Zte Gpon RFP Template - 20150320
Zte Gpon RFP Template - 20150320
Zte Gpon RFP Template - 20150320
Date
V1.0
2009/5/23
V2.00
2009/11/23
V3.00
2010/517
V3.10
Author
Reviewer
Wang
Xinsheng
Wang
Xinsheng
Yuan Ning,
Wang Xinsheng,
Zhang Hui
Dai Chi
Yuan Ning,
Wang Xinsheng,
Zhang Hui
Dai Chi
2011/2/23
Notes
V3.20
2012/8/22
Qin Yewen
Wang Xinsheng
V3.30
2012/12/3
Qin Yewen
Wang Xinsheng
V4.0
2013/4/27
Qin Yewen
Wang Xinsheng
V4.1
2014/6/23
Qin Yewen
Wang Xinsheng
V4.2
2014/10/21
Wang Xinsheng
Wang Xinsheng
Wang Xinsheng
Qin Yewen
Shi Ying
V4.3
2014/12/02
Qin Yewen
Qin Yewen
V5.0
2014/12/17
Meng Qing
Zhu Zhenghua
Bao Yintao
TABLE OF CONTENTS
1
1.1
1.2
1.3
2
2.1
2.1.1
2.1.2
2.1.3
2.1.4
2.1.5
2.1.6
2.1.7
2.2
2.2.1
2.2.2
2.2.3
2.2.4
2.2.5
3
3.1
3.1.1
3.1.2
3.1.3
3.1.4
3.1.5
3.1.6
3.1.7
3.2
3.2.1
3.2.2
4
4.1
4.2
4.3
4.4
4.4.1
4.4.2
4.4.3
4.5
4.6
4.7
5
5.1
5.1.1
5.2
5.2.1
5.2.2
5.3
5.4
5.4.1
5.4.2
5.4.3
5.5
5.5.1
5.5.2
5.5.3
5.6
5.6.1
5.6.2
Acronyms ........................................................................................................... 67
FIGURES
Figure 1-1 GPON Network Topology ..................................................................................... 6
Figure 2-1
Figure 2-2
TABLES
Table 3-1 FTTx MDU service cards requirement ................................................................. 45
Table 6-1
Acronyms ............................................................................................................. 67
General Introduction
1.1
Introduction
XXX have a key objective to enhance the level of telecommunications services and
solutions. The integrated triple-play solutions already in operation offer multimedia
services as well, although the significant growth of bandwidth demands is forecasted.
Optical systems among the new possibilities and the passive solutions, the PON networks,
in optical infrastructure will play an increasing role.
The main target of this technical specification is to functionally define the requirements of
the services for GPON network as FTTx configuration. The basic scenarios are taken into
consideration:
FTTP --- FTTH, FTTO, Fiber to subscribers premise
FTTN --- FTTB, FTTC, Fiber to about 1K-5K feet of subscribers premise; last mile is
copper-based (VDSL2)
1.2
GPON OLT
GPON ONT/ONU
Connectorized optical splitters for indoor and outdoor environment with the following
splitting ratio: 1:2; 1:4; 1:8; 1:16; 1:32; 1:64 and 1:128
Legend:
ONT: Optical Network Termination
ODN: Optical Distribution Network
OLT: Optical Line Termination
WDM: Wavelength Division Multiplexing (Optional)
NE: Network Element using different Wavelengths for OLT and ONU/ONT
AF: Adaptation Function
SNI : Service Node Interface
UNI : User Interface Network
Optical Line Termination (OLT): OLT provides an interface to PDN network side
(Optical Access Network) and sends the signal through one or more ODNs, which is
distributed to a certain number of ONUs
Optical Distribution Network (ODN): An Optical Distribution Network provides a
transmission mean between OLT and users in both transmission directions. It uses
passive optical components (optical fibers, cables, optical connectors, filters, splitters,
attenuators and splices).
Optical Network Unite (ONU): Optical Network Unit provides the user side interface of
the Optical Access Network and it is connected to ODN. All systems ONU receives the
same signal and each one of them extracts the corresponding information according to
an access protocol. In the reverse sense (downstream), data are transmitted according
to an OLT control mechanism using TDMA (Time Division Multiple Access) protocol that
allocates a transmission time to each ONU.
Optical Network Termination (ONT): Optical Network Terminal is an UN used for the
FTTH (Fiber To The Home) architecture and includes user's port functions
1.3
Referred Standards
1.
The GPON solutions offered must comply, but not limited to the following
International Standards
2.
3.
The proposed equipments should support IEEE 802.1D Spanning Tree Protocol
4.
5.
6.
The proposed equipments should support IEEE 802.1w Rapid Spanning Tree
Protocol of at least 8 ports, based on port-based, address-based, and round robin
7.
The proposed equipments should support IEEE 802.3u 100 Mbps Fast Ethernet
8.
The proposed equipments should support IEEE 802.3ad Ethernet Link Aggregation
9.
10. The proposed equipments should support IEEE 802.3z Gigabit Ethernet
11. The proposed equipments should support IEEE 802.3x Flow Control
12. The proposed equipments should support IETF RFC 2131: DHCP
13. The proposed equipments should support IETF RFC 2236: Internet Group
Management Protocol, Version 2
14. The proposed equipments should support IETF RFC 3376: Internet Group
Management Protocol, Version 3
15. The proposed equipments should support IETF RFC 3046: DHCP Relay Agent Info
Option (Option 82)
16. The proposed small-capacity OLT must have possessed of a MEF CE2.0
authentication
17. The proposed system should support SIP and H.248 for Voice providing
18. The Bidder must ensure that the compliance to any standards specified above is
kept up-to-date with the latest version available.
19. The version of hardware and software of the equipment should be provided
20. The proposed equipment must use a highly flexible, modular, scalable, and
non-blocking platform at all level/part of the design without any restriction.
21. The Bidder shall submit the detail chipset type, manufacturer, and version of the
proposed Equipment including the ONT.
22. The version of hardware and software of the equipment should be provided.
2.1
2.1.1
Transmission Requirements
1.
2.
3.
The logical reach of the offered GPON system shall be minimum 60km.
4.
The offered GPON system must support minimum 1:64 split ratio.
5.
The physical reach of the offered GPON system must be minimum 20km.
6.
The differential fiber distance of the offered GPON system must be minimum 20km.
7.
The offered GPON system must support downstream security: AES conformity to
clause 12.2 of ITU-T Rec. G.984.3 (02/2004). GPON system should be able to
switch the encryption on/off
8.
GPON system must be able to establish AES encryption per ONT/ONU basis
9.
The size of the OLT shelf should fit in a standard 19 inch or ETSI 21 rack
10
2.1.2
Physical layer
1.
The type of the offered GPON system must support 28dB and 32 dB link budgets
according to ITU-T Rec. G.984.2 Amendment 1. (02/2006).
2.
2.1.2.1
2.1.2.2
2.1.2.3
2.
3.
4.
5.
6.
7.
2.
3.
4.
5.
6.
Tolerance to the reflected optical power: Less than min. receiver sensitivity -10dB
11
2.
3.
4.
5.
6.
7.
8.
Launched optical power in case of without optical input signal: Less than min.
receiver sensitivity -10dB.
9.
10. Jitter transfer: Figure 4/G.984.2 see clause 8.2.8.9.1 of ITU-T Rec.G.984.2
(03/2003).
11. Jitter generation from 4.0 kHz to 10.0 kHz: 0.33UIpp.
2.1.2.4
12
2.
3.
4.
5.
Tolerance to the reflected optical power: Less than min. receiver sensitivity -10dB
2.1.3
Uplink interface
2.1.3.1
The offered GPON system must support 1000Base-LX (Long Wavelength Laser)
and 1000Base-SX (Short Wavelength Laser) optical uplink interfaces corresponding
to the provisions of Chapter 38 of the Standards IEEE 802.3 2005.
2.
3.
The uplink card support mixed plug, uplink card shall separate with control switch
card.
4.
The bidder shall give the number of pieces of interfaces implemented on one unit
(card).
5.
2.1.3.2
The optical modules insert on the uplink port should be an oblique type.
10 GbE
1.
The offered GPON system must support 10GBase-LR (1310nm, LAN PHY) optical
uplink interface. The parameters of the 10 GbE interfaces of the offered equipment
shall comply with the parameters corresponding to the provisions of Chapter 52 of
the Standards IEEE 802.3 2005.
2.
3.
The offered GPON system must have 10GBase-LR optical uplink interface.
4.
The offered GPON system must have 10GBase-ER optical uplink interface.
5.
GPON system uplink cards should support at least 8*10GE uplink interfaces in the
case of full user slots were configured.
2.1.3.3
E1
1.
13
2.
2.1.3.4
2.1.4
STM-1/STM/4
1.
The offered GPON system must support STM-1/STM-4 Standards ITU-T G.707
2.
2.
2.1.4.1
Types
There are mainly two types of optical fiber protection switchover: backbone optical fiber
protection switchover (TYPE B) and full optical fiber protection switchover (TYPE C), as
shown in Figure 2-1 and Figure 2-2 respectively:
14
2.1.4.2
1.
The offered GPON system must support LACP for uplink protection.
2.
The offered GPON system must support MSTP for uplink protection.
3.
The offered GPON system must support G.8032 for ring protection.
Criteria
In the GPON system, the optical fiber protection switchover must be implemented in one
of the following condition:
2.1.4.3
1.
2.
Protection Time
When the GPON system implements optical fiber protection switch over, the optical
channel protection time is recommended to be as follows:
1.
The TYPE B fiber protection: The service interruption is no longer than 100ms.
15
2.
The TYPE C Full fiber protection: The service interruption period is no longer than
50ms.
3.
The Uplink card protection: switchover time of 1+1 mode must no longer than
200ms.
2.1.5
GTC layer
1.
The offered GPON system must support GPON Encapsulation Method (GEM)
mapping conformity to clauses 8.1 8.3 of ITU-T Rec.G.984.3 (02/2004).
2.
The offered GPON system shall support optical leveling conformity clause 8.3.2. of
ITU-T Rec. G.984.2 (03/2003).
3.
The offered GPON system must support Dynamic Bandwidth Assignment (DBA)
payload processing conformity to clauses 7.7, 8.4 of ITU-T Rec.G.984.3 (02/2004).
4.
The offered GPON system shall support DBA Type: SR-DBA and NSR-DBA. The
minimum bandwidth allocation granularity shall be no more than 64kbit/s.
5.
The offered GPON system shall support FEC functionalities conformity to clause 13
of ITU-T Rec.G.984.3 (02/2004).
6.
The activation procedure in the ONT/ONU must comply with clause 10.2 of ITU-T
Rec.G.984.3 (02/2004).
2.1.6
The inviter of this RFQ intends to open the optical interface in order to achieve
interoperability between OLT and ONT of different vendors. To ensure the required
interoperability between multiple OLT and/or ONT the bidder must commit to open
the GPON interface (incl. OMCI) and to share this information with other selected
vendors.
16
2.
2.1.7
Ethernet OAM
1.
2.
3.
4.
5.
GPON system should support Continuity check (CCM) and Frame Delay
Measurement (DM) functions.
6.
GPON system should support Loopback (LB) and Link trace (LT) functions.
7.
8.
9.
GPON system should provide tc configuration of the following variables for Frame
Delay Measurement (DM):
17
2.2
2.2.1
2.
3.
Specify if the ONU support line card Flexible plug in and pull out, and specify the
number of slots that ONU have.
2.2.2
4.
5.
2.
3.
4.
FEC decoding
5.
DBA reporting in status indications in the PLOu, and by piggyback reports in the
DBRu
18
6.
7.
Transmission Wavelength
8.
2.2.3
2.
The ONT/ONU realizes the mapping of GEM frames into GTC payload (and
inversely extracts GEM frames from GTC payload) in conformance with ITU-T
G.984.3.
3.
The ONT/ONU realizes the mapping of Ethernet frames into GEM frames (and
inversely extracts Ethernet frames from GEM frames) in conformance with ITU-T
G.984.3.
4.
5.
The ONT/ONU supports the Non Status Reporting mode in conformance with ITU-T
G.984.3.
6.
The ONT/ONU is able to provide the information to the DBA function at the OLT in
order to optimize bandwidth allocation between ONUs when needed.
7.
The ONT/ONU supports the Status Reporting mode in conformance with ITU-T
G.984.3.
8.
9.
19
2.2.4
Upstream
1.
2.
Optical performances
The ONT/ONU supports Class B+ (Optical budget, source type, transmitter range,
mean launched power min, mean launched power max, extinction ratio) as
defined in ITU-T G.984.2 Amd1
20
2.2.5
Downstream
1.
2.
Optical performances:
The ONT/ONU supports Class B+ (Optical budget, receiver type, maximum
reflectance, BER, minimum sensitivity) as defined in ITU-T G.984.2 Amd1
3.1
3.1.1
3.1.1.1
GPON Layer
1.
GEM Port IDs must be assigned automatically (default) and manually by the OLT.
2.
A GEM Port must identify one or more traffic flows of a specific class of service
going to a specific U interface on a specific ONT/ONU.
3.
3.1.1.2
The GPON OLT must be able to prioritize traffic based on service VLAN in the
downstream direction.
2.
The GPON OLT must provide traffic shaping on per service basis in downstream
direction.
3.
The GPON OLT must be able to prioritize traffic based on service VLAN forwarding
to the uplink interface.
21
4.
The GPON OLT must support at least 4 queues per interface (including GPON
ports and Ethernet uplink interfaces), one per traffic class.
5.
The GPON OLT must support at least 4 traffic classes for Ethernet frames, and
shall support configurable mapping to these classes from the 8 possible values of
the Ethernet priority field.
6.
7.
8.
The GPON OLT should support combined queuing (strict for the highest queue and
weighted to the other queues).
9.
10. The bidder should provide information about traffic limit; minimum rate limit step,
available rate limit values, is limitation on L2 or L3 packets
11. The GPON OLT must support Hierarchical QoS.
12. The GPON OLT should support the controllable bandwidth accuracy not more
than1%.
3.1.2
3.1.2.1
Functionality
1.
The Ethernet interfaces must conform to IEEE 802.1q VLAN trunking standard.
2.
3.
4.
If the equipment has more than one Ethernet uplink interface, the interfaces must
support link aggregation according to IEEE 802.3ad standard.
5.
22
The Ethernet interface should support Ethernet frame MTU at least 9000 Bytes.
3.1.2.2
VLAN Considerations
1.
GPON OLT must support mapping of user VLANs of a given GPON port to different
service VLANs.
2.
Corresponding to the guidelines of DSL Forum TR-101, GPON OLT must support
simultaneously the following mappings of User VLANs and Service VLANs:
Mapping multiple User VLANs (of same or different GPON ports) to a single
Service VLAN,
Mapping multiple (m) User VLANs (of same or different GPON ports) to
multiple (n) Service VLANs, where m=n and n1.
(Remark: A given User VLAN shall not be bound to more than one Service VLAN.)
3.
The GPON OLT must be able to translate the VLAN tag received from customer to
the Service VLAN tag in the upstream direction.
4.
The GPON OLT must be able to translate the Service VLAN tag to User VLAN tag
in the downstream direction.
5.
The GPON OLT must support untagged frames received from the customer and
must be able to add the Service VLAN tag in the upstream direction.
6.
The GPON OLT must be able to detach the Service VLAN tag and forward
untagged frames in downstream direction in case of single tagged frame.
7.
The GPON OLT must be able to accept both tagged and untagged frames from the
customer and must attach the service VLAN tag to the frames.
8.
The GPON OLT should support selective QinQ (double stacking) encapsulation
Ethernet frames received from the customer should be dropped, forwarded without
change of the VLAN field, forwarded with QinQ encapsulation or forwarded with
translated VLAN field based on configuration.
9.
The GPON OLT must conform to N:1 VLAN forwarding defined in TR-101 of DSL
Forum.
23
3.1.2.3
Multicast Considerations
1.
2.
3.
4.
5.
6.
The GPON OLT must support dropping of all IGMP messages received on a
subscriber port.
7.
The GPON OLT must support an IGMP v2 (IGMP v3) transparent snooping function.
This feature shall be configurable on a per VLAN basis.
8.
The GPON OLT must support IGMP immediate leave (Fast Leave) as part of the
IGMP function.
9.
The GPON OLT must support IGMP join delay below 50ms.
10. The GPON OLT should be able to configure per GPON port the maximum number
of simultaneous multicast channels allowed.
11. GPON OLT must support the Globally Scoped Multicast Addresses (224.0.1.0
238.255.255.255).
12. GPON OLT must support the Limited Scoped Multicast Addresses (239.0.0.0/8).
13. The GPON OLT must support a mechanism to prevent a user port from becoming a
multicast router port by blocking IGMP query messages.
14. The GPON OLT must support mechanisms to stop user ports injecting unauthorized
multicast traffic into the aggregation network.
15. The GPON OLT must be able to rate limit the number of IGMP messages per user
port.
24
16. Multicast packets transported between RG (Routing Gateway) and GPON OLT is
using IPoE encapsulation.
17. The desired goal is to support multicast optimization by controlling the flooding of
Ethernet multicast frames making use of IGMP agents in intermediate (L2) devices
(e.g. GPON OLT, Ethernet aggregation).
18. N:1 VLANs forwarding mode should be used in order allow efficient forwarding of
multicast traffic. (It is to be noted that other types of traffic (data, voice, unicast video)
could be delivered via N:1 VLANs as well.)
19. Dedicated Multicast VLAN model should be supported. (This is a model where a
dedicated N:1 VLAN is used to send some multicast groups from a multicast router /
BNG to one or several access nodes (GPON OLT), over an aggregation network.
Other traffic is sent across different VLANs, where these VLANs could be 1:1 or
N:1.)
20. Integrated Multicast VLAN model should be supported. (This is a model where
multicast traffic is inserted into one of the N:1 VLANs that are terminated at a
subscriber GPON port, or alternatively dot1q trunked to the RG. This effectively
means multicast and unicast share a VLAN.)
21. GPON OLT should support 8K multicast groups, and support 1K multicast groups
per PON port.
3.1.2.4
Access Methods
1.
2.
3.
GPON OLT must support filtering options in order to prevent L2 traffic between
customers connected to the same GPON OLT considering PPPoE and DHCP
environment (Intra-GPON filtering).
4.
GPON OLT should support filtering options in order to prevent L2 traffic between
customers connected to different GPON OLTs considering PPPoE and DHCP
environment (Inter-GPON filtering) considering N:1 VLAN forwarding.
25
5.
6.
The OLT shall support ONU MAC address authentication based on PON port and
ONU logic identification authentication and their hybrid mode. The ONU logic
identification mode is the best choice. To authenticate the ONU legality, the OLT
shall refuse the illegal ONU access. It shall support to enable and disable the
function, and reduce the bad effect caused by ONUs continual authentication trial.
In consideration of construction convenience, the ONU should have a certain
chances of authentication trial.
3.1.2.5
GPON OLT must support configurable Ethertype filter for upstream direction.
2.
The bidder should provide the MAC address capacity in their documents.
3.
4.
GPON OLT should support configurable Source MAC (single address or a range)
filter in upstream direction.
5.
6.
GPON OLT must support configurable Multicast (enabling, disabling, and prefix
specific enabling) filter for upstream direction.
7.
GPON OLT must be able to store at least K*8 MAC addresses, where "K=Maximum
number of GPON-ports multiplied by the maximum splitting ration supported by
GPON ports".
8.
In order to prevent source MAC flooding attacks the GPON OLT must be able to
limit the number of source MAC addresses learned from a user VLAN
9.
26
10. GPON OLT must support Virtual MAC address and MAT (MAC Address
Translation).
11. Virtual MAC address and MAT must be configurable (enable/disable).
12. GPON OLT must support L2 marking (802.1p) of the traffic coming from the User
VLANs.
13. Binding management traffic to a dedicated VLAN must be provided.
3.1.3
IPv6
1.
The OLT shall support an option to migrate to IPv6 without any hardware upgrade
2.
OLT should support IPv6 SW upgrade, although IPv4 will be used in the initial
phase of the implementation
3.
3.1.4
The GPON OLT MUST support IPv6 and IPv4 dual stack function.
TDM Service
1.
When the GPON system bears E1 dedicated line service, it shall adopt MEF TDM
over Ethernet or IETF PWE3 mode in compliant with MEFs MEF8 or IETF
RFC3985 (2005), RFC4197 (2005) specifications. It configures its encapsulation
mode by the OLT local NM to be MEF8, RFC4553 (SATOP mode) or
Draft-left-pwe3-cesopn-02.txt (CESOPSN) mode).
2.
The GPON system born TDM service shall adopt self-adaptive clock recovery mode.
Thats to recover the clock through the clock stamp in the packet.
3.
4.
The OLT equipment to bear the TDM service shall support TDM (E1) service
transparent transmission, STM-1/STM-4 protection. The bidder shall elaborate the
STM-1/STM-4 protection mechanism and performance, and provide the application
instances in the existing network.
27
5.
3.1.5
3.1.6
1.
2.
1PPS + TOD
3.
IEEE 1588 V2
4.
Synchronization Ethernet
Security
1.
Please describe PON security features. Both logical and physical security should be
addressed.
2.
The proposed Equipment must be equipped with the security features to prevent
malicious DOS attack to the network and to other users.
3.
4.
5.
6.
7.
8.
The proposed Equipment should support the IP address filtering function. Details
explanation shall be given on how the user traffic is permitted and denied based on
source and/or destination IP addresses.
28
9.
The proposed Equipment must support the Ethernet MAC address filtering function.
10. The proposed Equipment must support the following, but not limited to:
IP anti-spoofing
DHCP snooping
11. Support MAC address registration capability to limit the number of MAC address per
port that can access that port
12. Prevention of IP/MAC Spoofing for DHCP user s Prevention of MAC spoofing for
PPPOE users
13. Limited MAC address based on the traffic stream
14. Static MAC address configuration based on the traffic stream
15. IP address binding based on the traffic stream\
16. MAC address filtering on the user side
17. Support unknown unicast packet suppression
18. Support broadcast packet suppression
19. DHCP Source Guard based on MAC and IP
20. Support downstream 128-bit advantage encryption standard (AEC) encryption
21. Support remote device management through Telnet
22. Support remote service configuration and device management through OMCI
23. Black List and White List for IP Address Segment is configurable
24. Ethernet uplink protection, Support LACP, MSTP and G.8032 for protection
25. Support STM-1, STM-4 uplink interface protection
29
3.1.6.1
3.1.6.2
IP Address
1.
2.
3.
4.
Anti DOS-Attacking
1.
2.
3.
4.
3.1.7
3.1.7.1
General Requirements
1.
30
Alarm management
Provisioning
Performance detecting
Troubleshooting
Inventory
Software upgrade
2.
The interface description of the equipment and the SNMP MIBs, NBI (TL1, XML),
API description of NB interface and other types of interfaces must be submitted.
3.
4.
5.
The NEs must have command line terminal access capability for initial
configurations and debug purposes.
6.
The NEs must have different user levels like read only, operator, system
administrator
7.
The NEs command line capability must cover the complete range of management
features and functions.
8.
The NEs must store all configuration parameters non-volatile, and must run in
service without any management system connection.
3.1.7.2
NE Interfaces
1.
2.
The proposed equipment shall have a command line IF via remote SSH access for
NE management.
3.
4.
The NE shall provide north-bound interface. Its protocol is in TL1, XML, FTP modes,
preferably TL1 mode.
5.
For all the offered NE an alarm, fault and performance interface must be proposed.
6.
7.
8.
31
3.1.7.3
The NEs of the offered system must be able to send alarm information to an existing
consolidated event management system via SNMP (GET-Request and Trap)
2.
The NEs of the offered system shall be able to send alarm information to an existing
consolidated event management system via syslog interface for real-time alarm
management.
3.
Supplier must hand over the list of the equipment events and alarms and their
severity.
4.
Please describe the FM (event and alarm management) features, functions and
operation of the proposed equipments.
5.
The NE must support ability of sending messages in form of SNMP Traps to at least
two specified destination. It's necessary to list all supported messages and MIBs.
3.1.7.4
The NEs of the offered system shall be able to be configured or managed via
SNMPv3 for any wanted changes eg. Configuration for operation of the network
elements, adaptation to planned operational modifications or user requirements.
2.
All the parameters and settings of the proposed NEs must be configurable remotely
(without any local assistance).
3.
It shall be possible to query the position of cards and interfaces via SNMP
(Entity-MIB, RFC4133).
4.
It shall be possible to query the type, own serial number and state of equipment
interfaces via SNMP (Entity-MIB, RFC4133).
5.
It shall be possible to query free resources (ports, cards, interfaces, positions) via
SNMP (Entity-MIB, RFC4133).
32
6.
7.
8.
The NE id (serial number) reported by the NE and printed on the surface of the NE
must be identical (both in semantics and syntactic).
9.
10. Supplier must hand over the list of the possible equipment configuration
parameters.
11. It must be possible to upload the configuration parameters from equipment.
12. It must be possible to download the configuration parameters to the equipment.
13. The configuration fails shall be detected and the changes shall be refused.
14. It shall be possible to restore the previous good configuration in all NE.
15. It shall be possible to reset the previous good configuration in all NE.
16. It must be possible to change the software releases in the equipment with remote
processes via SNMP or CLI.
17. The date of change shall be stored in the equipment.
18. It must be possible to read the software version(s) from equipment via SNMP or
CLI.
19. It must be possible to download the appropriate software/firmware to equipment.
20. The download fails shall be detected and the changes shall be refused. The NE
shall continue to work with the old software. The fail cause shall be reported to the
Management system.
33
21. It shall be possible to restore the previous good software release in all managed
equipment.
22. It shall be possible to reset the previous good software release in all managed
equipment.
3.1.7.5
2.
3.
The NE must provide traffic counter for both the incoming and outgoing traffic on all
the possible interfaces (on the OLT as well as on the ONT).
4.
Supplier must hand over the list of the retrievable performance data of the proposed
equipment.
3.1.7.6
2.
3.
The same LCT and unified interface shall be provided to connect to the different
type of equipment. Comment: 10/100BaseT Ethernet with R-J45 plug as unified
interface is proposed.
4.
The access priority to the equipment from the LCT shall be higher than from the
EMS.
5.
The LCT access shall operate independent from the EMS access.
6.
Each configuration change carried out through the LCT must automatically be
synchronized with the EMS.
7.
34
8.
The LCT must provide for configuring the default settings (default VLAN, IP address,
etc.).
3.2
3.2.1
3.2.1.1
3.2.1.2
3.2.1.3
Wi-Fi
RF overlay
Uplink interface
1.
2.
Access protocols
1.
GPON ONT must support bridging of 802.1q tagged Ethernet frames between its
LAN and WAN interfaces.
2.
GPON ONT must support bridging PPPoE over the encapsulated Ethernet as
defined in IETF RFC 2516 and support up 4 PPPoE sessions.
3.
35
3.2.1.4
4.
GPON ONT must support oversized Ethernet frames at least 1934 bytes.
5.
6.
7.
8.
The ONT must support mapping traffic into individual GEM Ports based on user port
/ VLAN priority bits / VLAN ID in the upstream direction.
2.
In the downstream direction, the ONT must support at least 4 queues per user
facing port, one per traffic class.
3.
In the upstream direction, the ONT must support at least 4 user queues, one per
traffic class
4.
The ONT must support scheduling of user queues according to strict priority among
at least 4 queues.
3.2.1.5
5.
The ONT must support at least 4 network facing T-CONTs, one per traffic class.
6.
Multicast support
1.
The ONT should support dropping of all IGMP messages received on a user port
and/or VLAN.
2.
3.
The ONT must support IGMP immediate leave as part of the IGMP transparent
snooping function.
4.
36
5.
The ONT MUST support IGMP explicit host tracking as part of the IGMP
transparent snooping function
3.2.1.6
2.
3.
For each Ethernet UNI, it is possible to configure manually duplex mode as half or
full.
4.
5.
For each Ethernet UNI, the ONT supports "Flow Control" (in conformance with IEEE
802.3 Annex 31B) with PAUSE functionality1
3.2.1.7
3.2.1.8
The ONT supports at least one, to two POTS interfaces with RJ11 connectors.
2.
Protocol: SIP/H.248
3.
The following codecs should be supported: G.711 A-law, -law, G.723, G.722.
4.
USB(UNI) Interface
1.
The ONT supports at least one USB host interface in conformance with USB2.0
standard.
2.
Support 3G dongle
3.
37
4.
3.2.1.9
2.
3.
Support 4 SSIDs
4.
Each SSID can be allocated for home network connection, WEB portal for public
hot-spot access exclusively, each scenario can bundle with one WAN.
5.
3.2.1.10
ii.
Pre-shared Key
Remote management
RF Overlay
(Depends on the ONU type features)
1.
2.
The enhancement band used for video shall be according with option 3 of G.984.5
Recommendation, from 1550nm to 1560nm
3.
38
4.
The ONT shall be able to convert optical signals with modulation format is Intensity
Modulation (IM) in FDM analogue AM-VSB and/or digital video signals.
3.2.1.11
3.2.1.12
3.2.1.13
5.
6.
7.
8.
Flatness : -1~1dB
Management requirements
1.
2.
The possibility for Local management for ONT (PON part), it must be disabled.
3.
4.
IPV6
1.
The ONT shall support an option to migrate to IPv6 without any hardware upgrade
2.
3.
Support DS-Lite
Security
1.
2.
3.
39
4.
3.2.1.14
5.
6.
Remotely software image download over OMCI, as well as activation and rebooting
Power supply
1.
3.2.1.15
Other requirements
1.
All physical ports (POTS and GE) shall have a link integrity indicator LED (one for
each port).
2.
The equipment shall have a reset button, in order to reset the equipment
configuration to the default factory settings. The reset button may be labeled as
"reset" so a help desk can more easily identify it to a user.
3.2.2
3.2.2.1
3.2.2.1.1
Classifies the upstream service traffic based on physical ports, source MAC
address, destination MAC address, VLAN ID, VLAN priority (IEEE 802.1p),
Ethernet type (such as IP, PPPoE, ARP/RARP), destination IP address,
source IP address, IP protocol type (TCP, UDP, ICMP, IGMP), IP DSCP,
TCP/UDP protocol port, and implements in-depth packets detection (the first
128 bytes).
40
It should support the mapping relations between 802.1p priority and services.
2.
3.
4.
5.
GPON ONU should support status reporting DBA, schedules the upstream service
traffic according to the DBA authority of the OLT to limit the upstream service traffic
rate.
6.
The Ethernet interface at the user side supports rate limit of the upstream and
downstream service port.
3.2.2.1.2
VLAN considerations
1.
IEEE 802.1ad VLAN Stacking, with the C-VLAN ID and S-VLAN ID ranging
from 1 to 4094
41
2.
3.
GPON ONU must be able to translate the VLAN tag received from customer to the
Service VLAN tag in the upstream direction.
4.
GPON ONU must be able to translate the Service VLAN tag to User VLAN tag in the
downstream direction.
5.
GPON ONU must support untagged frames received from the customer and must
be able to add the Service VLAN tag in the upstream direction.
6.
The GPON ONU must be able to detach the Service VLAN tag and forward
untagged frames in downstream direction in case of single tagged frame.
7.
The GPON ONU must be able to accept both tagged and untagged frames from the
customer and must attach the service VLAN tag to the frames.
3.2.2.1.3
42
Multicast support
1.
2.
3.
4.
5.
GPON ONU should be able to configure per user port the maximum number of
simultaneous multicast channels allowed.
6.
GPON ONU must be able to rate limit the number of group records per second per
user port.
7.
3.2.2.1.4
Security
1.
Specify if the ONU supports the AES security mechanism defined in G.984.3.
2.
3.
4.
5.
6.
Remotely software image download over OMCI, as well as activation and rebooting
3.2.2.2
3.2.2.2.1
The Tender must describe the general architecture and functional block diagram of
the proposed GPON ONU, which used as MDU (Multi-Dwelling Unit) equipment in
FTTB/C scenario.
2.
The Tender must indicate which buses are dedicated and which are shared by
different parts of the MDU as well as the bandwidth.
3.
Software roll-back to the old version shall be supported in case of update failure.
43
4.
Please indicate the number of MDU slots. Please breakdown into slots for
subscriber's cards, network cards, etc.
3.2.2.2.2
The proposed system should be 5U or less height and can be plug into 19 inch
standard rack.
2.
The proposed system should be in general consist of the following service interface
and all service line card can be mixed plugged in the same shelf:
3.
ADSL2+ interface
VDSL2 interface
SHDSL interface
SHDSL.bis interface
VoIP interface
FE and GE interface
4.
GPON uplink
5.
44
6.
7.
8.
9.
10. The Tender should state the capacity figures of the system, if the proposed
equipment include several types, For each type, please fill the table respectively :
cards Per
System
Quantity of ports
Per card
ADSL2+
VDSL2
POTS
FE
SHDSL
ISDN(BRI)
ISDN(PRI)
GE uplink
FE uplink
GPON uplink
11. The backplane capacity of MDU should be more than 20G
12. The switching capacity of MDU should be more than 10G
3.2.2.2.3
VoIP service
1.
2.
3.
45
3.2.2.2.4
4.
5.
2.
The connector must be RJ45 female and shall conform to IEC 60603-7 standard.
3.
The Ethernet interfaces must conform to IEEE 802.1q VLAN trunking standard.
4.
3.2.2.2.5
5.
6.
7.
The Ethernet interface must support oversized Ethernet frames at least 1526 byte.
Power supply
1
MDU should support power supply mode: AC (220V), DC (-48V), AC (220V) +DC
(-48V).
46
DC rated voltage -48 V with the range of -40 VDC to -57 VDC
AC rated voltage 110 VAC/220 VAC with the range of 88 VAC to 290 VAC
3.2.2.3
3.2.2.3.1
The Tender must describe the general architecture and functional block diagram of
the proposed GPON ONU, which used as CBU (Cellular Basic Unit) equipment in
FTTM scenario.
3.2.2.3.2
2.
Software roll-back to the old version shall be supported in case of update failure.
3.
The proposed system should be 2U height and can be plug into 19 inch standard
rack.
2.
3.2.2.3.3
SyncE Service
1.
2.
47
3.
3.2.2.3.4
3.2.2.3.5
GPON ONU should support two 1PPS+TOD ports and two 1PPS ports.
2.
3.
GPON ONU should fulfill the requirements of all kinds of mobile base stations.
2.
3.
GPON ONU should support the E1/T1 emulation service protocols as follows:
Specify the kind of connector and the impedance (75 Ohm or 120 Ohm) used for the
E1s
4.
5.
6.
7.
Specify the different types of loop back supported for maintenance and
troubleshooting
48
3.2.2.3.6
Power supply
1.
2.
DC rated voltage -48 V with the range of -40 VDC to -57 VDC
AC rated voltage 110 VAC/220 VAC with the range of 85 VAC to 286 VAC
CBU should support LiFePO4 battery for power backup when AC fails.
3.2.2.4
3.2.2.4.1
The Tender must describe the general architecture and functional block diagram of
the proposed GPON ONU, which used as MDU (Multi-Dwelling Unit) equipment in
FTTW scenario.
2.
3.2.2.4.2
Software roll-back to the old version shall be supported in case of update failure.
The proposed system should be 1U height and can be plug into 19 inch standard
rack.
2.
3.2.2.4.3
49
2.
GPON ONU in FTTW should support PoE management function, all the functions
listed below can be queried through CLI/TELNET/SNMP. POE management
function includes the following
Whether to disconnect power supply of the port on controlling the soft resetting
of the device
Remote PD resetting
over-voltage
50
Collecting the total current, voltage and power of the all PoE/PoE+ ports of the
overall device
3.
3.2.2.4.4
2.
The connector must be RJ45 female and shall conform to IEC 60603-7 standard.
3.
The Ethernet interfaces must conform to IEEE 802.1q VLAN trunking standard.
4.
3.2.2.4.5
5.
6.
7.
The Ethernet interface must support oversized Ethernet frames at least 1526 byte.
Power supply
1.
2.
DC rated voltage -48 V with the range of -40 VDC to -57 VDC
AC rated voltage 110 VAC/220 VAC with the range of 85 VAC to 286 VAC
MDU should support LiFePO4 battery for power backup when AC fails.
51
3.2.2.5
3.2.2.5.1
The Tenderer must describe the general architecture and functional block diagram
of the proposed GPON ONU, which used as MDU (Multi-Dwelling Unit) equipment
in FTTO scenario.
2.
Software roll-back to the old version shall be supported in case of update failure.
3.
Please indicate the number of MDU slots. Please breakdown into slots for
subscriber's cards, network cards, etc.
3.2.2.5.2
The proposed system should be 1U height and can be plug into 19 inch standard
rack.
2.
3.2.2.5.3
E1 interfaces
10/100Base-T interfaces.
2.
52
GPON ONU should support the E1/T1 emulation service protocols as follows:
3.
Specify the kind of connector and the impedance (75 Ohm or 120 Ohm) used for the
E1s
3.2.2.5.4
4.
5.
Power supply
1.
2.
DC rated voltage -48 V with the range of -40 VDC to -57 VDC
AC rated voltage 110 VAC/220 VAC with the range of 85 VAC to 286 VAC
MDU should support LiFePO4 battery for power backup when AC fails.
EMS Requirements
4.1
4.2
2.
The Supplier must support a 1:1 EMS redundancy architecture in which the Primary
(Active) and Secondary (Standby) EMS are geographically distributed.
3.
With 1:1 EMS redundancy architecture, please explain the method through which
the EMS Primary and EMS Secondary database synchronization will be maintained.
53
4.
With 1:1 EMS redundancy architecture, please explain the method by which the
switchover occurs from the EMS Primary to the EMS Secondary.
5.
6.
The proposed EMS must have different user levels like read only, operator, and
system administrator - with different access rights.
7.
8.
9.
10. A single instance of the EMS must support at least 50 users/ session
simultaneously.
11. The data communication solution between the EMS and the NE must be IP.
12. Management System shall have open API(s) that supports:
Fault Management,
Performance Management,
Configuration Management,
Inventory Management,
Security Management
54
17. EMS should support IPv6 SW upgrade, although IPv4 will be used in the initial
phase of the implementation
4.3
The proposed EMS must provide for fault and alarm management.
2.
Please describe the FM (event and alarm management) features, functions and
operation of the proposed equipments.
3.
Each alarm with its accompanied attributes, forming an alarm record, shall be
logged automatically. Alarm records shall be kept in the log for some time (e.g. 30
days) and alarm retrieval shall be supported. The same presentation, filter and
sorting functions shall be available for retrieved alarm records as they are for actual
alarms.
4.
All other events such as Alarm Acknowledgement, Alarm Severity setting, and
Alarm Collection allow/inhibit or Threshold settings shall be also logged.
5.
The report generation tool shall be available for Event Log records using filter
capabilities. Event Logging presentation shall allow the user to manage and analyze
the Event Log records.
6.
The event collection processes shall run continuously according to user defined
characteristic, even if all users are logged out.
7.
It shall be possible to archive any log file both manually and automatically.
8.
9.
55
4.4
4.4.1
It must be possible to query the position of cards and interfaces via the SNMP
Interface.
2.
It must be possible to query the type, own serial number and state of equipment and
the type and state of the interfaces.
3.
4.
5.
The NE id (serial number) reported by the NE and printed on the surface of the NE
must be identical (both in semantics and syntactic).
4.4.2
2.
3.
4.
The download fails shall be detected and the changes shall be refused. The NE
shall continue to work with the old software. The fail cause shall be reported to the
Management system.
56
5.
6.
4.4.3
2.
The date of change shall be stored and sent as a trap to the Management system.
3.
It must be possible to read the software version(s) from equipment via SNMP.
4.
5.
The download fails shall be detected and the changes shall be refused. The NE
shall continue to work with the old software. The fail cause shall be reported to the
Management system.
6.
It must be possible to restore the previous good software release in all managed
equipment.
7.
It must be possible to reset and the previous good software release in all managed
equipment.
4.5
2.
The EMS must provide traffic counter for both the incoming and outgoing traffic on
all possible interfaces (on the OLT as well as on the ONT). These counters must be
available in the NE.
3.
4.
Supplier must hand over the list of the supported performance information,
parameters of the proposed EMS and NE. Information shall be easy readable,
printable and exportable to other systems.
57
4.6
EMS Testing
1.
The EMS shall provide functions for performing equipment level testing.
2.
The EMS shall perform test functions for the optical and DSL performance of the
GPON network.
3.
The EMS shall provide functions for activating and deactivating temporary
loop-back connections.
4.7
2.
3.
Detect and locate any fault along the fiber optic cable (fault management)
4.
5.
6.
7.
System interoperability:
58
8.
Alarm management
9.
Multi-user capability
5.1
Environmental Requirements
5.1.1
5.1.1.1
Operating
1.
OLT:
The equipment are supposed to be placed at normal living or working areas shall
comply with the Standard ETSI EN 300 019-1-3 Class 3.1. (Temperature-controlled
locations) which is a combination of classes 3K3/3Z2/3Z4/3B1/3C2(3C1)/3S2/3M1
of the Standard EN 60721-3-3.
Specified temperature limits: +5....+40 C
Relative humidity:
2.
5....85 %
The proposed connectorized optical splitters (splitting ratio: 1:2; 1:4; 1:8; 1:16; 1:32
and 1:64) must have the environment conditions:
Operating Temperature (C) = -40 to +85 C
Operating humidity 95% and frozen-free
Air pressure = 70 KPa to 106 KPa
3.
We kindly ask you to specify for each proposed connectorized optical splitters the
following data:
Operating Temperature C"
Stationary operating temperature limits
4.
59
6.
LED status indication is supported for power, PON link status and UNI status.
7.
The indoor ONU is mounted either inside building or placed (stand alone) on a desk.
8.
The ONU can be equipped with maintenance-free backup battery that will operate
the system in case of AC failure as an option.
5.1.1.2
The bidder must make a declaration that the offered equipments not contain
components, materials and fittings that cause negative environmental impact during
transportation, storage installation or operation.
2.
3.
The bidder shall give a list for wrapping materials. Only recycling materials shall be
used for wrapping.
4.
60
5.2
Power Supply
5.2.1
OLT Devices
1.
The power supply interface of the equipment supplied with 48 V nominal DC must
satisfy the requirements stipulated in the Standard ETSI EN 300 132-2. (The
positive side should be grounded.)
2.
The bidder shall attach the test report of the power supply interface according to the
ETSI EN 300-132-2 to prove that all the equipment meet the above requirements.
3.
4.
The bidder should declare whether the equipment complies the European Code of
Conduct on Energy Consumption of Broadband Equipment. The energy
consumption is measured and compared according to ETSI TS 102 533 (2008-05).
5.
Supplier must give the power consumption of the equipment relevant to all modes of
operation.
6.
7.
The equipment should be protected against inversion of the polarity of the power
supply. Similarly, the power connector of the equipment shall be construed in a way
that it is provided against inversion of the polarity.
8.
The equipment must have remote management (remote checking feature) which
will inform the operator about discrepancies at the internal power supply.
9.
The power supply unit of the equipment (including the remote feeding circuits) shall
have a protection against overload and thermal runaway of the lead acid battery.
61
10. The normal service voltage must be within the range: -48 V 20%. The equipment
must operate at a voltage within this range.
11. The bidder shall specify the maximum power consumption for the OLT
12. The bidder shall describe the maximum overall power consumption of the OLT
equipment in full configuration with dual main control cards + dual power supply +
fan + dual 4GE uplink + GPON card.
13. GPON OLT should support 1+1 power supply redundancy protection.
5.2.2
2.
3.
Specify if the ONT/ONU Support POE (Power over Ethernet) and what is the
capability?
4.
The power supply interface of the equipment supplied with 230 V nominal AC must
satisfy the requirements stipulated in the Standard ETSI ETS 300 132-1 or ETSI
EN 300 132-3.
5.
Power supply: nominal voltage 90~230 V AC, 50Hz and Continental European plug.
6.
The equipments shall be tolerant of power fluctuations 230 VAC +15%, -25% @ 50
Hz 0.1%, continuing to operate normally and maintaining its configuration after
these events.
5.3
7.
Specify if the ONU support power saving mode for idle interface, and how?
8.
EMC Requirements
1.
In case of the RF emission the equipment must satisfy the class "B" limit of the EN
55022.
62
2.
The bidder must attach the Statement of Compliance (according to the Directive
2004/108/EC) to the Bid.
3.
4.
The bidder must attach the EMC Test Report to prove that all the equipment meet
the above requirements, or shall hand the EMC Test Report over to the Technical
Conformance Tests.
5.4
Safety Requirements
5.4.1
The equipments, its sub-systems and accessories must comply with the general
life- and material safety requirements.
2.
The bidder must guarantee that precautions must be taken in order to prevent any
injuries or damages due to the following hazards according to standard EN 60950-1,
2.0 Ed.:
3.
Electric shock,
Energy hazards,
Fire,
Radiation hazards,
Chemical hazards.
Only equipment must be allowed for installation that comply with the relevant
requirements in safety Standards (compliance evaluation procedure: according to
Directive 2006/95/EC and Directive 1999/5/EC of the European Parliament and of
the Council of 9 March 1999 on radio equipment and telecommunications terminal
equipment and the mutual recognition of their conformity ). The safety test reports of
63
the exchange and subscriber side units (the power supply of the subscribers unit if
exits too) according to EN 60950 must be attached to the bid.
4.
Markings and/or identity labels shall be placed on the equipments and on their
subsystems. The labels have to be placed on a visible place and should contain
durably the following information:
Classes of equipment - protection against electric shock (at class II. equipment
the symbol, too),
5.
CE marking.
All the delivered materials and equipments shall be free of defects (such as sharp
edges, burrs etc) that could represent a safety hazard to personnel involved in its
assembly, installation, use or maintenance.
5.4.2
With respect to electrical safety, the equipments and its power supply (if exists)
must comply with specifications in Standard EN 60950-1.
2.
The system of protection against electric shock, requirements for earthing and
equipotential bonding shall be established according to EN 60950-1, 2.0 Ed., and
ETSI EN 300 253 series of standards.
3.
5.4.3
2.
According to Standards ISO 3864-1 and ISO 3864-2 should be used on equipment
parts and housings where laser beam exist.
64
5.5
5.5.1
Maintainability
1.
GPON OLT and ONT equipment shall operate 24 hours a day, and every day of the
year. GPON OLT equipment shall be designed to meet an operational lifetime over
10 years with normal parts replacement.
2.
The bidder is obliged to ensure spare parts for offered platform for at least 10 year
period
5.5.2
Availability
Availability of the GPON OLT and ONU equipment shall be annually 99.99% for all nodes
5.5.3
Reliability
1.
MTBF of the GPON equipment used in the system should be more than 28 years.
2.
3.
4.
The
bidder
must
show
evidence
to
demonstrate
that
the
predicted
The bidder must state the maximum environmental operating temperature of the
fully equipped OLT in order to provide an availability/reliability of better than
99.999%.
5.6
Installation Conditions
5.6.1
General requirement
1.
Installation, operation and maintenance shall not require the use of special,
non-standard tools.
65
2.
All necessary materials for the installation shall be provided within the ONT, ONU,
OLT Kits
3.
4.
Installation materials shall be quoted for each OLT based on the following
assumptions
All patch-cord lengths for OLT shall be of 20m;
5.
6.
The proposed connectorized optical splitters (splitting ratio: 1:2; 1:4; 1:8; 1:16; 1:32
and 1:64) for indoor locations shall be 19" rack-able.
7.
The connectorized optical splitters installation must assure the eyes protection and
easy cabling.
8.
9.
The outer cover of the offered unit(s) shall be resisting to mechanical damaging
impacts that may occur during implementation/installation and operation.
10. The outer cover of the offered units should meet the requirements of Flammability
Class V-1 according to Standard EN 60950-1, 2.0 Ed..
11. The structural design (construction) of the offered equipment and the materials
chosen shall not cause injury to persons, or damage, or deterioration to objects, if
properly used. The technical characteristics of the basic components used shall
66
5.6.2
Cables
1.
The proposal shall include all the required tie cables from VDSL2 interfaces to the
MDF.
2.
The bidder shall offer quotation for the following tie cables lengths:
5m
10m
20m
Acronyms
Table 6-1 Acronyms
Acronym
Expansions
CP
Communications Provider
DoS
EMS
FSAN
FTTB
FTTC
FTTH
GA
General Availability
GEA
GEPON
GPON
IEEE
67
Acronym
ISP
ITU-T
68
Expansions
Internet Service Provider
International Telecommunication Union - Telecommunications
Standardization Sector
MDU
MSAN
OF
Optical Fiber
OFCOM
OLT
ONT
OOB
Out of Band
OSS
PON
POTS
SIP
SME
SoR
Statement Of Requirements
T&D
TDM
TSR
USO
VLAN
WDM