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Amersfoort, 2 & 3 juni 2015
Georges Kazantzidis, RCDD/OSP
Consultant
Huib van der Heijden, RCDD
Luuk Ros
PON
(c) Kannegieter 2015
SiPh
(c) Kannegieter 2015
GLASS AGE # GLASS AGE #
IT professionals today
Communications & Bandwidth
Attenuation
No EMI
Fire
Mechanical performances
Compact / Footprint
Green Receipt
AC6U/UTP 85,14Kg/CO2e per 1Km reel
AC6U/FTP 80,28Kg/CO2e per 1Km reel
HF008PDCO2LU 81,00Kg/CO2e per 2Km reel
GF008PDC02LU 79,99Kg/CO2e per 2Km reel
PON / POL / POLAN
Bandwidth 2,488Gb/s down & 1.244Gb/s up
Standardisation since1995
ITU & IEEE
128 BIT AES Encryption
P2(M)P, Tree or Buss Topology Support
99,999% Quality & Reliability, Telco Grade
Investments FTTH/B Industry
PON / POL / POLAN / GPON / XGPON
ODN
GPON
OLT
Video
OLT
XGPON
OLT
GPON ONU
WDM
1490 nm
1310 nm
1550 nm
1577 nm
1270 nm
XGPON ONU
XGPON ONU
GPON ONU
12
50
12
70
13
10
13
30
13
50
13
70
13
90
14
10
14
30
14
50
14
70
14
90
15
10
15
30
15
50
15
70
1
58
0
15
90
12
90
λ
Splitter
GPON - 1.2G us / 2.4G ds
XGPON - 2.4G us / 10G ds
XG
PO
N
US
GP
ON
US
GP
ON
DS
Vid
eo
DS
XG
PO
N
DS
Typical Building Deployment
Legend
ONT
Splitter
OLT
Each room will have an
ONT. There will be a
mix of wired only and
wired/wireless ONT’s Optical fiber cable will
go from the OLT up the
riser to IDF’s located
on every floor.
The MXK chassis and
OLT blades will be
located in the MDF.
Optical splitters will
be located in the
IDF’s of every floor.
Optical fiber cable will
go from the IDF to
each room.
From this to That
100 meters
20km
Ethernet Traffic
Core
Sw
itch
A
ccess
Sw
itch
• The Core Ethernet Switch Communicates with the Switches in the closets (Uplink)
• Generally Duplex transmission over MM Fibre
• The Closet Ethernet Switch communicates with the End Devices
• Generally over Twisted Pair Copper Cables
• The Access Switch manages the traffic flow to the devices. Only Frames intended for the end device are sent out the switch port.
• Power is required in the MC, IC and at the Workstation
• Cooling is required in the MC and IC
Passive Optical Network Traffic
Optical Lin
e
Term
inal
• The Optical Line Terminal (OLT) communicates with the Optical Network Terminals (ONT) through the Optical Splitter
• Simplex transmission over Single-mode Fibre
• The Optical Splitter is completely passive, splitting the light from the OLT into up to 64 separate light paths
• All frames sent from the OLT (downstream) are received by all ONTs, ignoring the frames not assigned to the addresses ONT.
• Frames sent from the ONT to the OLT (upstream) are sent at specific times to avoid collisions at the splitter
• Power is required at the MC and at the Workstation
• Cooling is required at the MC
Optical Network
Terminal
Optical Network
Terminal
Optical Network
Terminal
Optical
Split
ter
Building blocks
ITU-G.652 & G.657A Fibre
Optical Splitters, Distribution Boxes & BAT
Optical Network Terminal
Optical Line Terminal
ONT / ONU
2 – 4
Voice Ports
(SIP Phone)
2 – 4
PoE Ports
Ethernet
(STB with IPTV)
Triple-play QoS Support
VoIP with CLASS 5 Features
Desktop Design
Outdoor Units
WIFI Integrated
4 – 8
GE LAN
Ports
(POTS Phone / Fax)
Splitter units
Splits an incoming light source into 2 separate paths
Repeating this split multiplies the number of devices that can be connected
to a single port
Typical splits in the LAN 1X16 * 1X32 * 2X32
Five Nines quality and reliability
1:32 (IL 16dB / RL > 55dB)
Common Loss Limit 28dB
1x16
splitter
3dB loss
Protocols Supported
Network Integration
Multiple 1G and 10G Ethernet Uplinks
IEEE 802.3ad Link Aggregation Control Protocol (LACP)
IEEE 802.1Q VLAN Encapsulation
IEEE 802.1w Rapid Spanning Tree (RSTP)
IEEE 802.1s Multiple Spanning Tree (MSTP)
Virtual Router-to-Router Redundancy (VRRP)
IPv4 / IPv6
IGMPv2 / IGMPv3
Network Access Control (NAC)
IEEE 802.1x (Port-based Authentication)
Dynamic Host Control Protocol (DHCP)
DHCP Snooping and Option 82 insertion
Port Security, Sticky MACs
RFC-2267 (Denial of Service)
Traffic Storm Control
Bridge Protocol Data Unit (BPDU) Guard
Service Delivery
802.1p: Class of Service
IP differentiated services code point (DSCP)
Quality of Service: Per-VLAN, Per-Port,
Per-Service queuing / scheduling *
Sophisticated QoS and Traffic Management
Eight Queues per VLAN
Policing, Scheduling, Shaping per Queue
Congestion and Flow Control
Hardware Based ACLs: L2, L3, L4
Hardware Based Multicast Management
IEEE 802.3af, 802.3at (PoE)
Link Layer Discovery Protocol (LLDP)
Monitoring / Management
SNMP v1, v2, v3
CLI Console Port
Remote Monitoring (RMON) software agent
RMON I & II
Enhanced SNMP MIB support
RFC 1213-MIB (MIB II)
Extended MIB support
Network Timing Protocol (NTP)
RADIUS based authentication
SSH v1, v2
VMWare Support for EMS
OLT SysLog (future)
Ethernet Port MACSEC (Encryption) (future)
Key Takeaways
Eliminates access layer electronics
Provides splitter with ‘’five nines” reliability and quality
Reduces cabling & connecting hardware footprint
Can remove or consolidate Commsroom, freeing up valuable space
Uses fewer actives reducing power and HVAC requirements
Uses shared bandwith with high level security (encryption)
Uses Single mode fibre ‘’no rip and replace’’ as bandwith grows
Can realise up to 50% Capex savings
Can provide up to 50% Opex savings
Fixed Network Ports
Less Labour
PON / POL Customers
Eight floors Empire State Building
Live Demo Sessie
1# Fluke Networks & Brand-Rex Wietze Nijboer
2# Zhone & Corning Rob Klap
3# Lancom Wilfred Mokkum
Bedankt voor uw
aandacht.