May 4, 2012 - PON, Optical LAN Solutions (Gary Eifert, TE)

Optical LAN Solutions – Customer Overview
The Infrastructure of Tomorrow, Available Today
© 2011 Tyco Electronics Corp., a TE Connectivity LTD Company. All Rights Reserved.
ADC, ADC logo, Rapid Reel, RealFlex, TE Connectivity, TE Connectivity logo,
TFP, TRUENET, and Tyco Electronics are trademarks. Other products, logos, and
company names herein may be trademarks of their respective owners.
Sean P. Kelly, RCDD
March 12, 2012
PON Basics
• PON- Passive Optical Network
- (Carrier) Between Central Office (CO), or substation, and the premises in FTTx
• POL- Passive Optical Local Area Network
- (Enterprise) Between the data center and the user*.
*A user can be a human or device. (Virtually any IP device with an RJ-45 interface)
• No power required from the data center to the
user area.
PON Basics Cont.
• GPON
- One of the fastest growing PON architectures today
- Point to Multipoint
- Bandwidth on Demand
• Established and proven in the outside plant with various FTTH
projects such as Verizon FIOS in the US, and many others around the
world.
• The success of the OSP system has created an opportunity to bring
the same system design into the enterprise.
GPON Details
• Single, singlemode fiber to each work area
- Downstream up to 2.4Gbs @ 1490nm – (TDM) voice, data, switched video
- Upstream up to 1.2Gbs @ 1310nm – (TDMA) voice, data, signaling video
- WDM video (RF/Analog) overlay and future DWDM applications @ 1550nm
- All simultaneous
• Technically Future Proof (Passive Components)
- SM fiber has an unknown bandwidth limitation.
- Until electronics reach the limit, glass manufacturers will not design
“next generation” singlemode
- Upgrades to the next generation are as simple as replacing the electronics
Active Components (Powered)
– Motorola, Tellabs, Alcatel, and others
• OLT – Optical Line Terminal
- AKA - Enterprise Aggregation Switch
(19” Rack Mountable) 24.5” x 17.4”x 16.8”
- Located in the Data Center
- After the Level 3 WAN router
• Fully populated OLT
- Up to 14 Line cards
OLT – Optical Line Terminal
- 4 Singlemode output ports per card
= 56 Outputs per chassis
= 1792 Work Group Terminals (1x32 splitters)
= 7168 Ethernet Ports (ONT has 4 copper output ports)
Photo courtesy of Motorola
Active Components (Powered)
• ONT – Optical Network Terminal
- Located near the user or device
- 4 RJ45 (10/100/1000) output ports with optional POE
- Up to 62W* of available POE
- Standard HVAC is adequate
*Vendor Specific
ONT – Optical Network Terminal
Photo courtesy of Motorola
- Optional internal or external battery back-up.
Traditional LAN Solutions Key Elements
Top Level System View
Data Center
Application Services
Riser Closet
X
X
Distribution
Switch
XC
MM Fiber
Data
X
X
MM Fiber jumper
X
X
X
XC
X
C
P
`
Optional
Consilodation
Point
XC
CORE
LAN
Switch
X
X
X
CAT5 copper cable
Junction box
Voice
XC
X
WAN
= Connection required
MM Fiber for Data , CAT 5 copper for voice application
XC = Cross Connect cable
144 User Example
Requires this
much cable
884 lbs.
- 144 MMF x 55m (Horizontal) = 390 lbs.
- 144 Cat 5E x 55m (Horizontal) = 494 lbs.
Optical LAN Solutions Key Elements
Top Level System View
This is technically the
“Horizontal Cabling” – Copper
runs can be up to 100 meters.
Application Services
Data Center
Riser Closet
Raised Floor
Desktop
12 fibers
PNP
CORE
LAN
Switch
PNP
PNP
1-12
PNP
PNP
Router
1-56
OLT
WAN
Router
Fiber Panel
iFDH
iFDT
ONT
PNP= Plug-n-Play (no splicing required)
12 mile reach
No Power, Cooling, or Network Element Maintenance
144 User Example
Requires this
much cable
`
182 lbs.
- 144 SMF x 55m = 182 lbs.
`
OLS vs. MMF for data Copper for voice
FTTD Cables
•
The OLS solution eliminates cable
congestion that is associated with
traditional structured cabling
applications.
•
Traditional networks would require a
home run from each user for voice, data,
and even video.
•
The OLS solution utilizes a single fiber for
all services reducing cable bundles.
•
Small form factor factory terminated
multi-fiber cables and MT connectors
reduce cable congestion and speed up
installations
144 SM fibers (Data, voice & video)
Conventional Cables
144 MM fiber cables (Data)
144 copper cables (Voice)
Traditional Ethernet design for a
500 user system
YES
NO
REQUIRES
Power
HVAC
Racking
UPS
(8) 24 port Workgroup
switches per floor
Home-run cabling
to each user
Enterprise Multi-service
Router in Data Center
OLS design for 500 user system
YES
REQUIRES
NO
Power
HVAC
Racking
UPS
Workgroup switches
Home-run cabling
Enterprise Multi-service
Router in Data Center
TE OLS infrastructure schematic
Up to 12 miles!!!
Telcom Room or Data Center
OLT
Desktop
Raised floor
or Drop Celing
Riser Closet
Patch cord
to ONT
Patch cord
to OLT
GPON port
PNP
FDH
PNP
Router
1
12 Fiber cable
RR
TFP Fiber Panel
With MPO Cassettes
PNP12 Fiber cable
32
1 x 32
Splitter
RR
FDT
1
PNP
12
Fiber
Distribution
Terminal
Fiber Distribution
Hub
PNP= Plug -and- Play no
splicing required
Rapid Reel
RR
w/ built in
slack storage
PNP
Wall PNP
Plate w /
adapter
TE PON Solution
OLT
TFP – TrueNet Fiber Panel
iFDH – indoor Fiber
Distribution Hub
Passive Optical Splitters (1x32)
Fiber Patch Cords
ONT
iFDT – indoor Fiber Distribution
Terminal (Consolidation Point)
Faceplates
and
Adapters
TE Connectivity Confidential – Do Not Distribute
Copper
Patch
Cords
TE PON Solution
OLT
TFP – TrueNet Fiber Panel
iFDH – indoor Fiber
Distribution Hub
Passive Optical Splitters (1x32)
Fiber Patch Cords
ONT
iFDT – indoor Fiber Distribution
Terminal (Consolidation Point)
Faceplates
and
Adapters
Copper
Patch
Cords
xPON Active Equipment
DC Rectifier
Edge Router
TE
PON
Solution
1.6” (H) x 5.5” (W) x 6.5” (L)
ONT – Optical Network Terminal
OLT – Optical Line Terminal
Photos courtesy of Motorola
Rapid Innerduct collector box
• Collection point for iFDT feeder cables
• Positioned near each hub
– Typically within 100’ of the iFDH
– In a convenient location that will allow
access to pull cables from terminals
– Under the floor or in the ceiling
• Designed to accommodate all iFDH sizes
Savings
costs comparison
• Infrastructure
Footprint
The plug-n-play functionality of the FTTD solution offers
Footprint:
Power/Cooling/Capital
Expenditures:
tremendous
labor
cost
savings
over
traditional
FTTD infrastructure savings over
MMF
for data MMF
and copper
installations
for
-No
voice
switches
approach
and
patch panels = no racks = no
No
switches
(CapEx)
• dedicated
Power/Cooling/Capital
Expenditures
room
- No power
for switches
250
User
system>60%
$7K savings
savings
250
User
system- No additional
cooling >for$15K
switches
500 User system
savings
- iFDH
can
500
be
located
User
systemin
a
broom
62%
closet
savings
- No 1000
maintenance
contracts
User
system
> 70%
$30Ksavings
savings
• Infrastructure
savings
1000costs
User system2000
User
system
> 69%
$60Ksavings
savings
Floor
space
2000
can
User
be
reallocated*
system1000
User
system
70% savings
-–No
UPS
back
up for ~switches
(CapEx)
Source FOLS horizontal cabling costs model fiber vs. UTP
- Additional
power savings
Source FOLS horizontal
cabling costs model fiber vs. UTP
Source
FOLS
horizontal
cabling
costs model of
fiberspace
vs. UTP
* Savings- Additional
are realized
upon
reallocation
cooling savings
Actual
installation
data over traditional
• Plug-n-play
labor
cost savings
Footprint Savings
75 Users
250+ Users
Savings
Case Studies:
University of Mary Washington
Russell Investments, Seattle, Washington
- Part of UMW’s Sustainability Initiative
Reduced
the number
of IDFs
from 10 to 3 power savings
Estimated
$450K
in Washington
commercial
–-- University
of Mary
- Actual year one savings >$1MM
- Each IDF is now located in a broom closet
Previously
allocated
IDF space now revenue generating dorm rooms
IDF costs
reduced
–-- Russell
Investments
- $70k per IDF
- Design saved many pounds of plastic and copper compared to CAT6
- 2 IDFs per floor
- Reduced overhead racks
- Reduced building weight
Source: David Scott - Motorola
- Received two LEED credits (Unusual for structured cabling)
Source: David Scott - Motorola
Design savings using TE OLS
Passive Optical LAN (PON) Solution
2 Users Per ONT
Traditional LAN
(1Cu Data / 1Cu Voice)
Traditional LAN
(1 Shared Cu Voice/Data)
•
•
•
•
4 Users Per ONT
System
User
System
User
46%
73%
-
-
System
User
System
User
-
-
28%
82%
Percentages reflect savings over traditional
Savings of cable plant and electronics only
Does not include potential OpEx or Labor savings
Exact savings may vary by specific design
Source data
2010 Department of Army Directive
Technical Guidance for Network Modernization April 23, 2010
Your Converged Network Solution
Services
WAN
LAN
Firewall
Edge
Router
PSTN
IP-TV
12 x Gig-E
2 x 10 Gig-E
Data Center
Soft
PBX
Video
Server
OLT
Riser Closet
FDH
Office Workspace
FDT
No Power
No Cooling
No Monitoring
No Maintenance
12 miles nominal distance
from OLT to ONT
SMF Jumper
4 x 1000 Base-T
Desktop
Remote Mgmt
No User Ctrls
Remote Test
QoS Features
PWR
12VDC
8 Watts
VoIP Phone
IP Video
LAN
Spare
23
Typical Office Layout (Leading Solution)
12 mile reach
No Power, Cooling, or Network Element Maintenance
OLS Campus/Redundant Architecture
OLS Architecture
Alternate Home-run Application
Deployment: Single Wing in Building
Environment
Cubicles:120
Offices: 20
Printer/Fax: 4
Conf. Rooms: 6
Solution
Fiber Hub:1
Terminals: 12
Splices: 0
Field Terminations: 0
Results
Duration: 1 Week
Gbps Ethernet Ports: 600
Deployment: Dorm Room
Environment
2 students sharing a room
Voice Ports: 1+
Data Ports: 6
RF Connections: 3
Solution
ONTs per Dorm: 2
Lockable cabinets: 2
Splices: 0
Field Terminations: 0
Results
Fibers to each room: 2
Comms ports provisioned: 12+
Deployment: Three Separate Networks
Environment
Cubicles:204
Offices: 16
Printer/Fax: 16
Conf. Rooms: 10
Solution
Fiber Hub:2
Terminals: 18
Splices: 0
Field Terminations: 0
Results
Duration: 2 Weeks
Gbps Ethernet Ports: 984
Deployment: Business Office
Environment
Cubicles:195
Offices: 8
Conf. Rooms: 10
Solution
Fiber Hub:2
Terminals: 24
Splices: 0
Field Terminations: 0
Results
Duration: 1 Week
Gbps Ethernet Ports: 812
Campus Distribution
FDT
FDT
FDH
ONT
FDT
ONT
FDH
FDH
FDT
FDH
2x32 + Patch
1x32
FDT + Patch
FDT
FDT
ONT
FDH
FDT
FDT
FDH
FDT
ONT
ONT
ONT
2x32 + Patch
1x32
FDT + Patch
FDH
FDH
ONT
2x32 + Patch
1x32
FDT + Patch
OLT
TFP
ONT
ONT
FDT
FDH
FDT
FDT
FDH
FDT
FDH
FDH- Each
Floor
FDT
OLT
ONT
FDH
FDT
TFP
FDH
FDT
FDH
FDH
FDT
FDHFDH
ONT
FDT
FDH
FDHHomerun
TFP
FDHFDH
FDT
ONT
FDT
TFP
FDH
FDT
FDH
FDH
1x32 + Patch
OLT
ONT
TFP
1x32 + Patch
FDH
1x32 + Patch
FDT
FDH
FDT
ONT
FDT
FDH
OLT
FDH
TFP
FDT
TFP
FDH
OLT
FDH
FDT
ONT
FDH
FDH
FDH
FDH
FDT
TFP
FDHCentral
OLT
TFP
FDH
OLT
OLT
FDH OLT
FDH FDH
OLT
TFP
FDH
FDH
OLT
FDH
TFP
2x32 + Patch
ONT
FDH
2x32 + Patch
2x32 + Patch
FDH
TFP
OLT
Split on Floor (2x32)
Redundant
Split
onEach
Central
Floor
Split
FDHon
Floor
FDHHomerun
Campus
Distribution
(2x32)
(1x32)
Floor
Redundant
Split on Floor
(1x32)
OLT Installation (Data Center)
Tellabs OLT EXAMPLE
Motorola OLT EXAMPLE
EMS Server
ONT Installation
ONT under-desk mount version
SECURE Wall Box version
ONT wall-mount version
Appliance outlet
ONT desktop mount version
Target PON Users
Hospitals
Campuses
Universities
Cruise Ships
Hotels (Large)
Government and Military
High Occupancy Buildings (Call Centers)
Multi-Tenant Units (Commercial and Residential)
Summary of Benefits
•
• Reduced
fire reduction
load, building
weight,power
and use
of non-renewable
Up to 50%
in network
consumption
materials
• Significantly reduced cabling construction costs*
• Intuitive plug and play design reduces installation time and errors
• Significant floor space savings with TE OLS plug and play
• Lower
future expansion costs
design
Multiplefuture
buildings
one main equipment room
•• Virtually
proofserved
(cable by
plant)
Plenum
rated
cable and reduced bulk allow for more flexible
•• Overall
TCO
reduction
architectural design considerations
Thank You!
Thank you