for fiber-deep deployment close to the end-user
and perfectly suited for migration on existing
installations, as well as for new customers.
Since the early EDA 1200 days, Ericsson has been
shaping and promoting the IP and Ethernet-based
architecture. The Ethernet-based architecture (TR-101)
has been standardized by DSL Forum, and is seen as
the future architecture for telecom operators for years to
come.
Market shares have been constantly growing with EDA
1200 and leading European customers have selected
EDA 1200 as their preferred technology.
Main features
• Modular access node structure
− Unique scalability in steps of 12 lines reduces
sleeping investments to an absolute minimum
− Flexible combination of VDSL2 and
ADSL/ADSL2/ADSL2+ on remote sites
− Multimode IP DSLAM
− Support of all VDSL2 profiles in the same Hardware
(30a not supported)
• Flexible topology support
− Efficient management of remote sites
− Easy deployment close to the end-user
− Migration/upgrade path for VDSL2
− Fiber and copper access
• Environmentally hardened VDSL2 solution
− Extended temperature range -40°C to +75°C
without any additional protection.
− Withstand contaminant, solid objects and humidity
− Robust IP44 compatible design
− Ideal for remote application in outdoor cabinet
− Reduced cost of outdoor cabinets
• Intelligent access node
− Advanced service mapping and quality of service
features
− Offering bridged and routed service connectivity
• Cost effective solution
3
EDA 1200 overview
The EDA 1200 solution (previously called EDA Box)
deploys an access network with switched Ethernet and
a number of access drop technologies. The following
sections describe the components of the EDA 1200
solution with emphasis on the cornerstone of the
system - the IP DSLAM.
EDA components
The EDA solution comprises a number of components
that allows telecom operators to offer a full-featured
access solution:
• 12, 96, 144 and 288-line ADSL/ADSL2/ADSL2+ IP
DSLAMs (EDN312, EDN144 and EDN288)
• 24-port fiber access nodes (EFN324f, EFN324df and
EFN324c)
• 24-port Ethernet Controller Node (ECN330)
• 8-port and 24-port Ethernet switches with power over
Ethernet (ESN108 and ECN330 in switch mode)
• 12 port Gigabit Ethernet aggregation switch (ESN410)
• 2-port Ethernet Power Nodes (EPN102)
• Fast Ethernet to E1/T1 converter (EXN104)
EDA 1200 4.0 introduces a new generation specialized
for VDSL2 rollout. The new EDA 1200 is environmental
hardened and presents a new look and feel as well as
new broadband features:
• 12-line VDSL2 IP DSLAM (EDN612)
• 12 port Gigabit Ethernet aggregation switch (ESN212)
• 10-port Ethernet Power Node (EPN210)
• 24-port cat5 access node (EFN324c)
• 24-port fiber access node for multimode/dual fiber
(EFN324df)
IP DSLAM EDN312x (left) of the existing EDA 1200 product line
(the “blue box“) next to the new generation of EDA 1200,
the environmental hardened IP DSLAM EDN612 (right).
IP DSLAM with high functionality
The EDA 1200 IP DSLAM is available as a complete all-
in-one system with a unique scalability from 12 to 288
lines. The IP DSLAM is built on Ethernet technology
(TR-101). In essence, the IP DSLAM terminates the DSL
line, and aggregates the traffic into the access network
using standard Ethernet uplink connections.
The limited physical dimensions of the EDA 1200 IP
DSLAMs are secured without compromising
functionality. On the contrary, the IP DSLAM is fully
functional and designed using state-of-the-art
components, enabling easy SW updates for new
functionality support.
The IP DSLAM complies with all relevant DSL
standards, and interoperability is constantly verified
against the world’s leading CPE modem and chipset
vendors. All the DSL line coding is included in one
software package, making updates easy to
administrate. EDA 1200 supports VDSL2 as well as
asymmetric ADSL, ADSL2, and ADSL2+ including:
• VDSL2 Annex A for North America (POTS and ISDN)
• VDSL2 Annex B for Europe (POTS and ISDN)
• ADSL Annex A for POTS support
• ADSL Annex B for ISDN support
• ADSL Annex M for support of enhanced upstream
• ADSL Annex L for Reach Extended
EDA 1200 provides an option for enabling L2 power
down per line, which makes it possible for the operator
to save up to 25% on the power budget for a complete
IP DSLAM. The most significant benefit is obtained
when the lines are trained to maximum speed and the
CPE is at a distance of 10,000 feet from the IP DSLAM.
EDA 1200 allows PSD shaping to optimize the power
distributed from the IP DSLAM. This option is used
when an operator has both central-based equipment
and remote-based equipment in the network. The
solution offers six fixed options: two for standard, two
for central-based, and two for remote-based
equipment. Radio frequency interference notching
makes it possible to restrict parts of the frequency band
when training the DSLAM for the requested bandwidth.
The IP DSLAM is an environmentally friendly product,
designed in accordance with the ISO14001 standard
and produced with regards to a minimum use of lead
and halogens in the product. The IP DSLAM conforms
to the rigid Bellcore GR-63-core.
4
Solutions with IP DSLAM EDN612
The 12-line IP DSLAM EDN612 is the cornerstone of the
new EDA 1200 product line specialized for VDSL2
rollout with a fallback option for ADSL/ADSL2/ADSL2+.
EDN612 is supported by the 12-port Gigabit
aggregation switch ESN212; and together they form an
unmatched scalability and deployment opportunity. This
new generation of EDA 1200 is environmental hardened
and designed for cost-effective installation close to the
end-users in remote outside plants, where it demands
very little protection against weather and rough
environments.
12-line VDSL2 IP DSLAM EDN612
EDN612 has 12 fully flexible lines capable of running
VDSL2, ADSL, ADSL2 or ADSL2+. EDN612 is available
with POTS front-end (EDN612p) or ISDN front-end
(EDN612i). Underlying POTS or ISDN services are
available with external splitter, and EDN612 is also
prepared for built-in splitter. Two electrical Gigabit
uplink connections that can be used for redundancy
ensure non-contention operation. EDN612 has a
separate connector for -48 V powering (Power over
Ethernet is not included in this product line). EDN612 is
rail mounted like the existing EDA 1200 product line.
Environmental aspects
The new generation of EDA 1200 is designed for
operation under extreme conditions (ETSI EN 300 019-
1-3 Class 3.3 and GR-3108 CORE class 3) in order to
meet the requirement for VDSL2 equipment to be
pushed even closer to the end-user than ever before.
Hence, EDA 1200 can be placed in non-controlled road-
side cabinets and other locations with high humidity,
dust and dirt, as well as the operating temperature
range cover temperatures from -40°C to +75°C, thanks
to an optimized cooling channel that easily transports
dissipated heat out of the box. In fact, the only
protection needed is shelter against rain, direct sunlight,
and objects of 1 mm and greater.
POTS and ISDN services
For the support of underlying telephony services POTS
and ISDN a external splitter solution is available as well,
compliant to the EDA installation method.
Subrack solutions with EDN612
Both 19” and ETSI (21”) wide subracks are available for
up to 96 subscriber lines per subrack. Subracks include
built-in cable management and air guides and it is
possible to mix EDN612 IP DSLAMs, ESN212 switches,
and external splitters. An optional Power Distribution
Node EPN210 is also available, which also opens the
possibility of aggregating EDN312 IP DSLAMs for a
cost-efficient ADSL2+/VDSL2 upgrade of a remote site.
Below is shown a fully equipped 96-line ETSI subrack
solution without splitters equipped with eight EDN612 IP
DSLAMs, one ESN212 switch, and one EPN210 power
distribution node.
96-line ETSI subrack with EDN612, ESN212 and EPN210
Migration from existing installed base
EDA 1200 meets the operator’s need for smooth VDSL2
rollout on remote outside plants. The new EDA 1200
designed for VDSL2 rollout is not only a stand-alone
product line; it also goes nicely in line with the existing
installed base of EDA 1200. The illustration below
shows the existing EDA 1200 on the left next to the new
generation EDA with front cabling.
Coexistence between the existing and the new EDA 1200
showing EDN312x on the left and EDN612 on the right
5
Solutions with IP DSLAM EDN312
The 12-line IP DSLAM EDN312x is the cornerstone of
the existing EDA 1200 product line (the “blue Box”) and
it provides full support for ADSL, ADSL2 and ADSL2+.
The 12-line IP DSLAM EDN312x aggregates all the
incoming ADSL links onto one or two 100Base-T
Ethernet connections depending of the bandwidth
demand.
One innovative aspect of IP DSLAM EDN312x is the
power feeding over Ethernet (PoE). Another innovative
feature of the EDN312x is the built-in Central Office (CO)
base-band filter, available in both POTS (cost-effective
POTS, ETSI POTS, and ANSI POTS) and ISDN versions.
EDN312x is also available in a version with ISDN high
pass filter and no low pass filter. The integrated base-
band filter enables base-band telephony.
IP DSLAM EDN312x allows bonding of up to six lines in
order to provide high bandwidth to end-users, even to
end-users located at distances above 1.6 km. Line
bonding is a technique that allows the use of several
physical twisted copper pairs as if they form one single
line, provided that this is also supported in the CPE.
12-line IP DSLAM EDN312x with built-in base-band filter.
The front end of IP DSLAM EDN312x is well integrated
with standard building practice in the sense that it has
built-in Gas Discharge Tube (GDT) and Over Voltage
Protection (OVP), which means that the IP DSLAM can
operate as the primary protection.
Pre-configured solutions with EDN312
EDA 1200 is available as a pre-configured solution.
Ordered, delivered, installed, and commissioned as one
fully assembled unit, the system ensures easy and
trouble-free installation.
The scalable IP DSLAM concept is built from a
combination of the 12-line IP DSLAMs and the Ethernet
Controller Nodes — with the possibility of using the 8-
port switch ESN108 for aggregation in between.
The system can be configured in various ways:
• EDN144x:
144-line IP DSLAM built from one ECN330 and 12
EDN312x IP DSLAMs (link aggregated configuration
using both uplinks from the IP DSLAM)
• EDN288x:
288-line IP DSLAM built from one ECN330 and 24
EDN312x IP DSLAMs. For redundancy, the 288-line
IP DSLAM can be expanded with an additional
Ethernet Controller Node (ECN330), as shown below.
288-line IP DSLAM EDN288x - one fully assembled unit.
6
Solutions for fiber and Cat5
EFN324 is the cornerstone of Ericsson's fiber access
portfolio, targeting residential end-users, small
offices/home offices (SOHO), and small to medium
enterprises (SME).
EFN324 is a multi-functional, optical fiber access node
that supports triple play services, including multicast
video streaming with IGMP snooping.
EFN324 provides 24 x 100 Mbps Fast Ethernet downlink
ports and two combo GbE uplink ports. EFN324 is
prepared for 19” rack mounting.
EFN324 is available in three variants:
• Single mode single fiber (EFN324f)
• Multi mode dual fiber (EFN324df)
• Cat5 (EFN324c)
EFN324f with 24 optical ports
Combined with the Ethernet aggregation switch
ESN410, a large scale, cost-efficient fiber node is easily
built, supporting Single Mode/Single Fiber (SM/SF),
Multi Mode/Dual Fiber (MM/DF) and Cat5.
Controller Nodes and Ethernet
switches
The EDA solution offers a unique suite of 1st and 2nd
level Ethernet aggregation switches and Controller
Nodes. The Ethernet Controller Nodes are equipped
with EDA Management Proxy (EMP) for local
management of subtended nodes. The Ethernet
switches and Controller Nodes are all managed by the
Public Ethernet Manager (PEM), using the Ethernet
connection for both user traffic and management traffic.
The portfolio comprises the following products:
• ECN330; 24-port electrical Ethernet Controller Node
with two combo GbE uplinks and one electrical GbE
uplink. Includes standard switch functionality when
EMP is disabled.
• ESN212; 12 port Gigabit Ethernet switch with 8
electrical GbE ports and 4 SFP ports.
• ESN410; 12-port Gigabit Ethernet switch with 8 SFP
and 4 combo ports
• ESN108; 8-port electrical Ethernet switch with optical
uplink (FE/GbE)
ECN330 and ESN108 include integrated Power over
Ethernet (PoE) functionality for powering the connected
IP DSLAMs.
For installations, where the IP DSLAM is not connected
to a switch with built-in Power over Ethernet (PoE), a
separate Ethernet Power Node, (EPN210 or EPN102)
can be used, however, the VDSL2 IP DSLAM (EDN612)
may also be powered separately.
Ethernet Controller Node ECN330
The Ethernet Controller Node ECN330 is a combined
management and traffic aggregation nodes. On the
outside, the Ethernet Controller Node looks like an
ordinary Ethernet switch, however, as the name
indicates, it includes more functionality.
Ethernet Controller Node ECN330
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The most significant feature is the integrated EDA
Management Proxy (EMP) functionality. EMP enables
the Ethernet Controller Node to reduce management of
IP addresses to just one management IP address per
Ethernet Controller Node, independent of the number of
subtended IP DSLAMs.
Ethernet Controller Node ECN330 is a natural
aggregation point for the EDA 1200 series of IP
DSLAMs based on EDN312x, as it contains 24 100
Mbps Fast Ethernet downlink ports.
Combined with ESN410/ESN212 for traffic aggregation,
ECN330 may also be used for management of VDSL2
nodes or combined ADSL/VDSL nodes in fixed or
flexible topology scenario.
ECN330 is equipped with the built-in EDA Management
Proxy (EMP) that is capable of managing up to 250
embedded nodes or 2500 VDSL2/ADSL2+ lines.
ECN330 can also be used as a regular Ethernet switch,
as it is possible to disable the EDA Management Proxy
(EMP) by command either for all ports or on a per-port
basis.
The Ethernet Controller Node offers the following
functionality - all in one box:
• Aggregation switch
• 24 electrical Fast Ethernet ports
• Two combo uplink ports, either as
− Two electrical 10/100/1000 Mbps or as
− Two 100/1000 Mbps optical SFP
• One electrical 10/100/1000 Mbps uplink (ECN330)
• Built-in Power over Ethernet
• EDA Management Proxy (EMP) application designed
to aggregate management traffic from all EDA
elements attached
− The EMP allows daisy-chaining of up to 7 ECN330
switches for increased management capacity
− Management of up to 250 embedded nodes or
2500 VDSL2/ADSL2+ lines
− One IP address
• Downgrading to basic switch functionality by
disabling EMP
• L2MPLS (Martini draft) for tunneling (ECN330)
• Layer 3 routing features (ECN330)
Aggregation Ethernet switch ESN212
The 12-port Gigabit Ethernet aggregation switch
ESN212 is part of the new generation EDA 1200 series —
designed for installation in rough environments close to
the end-user.
Ethernet switch ESN212 is a 1st level aggregation switch
with eight electrical Gigabit Ethernet ports, four optical
Gigabit SFP ports and two separate connectors for
redundant -48V powering.
ESN212 is rail-mounted and hence ideal for placing in a
remote cabinet aggregating up to eight IP DSLAMs
(EDN612 as well as EDN312) on the electrical Gigabit
ports, using one or more of the optical ports for uplink
connection to the central office. ESN212 could,
however, also be part of a fiber ring topology, utilizing 2
or more of the 4 optical SFP ports.
ESN212 is equipped with a DIP-switch that allows the
telecom operator to assign a unique identifier to the
switch for operation in a flexible topology setup with
ECN330.
Aggregation Ethernet switch ESN108
Ethernet switch ESN108 is a 1st level aggregation
switch with eight electrical Fast Ethernet ports and one
optical uplink port. ESN108 will detect the uplink
capacity from the SFP module installed and configure
the uplink accordingly for 100 Mbps Fast Ethernet or 1
Gbps Ethernet.
8
ESN108 is especially designed for EDA 1200 series for
deployment in areas with low subscriber penetration.
The switch ESN108 has a built-in PoE for powering of
the IP DSLAM. In connection with the IP DSLAM
EDN312x, ESN108 makes it possible to build small
remote sites of up to 96 end-users with 1 Gbps uplink.
ESN108 can be installed directly on a LSA® PROFIL or
U-shaped back mount frame.
2nd level aggregation switch ESN410
Ethernet switch ESN410 is a 2nd level aggregation
switch with 12 optical SFP ports. Four of these ports are
combo ports enabling RJ45 interface. ESN410 is
designed for direct aggregation of Controller Nodes
(ECN330) and Ethernet switch ESN108 with Gbps
uplink, as well as ESN410 can be utilized to aggregate
EDN612 traffic. ESN410 supports link aggregation for
larger bandwidth.
Ethernet Switch ESN410
The Ethernet switch offers the following functionality:
• Aggregation switch
• Eight + four Ethernet ports
• Eight 1000Base-X optical SFP
• Four combo uplink ports, either as
− electrical 10/100/1000Base-TX or as
− 1000Base-X optical SFP
• 10/100/1000Base-TX ports that support auto-sensing,
auto-negotiation.
• Supports Jumbo frame up to 9 KB
• Provides wire speed L2/L3 switch
• Supports up to 16,000 MAC address entries
• Flow Control supported:
− Full duplex mode
− Back pressure flow control half duplex mode
• Store-and-forward forwarding scheme
• Head of Line (HoL) blocking prevention
• Broadcast storm protection
• VLANs support, GVRP, IEEE802.1Q, IEEE802.1v
• Supports up to 4k VLAN
• Supports IGMP snooping
• Provides 8-level priority in switching
• Provides Spanning Tree (IEEE 802.1D)
• Fast forwarding mode supported (802.1s, 802.1w)
• Provides Link Aggregation (802.3ad with LACP)
Management
Utilizing the advanced management features of the
Ethernet Controller Nodes (EMP), the EDA 1200 series
constitute a largely scalable IP DSLAM covering up to
2,500 lines within a single management point. This is a
truly unique feature that allows telecom operators to
deploy and manage the access aggregation network in
an efficient and powerful way.
Above the EMP functionality, PEM (Public Ethernet
Manager) can be used as element manager, covering
Fault, Configuration, Performance and Security
management for the EDA 1200 solution.
Furthermore, Service on Access (SOA) can be used for
telecom operators that require a complete telecom
management solution covering end-to-end FCAPS
(Fault, Configuration, Accounting, Performance and
Security).
Please refer to separate documentation for a description
of PEM and SOA features in relation to EDA 1200.
EDA Management Proxy (EMP)
EDA Management Proxy (EMP) is a series of functions
and work processes that efficiently reduce the costs
and time needed in relation to installation, operation,
and maintenance of the access network.
ECN330 has built-in management functionality in terms
of a mini Domain Server. This makes it possible to
install, test, and provision a node without any external
contact with the overall management system.
Once controlled by an overall management system, the
Ethernet Controller Node and all embedded EDA
equipment will appear as one node — one large logical
IP DSLAM.
9
In this way, there is only one management interface and
one static IP address. For provisioning, the EMP is
managed via standard MIBs, and for system
maintenance via EDA SNMP MIBs. All SW images and
configurations are stored in local non-volatile memory to
secure full operation, even if access to the management
system is unavailable.
EMP secures a fast and safe installation process and
low recovery time in case of a total power outage,
returning the network into operation within a few
seconds after the power has returned.
EDA Topologies
EDA 1200 support a number of topologies below the
Ethernet Controller Node ECN330.
ECN330 EMP supports the “EDA legacy topologies”
including ESN108-based scenarios, EXN104 and switch
extension, as well as the ESN212 and EDN612 are
supported for VDSL2 deployment.
In order to increase the uplink capacity for VDSL2, one
or more ESN410 may be used for traffic aggregation for
the VDSL2 nodes. Typically a VDSL2 node will be
remote a cabinet consisting of an ESN212 and
EDN612/EDN312 IP DSLAMs.
Flexible topology
Ethernet Controller Node ECN330 also supports flexible
topologies together with ESN212, which allows
unmanaged — or even 3rd party — switches between the
EMP and the ESN212 aggregation switch.
The flexible topology support is particularly powerful for
VDSL2 deployment in scenarios where telecom
operators already have access aggregation switches in
place, with non-Ericsson equipment.
L2CP BRAS controlled provisioning
Using the L2CP protocol makes it possible for an
operator to use a management system independent of
PEM. The nodes that can be accessed are the
Controller Nodes ECN330.
Disabling EMP on port basis
By disabling EMP on a specific port on ECN330, makes
it possible to add third party equipment such as alarm
boxes in the same Ethernet connection.
SNMPv2 and SNMPv3
All EDA elements support SNMPv2 for provisioning,
monitoring and traps sending. For obtaining security in
the network all management commands are
encapsulated in a management VLAN securing
unauthorized access to any element in the EDA
network.
SNMPv3 is implemented in ECN330 adding an
additional element of security to the VLAN security.
Adding SNMPv3 to the management an even more
secure connection can be established, e.g. if
management is done over a third party network.
Local Craft Tool
A Local Craft Tool (LCT) is partly built-in the ECN330
Controller Node, making it possible to use a standard
laptop as tool.
The LCT is used for:
• Installation of software images on ECN330
• Line Test; testing and line training on all ADSL lines
• Provisioning of end-users using scripts
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Traffic mapping
End-user traffic is mapped to service VLANs. These
VLANs may be end-user specific or common to multiple
end-users. Through such VLANs a single or multiple
application services, e.g. voice, video or data, may be
accessible.
The traffic mapping to service VLAN may be based on:
• PVC or PVC bundle
• VLAN
• Line
• Ethertype
On each end-user line, EDA 1200 allows for
configuration of up to eight individual PVC or VLAN
based traffic mapping definitions (maximum 72 PVC
based mapping definitions in total per EDN312).
Quality of Service
In order to provide the required Quality of Service (QoS)
for the various triple play service classes (voice, video
and data), all EDA nodes support prioritization of
Ethernet frames in accordance with the IEEE 802.1Q
specification.
The EDA 1200 IP DSLAMs also supports a number of
advanced QoS and scheduling features for fine-tuning
the network performance:
• Packet-based QoS
− Queuing and scheduling
− PTM principles
− PTM QoS mapping downstream traffic
• ATM-based QoS for ADSL2+/ADSL2/ADSL
− Separation of traffic classes into PVCs
− Traffic processing according to priority (packet
based queuing)
− EDN312 overload protection; ensuing high priority
traffic handling during high load situations
Packet based queuing and scheduling
IEEE 802.1 p-bit based traffic distribution is performed
towards a structure of queues (per end-user).
Scheduling from these queues can be performed as
strict priority, deficit round-robin or modified deficit
round-robin. Using these scheduling methods enables
optimization towards high priority traffic and/or fair
bandwidth division between traffic classes.
PTM for VDSL2 - Principles
With VDLS2 on the EDN612 Packet Transmission Mode
(PTM) is introduced instead of ATM. In short, PTM
allows direct transmission of Ethernet packets on the
DSL line, by segmenting the line capacity into two
latency paths — a fast path and an interleaved path. The
two paths are individually configured and will typically
be utilized for separation of different types of services.
In addition to a somewhat simplified operation
compared to ATM, PTM will also reduce transmission
overhead by up to10%.
PTM QoS mapping
Upstream PTM Quality of Service mapping can be
based on:
• P-bit
• DSCP
• VLAN
The service mapping function keeps the relationship
between service VLANs and end-user VLANs, replacing
the VLAN from the end-user with the corresponding
service VLAN in the upstream direction, and vice-versa
in the downstream direction.
The Queuing and scheduling function uses the VLAN
and Ethernet Class-of-Service (p-bit) setting to
determine the appropriate queue and latency path for
each specific packet. As each latency path (like PVCs in
the ATM-world) is a limited resource in terms of
bandwidth, the schedulers handle bandwidth utilization.
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ATM-based QoS
The ATM-based QoS takes advantage of the fine-
grained segmentation into ATM cells, further minimizing
latency and jitter. This ATM-based QoS can be
combined with packet-based QoS.
In the traditional setup, there is a fixed relation between
PVCs and VLANs for traffic separation. The VLANs are
differentiated by priority and the IP DSLAM is
configured to map the traffic in a specific VLAN to
specific PVC configured with the relevant service class.
Upstream traffic can be classified based on:
• End-user PVC
• DSCP
Downstream traffic is distributed to PVCs based on a
combination of service VLANs and p-bit.
EDA 1200 thereby supports multiple services within a
single service VLAN to be mapped into multiple PVCs
based upon Ethernet Class-of-Service (p-bit).
QoS within single PVC (EDN312)
The IP DSLAM also supports multiple traffic classes
(services) within the PVC, allowing the access provider
to support multiple services from a single gateway.
Quality of Service within a single PVC is a highly flexible
feature that can be supplemented with other PVCs for
traffic separation, e.g. between company VPN and a
private triple play access on the same DSL line.
Overload Protection (EDN312)
On the receiver side of the Ethernet and ADSL
interfaces, the IP DSLAM implements mechanism to
secure prioritized packet handling in situations where
the traffic load exceeds the packet processing
performance of the IP DSLAM. Ethernet Overload
Protection (EOP) and ADSL Overload Protection (AOP)
are common for all lines in the IP DSLAM, and secures
that high prioritized traffic is processed (e.g. voice and
video) before best-effort traffic such as Internet surf in a
packet overload situation.
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Multicasting
EDA supports the increasing demand for streaming and
high quality broadcast video services by offering
multicast for video streams both in the IP DSLAM (using
IGMP Snooping) and in the aggregation layer.
With Internet Group Management Protocol (IGMP)
multicast, parallel transmission of the same video
stream is avoided. Snooping the streaming requests
from one user and connecting them to an already active
stream towards another user saves Ethernet bandwidth.
Advanced IGMP White List functionality inside the IP
DSLAM allows the operator to specify content-
differentiated services to be filtered in the IP DSLAM.
The whitelist is end-user specific and is used to validate
end-user IGMP reports (join requests). It can be
updated with definitions of allowed multicast group
addresses and address ranges, and with information
about the VLAN, in which the multicast group is
available.
IGMPv3 (EDN612)
EDA 1200 support IGMPv3 signaling without source
specific routing.
Security
EDA bases security on four basic principles:
• Filtering of Ethernet frames in the IP DSLAM
• Forced Forwarding
• Virtual MAC address to prevent MAC spoofing
• Layer 2 separation of Ethernet services in virtual sub-
networks or tunnels, using Virtual LAN (VLAN)
Filtering
By use of specific filtering, the IP DSLAM is able to
control the traffic to and from the EDA end-user in order
to restrict the types of frames/packets forwarded by the
IP DSLAM. The filtering policy is based on a wide set of
rules controlled by the access provider that can be
updated on the fly if a security risk is discovered. The
rules can also be configured individually per PVC. The
filtering can be a mix of rules that cover broadcast,
Source MAC/IP, Destination MAC/IP, Ethernet frame
type, and IP port.
Forced Forwarding (RFC 4562)
Forced Forwarding is an EDA technique that prevents
direct connections between end-users. This function
separates the users on layer 2 and forces the end-user
to use a router for all upstream traffic. The Layer 2
separation is achieved by an ARP proxy function in the
IP DSLAM. Hence, End-user (1), who is trying to
communicate with End-user (2) within the same VLAN,
will issue an ARP request to get the destination MAC
address. However, the ARP proxy will respond to the
ARP request with the MAC address of the default
gateway instead of the MAC address of End-user (2). In
this way, the requesting End-user (1) will now send
traffic via the default gateway, assuming that it is in fact
End-user (2).
Virtual MAC address
To prevent MAC spoofing, and to provide access to
multiple end-users with identical MAC addresses, the
EDA solution offers the use of Virtual MAC address.
Using virtual MAC for an end-user ensures that MAC
addresses are unique within the EDA 1200 network,
independent of the MAC address used on the end-user
line. All traffic from the end-user line will have a specific
MAC address, based upon the topology of the EDA
1200 network.
1:1 MAC address translation
EDA 1200 supports 1:1 MAC address translation. This
feature translates each individual end-user MAC
address to a unique VMAC address used within the
network.
N:1 MAC address translation (EDN612)
EDA 1200 supports N:1 MAC address translation. This
feature translates multiple end-user MAC addresses to
be represented by a single MAC address within the
network. It can be used to save space in the MAC-
tables of the switches in the access aggregation
network.
VLANs
The Ethernet Access Domain traffic may be separated
by use of different VLANs for different traffic types
(VLAN per service). It is also possible to configure
VLANs per node or even VLAN per end-user for e.g.
business access. VLAN per end-user is commonly
referred to as the 1:1 VLAN model while VLAN per
service or per node is designated the N:1 VLAN model.
13
The following VLANs are depicted in the figure below,
as an example of using VLANs per service:
• Voice VLAN for voice ToIP service
• Video VLAN for video broadcast
• Data VLAN for Internet access service
• Management VLAN used for all O&M
Access methods
Access methods are used to define rules suitable for
specific end-user host configurations and behavior.
An access method provides the basic filter functions to
enforce policies related to establishing and maintaining
end-user sessions on a PVC or a VLAN. It is
consequently a basic part of defining a traffic mapping
definition. Traffic mapping definitions can be
established using one of the following access methods:
• DHCP
• PPPoE
• Static IP address
• Transparent LAN/VLAN
• IPoA and PPPoA (EDN312)
Transparent LAN/VLAN services
Transparent LAN services provide VLAN transparency
between home offices or connection of multiple offices.
EDA provides the VLAN transparency by encapsulating
en-user traffic using stacked VLAN. Up to five VLAN
tags are supported, including up to two tags added by
the IP DSLAM.
Business access
For business access, EDA offers ADSL, ADSL2, and
ADSL2+ Annex M, a symmetrical service that enables
the business solution to offer high capacity uplink and
downlink traffic suited for business applications.
Provisioning
Combined with PEM, EDA 1200 provides a number of
profiles and templates to create services in an easy
way. By pre-defining service and line configuration
profiles, end-user provisioning is easily created by
choosing the desired template.
Profiles can also be incorporated within the Access
Node. This feature can be used to automatically provide
the configuration defined in a profile to all end-user lines
(bulk pre-configuration) or to a group of lines.
In combination with PEM, EDA 1200 can make bulk
configuration by use of XML files with the desired
configurations. A GUI is provided to manage the
execution of the XML file and the result will be
presented in a log file.
Operational mode
EDA is highly versatile and can be deployed in any
network configuration. The EDA system offers Ethernet
connectivity to the end-user for any kind of service.
Basically, the EDA system acts as an extension cord
from the backbone network to the end-user, using DSL
as drop technology.
The IP DSLAM creates an end-to-end virtual LAN
architecture between the Ethernet access network and
the CPE Ethernet, encapsulating the Ethernet frame
over the ADSL connection between the IP DSLAM and
the CPE. This architecture is also known as Bridged
Ethernet. This applies to voice, video, and data services.
EDA supports DHCP Option 82 according to RFC 3046
on a PVC basis. For authentication by the service
provider, a configurable identifier is attached to the
DHCP request from the end-user.
14
DSL deployment and
maintenance
EDA supports VDSL2 ITU 993.2, ADSL2+ ITU G.992.5,
ADSL2 ITU G.992.3 and ADSL ITU G.992.1. VDSL2
opens for up to 100/50 Mbps downstream/upstream
bandwidth that enables the possibility for bandwidth
demanding services in the network. ADSL2+ also offers
high bandwidth of up to 24 Mbps downstream.
Single Ended Line Test (SELT)
SELT is an EDA function supported by the EDN312
series of IP DSLAMs, improving the TTC of broadband
access services for the operator. Using advanced
frequency and time domain analysis, this tool estimates
both the length and properties of the local loop and
possible ADSL service that can be carried through the
local loop. Results will be shown in PEM and all detailed
data can be exported for further processes.
Loop Diagnostics
Loop diagnostics is an ADSL2 feature (ITU G.992.3)
supported by EDN312 series of IP DSLAMs utilizing
both the IP DSLAM and the Customer Premises
Equipment (CPE) to measure the line quality.
Operation and Maintenance surveillance
Surveillance of end-to-end services is possible in two
steps. It is always possible to monitor the service paths
between the IP DSLAM and the CPE using standardized
ATM AAL0 F5 cells. For services using the PPPoE,
DHCP, or static IP access method it is possible to make
link verification between the IP DSLAM and the service.
Furthermore, the EDN312-based system provides other
useful information such as last estimated line length,
attainable bit rate on the ADSL physical link, and CPE
information such as chipset ID and dying gasp (CPE
switched off).
Network migration
Operators can save investments by building on existing
solutions — both in the access area as well as for the
network infrastructure.
New technologies like VDSL2 often emerge rather
slowly, and require only a relatively small penetration
ratio compared to e.g. ADSL/ADSL2/ADSL2+. Very
often it makes sense — financially as well as technically —
to migrate already installed equipment into new and
improved solutions. EDA offers a unique opportunity to
upgrade already installed remote sites with VDSL2.
On the topic of network infrastructure the EDA Ethernet
Aggregation and Transport products enable re-use of
existing legacy networks, while preserving the key
benefits of Ethernet aggregation and all-IP end-to-end
solutions.
Adding VDSL2
Migration of existing equipment is an extremely
important parameter for most telecom operators, in
order to protect investments and secure stability for the
end-users. This is, of course, also the case when
introducing VDSL2.
In essence, VDSL2 can be added to an existing
ECN330-based site. This is done by connecting an
ESN410/ESN212 to an uplink port of the ECN330 and
optionally adding additional fiber uplinks to the new
switch for traffic aggregation. The IP DSLAMs below the
ESN410/ESN212 will be handled by the EMP in the
ECN330 and hence “piggy-bag” on the existing
installation.
15
It is, of course, also possible to use flexible topologies
when adding VDSL2 to an already existing site with
ECN330. With EDA 1200 there is always an efficient
upgrade path at hand when introducing new
technologies and solutions.
Transport
Ethernet over SDH
Operators with an Ethernet-based core network might
still have an existing Sonet/SDH-based infrastructure,
mostly to small and rural sites where the penetration of
bandwidth demanding services is not yet high. These
operators might wish to re-use spare capacity in the
Sonet/SDH infrastructure to carry Ethernet frames. The
Fast Ethernet to E1/T1 converter EXN104 makes this
possible. Other products covering the range of different
Sonet/SDH E3 and STM-1 interfaces are also available
from Ericsson.
Fast Ethernet to E1/T1 converter
EDA provides a cost-effective solution for transporting
Ethernet traffic via vacant E1/T1 lines, which is useful on
small sites. The stand-alone design of the IP DSLAM
removes the need for a back plane and subrack and
sets new standards for scalability and costs. This is
made possible by using the small, managed Fast
Ethernet to 4xE1/T1 converter (EXN104). A small Power
over Ethernet Node (EPN102) is available for power
feeding of both the IP DSLAM (EDN312x) and the
EXN104. All products provide a small scale ADSL
solution for remote sites down to 12 lines.
The EXN104 is typically used in a back-to-back
configuration as shown in the illustration below. But
aggregation of a number of EXN104 E1/T1s into a single
STM-1 is also possible using the implemented Cisco
Framing variant.
EXN104 supports up to four 120 Ω E1/T1 ports each
with a speed of 2 Mbps. EXN104 conforms to ITU-T
G.703 on the LSA® interface and is fully manageable
via SNMP from PEM.
16
Mechanical enclosures
The EDA solution offers a number of mechanical
enclosures for easy and trouble-free installation. The
enclosures are available in European and US variants.
The US variants include Telco connectors and NEBS
approved protection for the EDN312x.
The following enclosures are available:
• Subrack for up to 36 ADSL subscribers (EU)
• Subrack for up to 96 ADSL subscribers (EU/US)
• Subrack for up to 96 VDSL2/ADSL subscribers (EU)
• Subrack for up to 144 ADSL subscribers (EU/US)
• Subrack for up to 288 ADSL subscribers (EU)
• Cabinet for up to 1152 ADSL subscribers (EU)
36-line subrack
The 36-line subrack is a 2 Height Units (HU), ETSI/19”
wide universal usage subrack for EDA units EDN312x,
ESN108, EPN102, and EXN104. Utilizing a large number
of different configurations, the micro subrack is
intended for installation in places of limited available
space.
36-line subrack
96-line subrack
The 96-line subrack is available in three variants:
• Subrack for VDSL2 based on EDN612, optionally
combined with ADSL/ADSL2/ADSL2+ based on
EDN312
• EU subrack for ADSL/ADSL2/ADSL2+ based on
EDN312
• US/NEBS subrack for ADSL/ADSL2/ADSL2+ based
on EDN31296-line ETSI subrack with EDN612,
ESN212 and EPN210
The 96-line VDSL2 subrack is available in both 19” and
21”/ETSI variants, with integrated cable holder and air-
guide. The subrack can be mounted into new or existing
cabinets with a free space of 250mm. The cabinet
houses one ESN212 switch and up to 96 EDN612
VDSL2-lines. By using the EPN210 power node, the
subrack may even be equipped with EDN312
ADSL/ADSL2/ADSL2+.
96-line subrack for VDSL2
The 96-line ADSL/ADSL2/ADSL2+ subracks based on
EDN312 for EU/US houses one 8-port switch (ESN108)
and up to eight 12-line IP DSLAMs (EDN312x). The
subrack conforms to ETSI /19” cabinet standards and
can be mounted into existing cabinets with a free space
of minimum 6 HU. The unique scalability means that this
subrack covers a range from a minimum of 12 to a
maximum of 96 subscribers, ensuring a cost-efficient
solution as starting point for small-sized sites.
96-line subrack for ADSL with backplane
144-line subrack
The 144-line subrack with backplane is available in EU
and US variants, housing up to 12 IP DSLAMs
(EDN312x). The height is 6.5 HU covering up to 144
lines. The subrack includes the 24-port Ethernet
Controller Node ECN330.
144-line subrack with backplane
17
288-line subrack
The 288-line subrack is equipped with 24 12-line IP
DSLAMs (EDN312x); the height is 11 HU covering up to
288 lines. The subrack includes the 24-port Ethernet
Controller Node ECN330.
288-line subrack
1152-line cabinet solution
This solution consists of an Ericsson BYB501 cabinet.
Housing up to four 288-line EDN288x IP DSLAMs, this
cabinet solution offers up to 1152 ADSL lines. Cabinet
dimensions are HxWxD: 2200 x 600 x 400 mm or
46 HU.
Cabinet with 1152 lines
If each EDN288x is expanded with one extra Ethernet
Controller Node ECN330 for redundancy or doublet
uplink capacity, the cabinet can house three END288x
IP DSLAMs, which adds up to 864 lines.
Outdoor enclosure
The EDA 1200 solution is perfectly suited for outdoor
installation, due to its environmentally hardened nature
and unique scalability.
Environmental characteristics
EDA 1200 based on EDN612/ESN212/EPN210 are
designed to meet ETSI EN 300 019-1-3 class 3.3 and as
GR3108 CORE class 3 with the extended temperature
range from -40 to +75 Celsius. Also the design is
resistant to humidity, dust and dirt enabling the product
line to be installed in an IP44 environment. These boxes
can easily be placed in non-controlled road-side
cabinets and other locations with high humidity, dust
and dirt. This significantly reduces the requirements on
the outdoor enclosure needed for EDA 1200 systems
based on EDN612, and facilitates cost-efficient rollout
of VDSL2 equipment close to the end-user.
The outdoor enclosure solution comes in two different
variants:
• Environmental controlled cabinets, which are suited
house 3rd party equipment that are not temperature
hardened, alongside with EDA 1200 equipment.
• Non-environmental controlled cabinets, which are
specifically designed to house temperature hardened
EDA 1200 equipment.
Environmental controlled cabinet
The environmental controlled cabinet offers a complete
solution for remote outdoor installation of EDA 1200:
• EDN312-based: Up to 96 ADSL/ADSL2/ADSL2+ lines
with embedded filters and 100/1000 1000BaseFX
optical uplink
• EDN612-based: Up to 48 lines VDSL2/ADSL2+ with
external filters and up to four 100/1000BaseFX optical
uplinks
The cabinet is designed for wall or pole mount with the
advantage of additional installation cost savings. Its
heat exchange unit and heat control allows third party
non-hardened equipment to be installed in the cabinet.
Subscriber and Local Exchange Connectivity MDF is
part of the solution. Optional Remote Powering solution
is available when including AC powered battery backup.
18
Outdoor cabinet with up to 96 subscribers
EDA RSC96m
The environmental controlled cabinet offers a complete
solution for remote outdoor installation of EDA 1200:
• 12 to 96 line VDSL2/ADSL2+ based on EDN612,
ESN212 and optional EPN210
The EDA RSC96m solution can use direct air cooling in
the cabinet instead of the more traditional heat
exchanger unit. This means no humming noise and
cost savings of up to 35% compared to the more
traditional cabinet solutions.
The cabinet is designed for curb side mount with the
advantage of additional installation cost savings.
Outdoor cabinet with up to 96 subscribers
EDA RSC288m
The environmental controlled cabinet offers a complete
solution for remote outdoor installation of EDA 1200:
• 12 to 288 line VDSL2/ADSL2+ based on EDN612,
ESN212 and optional EPN210
The EDA RSC96m solution can use direct air cooling in
the cabinet instead of the more traditional heat
exchanger unit. This means no humming noise and
cost savings of up to 35% compared to the more
traditional cabinet solutions.
The cabinet is designed for curb side mount with the
advantage of additional installation cost savings.
Outdoor cabinet with up to 288 subscribers
Non-environmental controlled cabinet
EDA RSC24c
The EDA RSC24c solution is specifically designed to
house temperature hardened EDA 1200 equipment. It
uses direct air cooling in the cabinet instead of more
traditional heat exchanger unit. This means lower
environmental load regarding noise emission and power
consumption.
The cabinet can be used in the following configurations:
• 12 to 24 line VDSL2/ADSL2+ based on EDN612,
ESN212 and optional EPN210
19
Outdoor cabinet with up to 24 subscriber
EDA RSC96c
The EDA RSC96c is specifically designed to house
temperature hardened EDA 1200 equipment. It uses
direct air cooling in the cabinet instead of more
traditional heat exchanger unit. This means lower
environmental load regarding noise emission and power
consumption.
The cabinet can be used in the following configurations:
• 12 to 96 line VDSL2/ADSL2+ based on EDN612,
ESN212 and optional EPN210
Outdoor cabinet with up to 96 subscribers
20
Technical specifications
SUPPORTED STANDARDS
xDSL standards:
• ITU-T G.992.1 Annex A
(ADSL over POTS)
• ITU-T G.992.1 Annex B
(ADSL over ISDN)
• ITU-T G.992.3 Annex A
(ADSL2 over POTS)
• ITU-T G.992.3 Annex B
(ADSL2 over ISDN)
• ITU-T G.992.3 Annex L
(ADSL2 Reach Extended)
• ITU-T G.992.3 Annex M
(ADSL2 Symmetrical ADSL)
• ITU-T G.992.5 Annex A
(ADSL2+ over POTS)
• ITU-T G.992.5 Annex B
(ADSL2+ over ISDN)
• ITU-T G.992.5 Annex M
(ADSL2+ Enhanced upstream)
• ITU-T G993.2 Annex A
(VDSL2 American Region)
• ITU-T G993.2 Annex B
(VDSL2 European Region)
• ITU-T G.994.1
(Handshake Procedures)
• ITU-T G.997.1
(Operation and Management)
• ETSI TS 101 388*
(European requirements)
• ETSI ETR 328 (ADSL requirements
and performance)
• TR-048
(Test specifications (DSL Forum))
• ANSI T1.413-1998
• ETSI TS 101-952-1-1 v.1.1.1
(2002-05) POTS
• ETSI TS 101-952-1-3 v.1.1.1
(2002-05) ISDN
• ILMI (DSL Forum TR-037 auto
configuration)
ATM Attributes:
• ATM Cell over ADSL AAL5
• RFC2516 — PPP over Ethernet
(PPPoE)
• RFC2364 — PPP over ATM (PPPoA)
• ATM Service Classes: UBR, CBR,
VBR-nrt and VBR-rt
• RFC2684 - Multi-protocol
Encapsulation over ATM
Adaptation Layer 5
• RFC2684 — Routed Encapsulation
General switch functionality:
• IEEE 802.1D - Bridged Ethernet
• IEEE 802.1Q - VLAN and Frame
prioritization (802.1p)
• IEEE 802.2 Ethernet V2
• IEEE 802.3 — 10/100 Mbps Ethernet
RJ45 connector
• RFC1531 - Dynamic Host
Configuration Protocol (DHCP)
MANAGEMENT SYSTEM:
• Ericsson’s Public Ethernet Manager
(PEM) is based on Hewlett Packard
OpenView Network Node Manager
for Intel® platform.
• Northbound Interfaces:
− CORBA
− SNMPv1/SNMPv2C
Supported standards:
• FTP, TFTP
• RFC2233 — The Interfaces Group
MIB using SMIv2
• RFC2662 — definitions of Managed
Objects for the ADSL Lines and
ADSL MIBs extension
• RFC1213 — Management
Information Base for Network
Management of TCP/IP-based
Internets: MIB-II
• ATIS T1.PP.427.01-2004 and
ITU-T G.998.1 ATM-Based Multi-
Pair Bonding
12-LINE IP DSLAM EDN612
• Mechanically compatible with
KRONE PROFIL
• External connector: RJ-45
1000BaseT Ethernet
• Power consumption (12 lines):
• Idle: 33 watt
• Trained lines:
− 39 watt @ 14.5 dBm
− 45 watt @ 20.5 dBm
• MTBF EDN612i/p: 31.6 years
• External dimensions:
HxWxD: 186 x 47 x 186 mm
12-LINE IP DSLAM EDN312X
• Mechanically compatible with
KRONE PROFIL
• External connector: RJ45
100BaseT Ethernet
• Built-in filters for versions:
− EDN312xp =Cost-effective POTS
− EDN312xe = ETSI POTS
− EDN312xa = ANSI POTS
− EDN312xi = ISDN
− EDN312x = ISDN high pass filter,
no low pass filter
• Power consumption (12 lines):
Cable length 1.3 m:
Idle/Typical/Max = 5.0/17.1/19.8 W
Cable length 100m:
Idle/Typical/Max = 5.1/18.4/23.0 W
• MTBF EDN312xp/xi/xe/xa/x:
46/46/43/44/46 years, 25°C
ambient
• External dimensions:
(HxWxD) 185 x 35 x 157 mm
• Weight EDN312xp/xi/xe/xa/x:
589/636/661/710/532 g
288-LINE IP DSLAM EDN288X
• Fully assembled unit housed in
11 HU chassis
• Dual 10/100/1000 electrical or
100/1000 Mbps optical SFP uplinks
and one 10/100/1000 Mbps
electrical uplink
• Power consumption (288 lines; one
ECN330):
Cable length 1.3 m:
Idle/Typical/Max = 170/472/545 W
Cable length 100m:
Idle/Typical/Max = 173/505/626 W
• Supports 19” and ETSI cabinets
• Weight: 25 kg
• External dimensions:
(HxWxD) 490 x 480 x 300 mm
21
IP DSLAM EDN288X WITH EXTRA
ECN330
• Additional ECN330 configured as
switch on top of EDN288x
• Fully assembled unit housed in
12 HU chassis
• 2 x 10/100/1000 electrical or
2 x 100/1000 Mbps optical SFP
uplinks and one additional electrical
10/100/1000 Mbps uplink for each
ECN330-switch
• Power consumption (288 lines; two
ECN330):
Cable length 1.3 m:
Idle/Typical/Max = 215/517/590 W
Cable length 100 m:
Idle/Typical/Max = 218/550/671 W
• Supports 19” and ETSI cabinets
• Weight: 30 kg
• External dimensions:
(HxWxD) 535 x 480 x 300 mm
CONTROLLER NODE ECN330
• 24 x 10/100 Mbps ports electrical
• PoE for up to 24 IP DSLAMs or
EXN104s
• Open slot for Fast or Gigabit SFP
fiber ports
• Input voltage: —48 V DC
• Power consumption (24 ports):
Cable length 1.3 m:
Idle/Typical/Max: 50/62/70 W
Cable length 100m:
Idle/Typical/Max: 50/64/74 W
• MTBF: Minimum 15 years at 25°C
ambient
• External dimensions:
(HxWxD) 43 x 440 x 250 mm
ETHERNET SWITCH ESN212
• Installed directly on KRONE
PROFIL
• 4 x 100/1000 Mbps optical uplink
ports (SFP Fiber ports)
• 8 x 100/1000 Mbps electrical ports
(RJ-45)
• Dual -48VDC power input
• IEEE 802.1w (RSTP) and
IEEE 802.1s (MSTP)
• IEEE 802.1ad provider bridges
• IEEE 802.3ad Link aggregation
• 4k VLAN
• 16 k MAC
• 255 multicast groups
• Power consumption: Max 34 W
• MTBF: 32.7 years
• External dimensions:
(HxWxD) 186 x 47 x 186 mm
ETHERNET SWITCH ESN108
• Installed directly on a KRONE
LSA® and PROFIL
• 8 x 10/100 Mbps ports electrical
• One 100 Mbps / 1 Gbps uplink port
(SFP Fiber Port)
• PoE for up to 8 IP DSLAMs or
EXN104s
• Power consumption (8 ports):
Idle, no IP DSLAMs attached: 18 W
Max incl. PoE to 8xEDN312=217 W
• Input voltage: —48 V DC
• MTBF: 56 years at 25°C ambient
• External dimensions:
(HxWxD) 186 x 42 x 133 mm
AGGREGATION SWITCH ESN410
• 12 x 1 Gbps SFP optical ports or
• 8 x 1 Gbps SFP and 4 x
10/100/1000 Mbps Base-TX
• Input voltage: —48 V DC
• Partly managed by the Public
Ethernet Manager (PEM)
• Provides 8-level priority in
switching
• Provides wire speed L2/L3 switch
• Supports up to 16K MAC address
• Supports up to 4k VLANs
• Provides IPv4 routing at wire speed
• Power consumption: Max. 34 W
• MTBF: 25 years at 25°C ambient
• External dimensions:
(HxWxD) 44 x 440 x 230 mm
POWER DISTRIBUTION EPN210
• Installed directly on KRONE
PROFIL
• Dual power inlet for -48VDC (-40.5
VDC to 60 VDC)
• 10 Power output terminals for
powering EDN612/ESN212 or PoE
for EDN312
• Output power: 500 W
• External dimensions:
(HxWxD) 186 x 47 x 186 mm
POWER DISTRIBUTION EPN102
• PoE for one EXN104 and one IP
DSLAM
• Mechanically compatible with
KRONE LSA® 10 pair connector
system
• Input voltage: two terminals for —
48 V (-40.5 V DC to 60 V DC)
• Output power: 21 W per port (0.7 A)
• External port connectors: 2 x RJ45
• External dimensions:
(HxWxD) 185 x 21 x 110 mm
• Supports one LAN data string
(signal path internally crossed) and
feeds both ports with PoE with an
intelligent on/off function to protect
non-PoE equipment.
FAST ETHERNET TO E1/T1
CONVERTER EXN104
• Mechanically compatible with
KRONE LSA® 10 pair connector
system
• 4 x G.703/G.704 120 Ω balanced
E1/T1 interfaces at the LSA®
connector
• Fast Ethernet 100 Mbps ports
electrical
• Power consumption Nominal 5.4 W
• External dimensions:
(HxWxD) 185 x 21 x 109 mm
CUSTOMER PREMISES
EQUIPMENT
The EDA system fully supports open
interfaces and complies with all
relevant ADSL standards. This
ensures that EDA is interoperable with
any standardized ADSL CPE modem,
Ericsson and non-Ericsson
ENVIRONMENTAL
• EN 300 386:2001 Class B
• Electro Magnetic Compatibility
(EMC) requirements
• ETS 300 019-2-1 class 1.2
• Storage conditions
• ETS 300 019-2-2 class 2.3
Transport conditions
• ETS 300 019 —2-3 class 3.2 Partly
Temperature controlled locations
• ETS 300 019 —2-3 class 3.3 Not
Temperature controlled locations
• ETS 300 753 class 3.2
• Acoustical Environment
• ITU-T K.20, ITU-T K.21
• Resistibility of telecommunication
equipment installed in a
telecommunications center or
premises to over-voltages and
over-currents-currents
22
Ericsson AB
www.ericsson.com
221 05-FAV 901 101/1 Uen C
©Ericsson AB, August 2007