Nortel Networks Switch 10292FA User Manual

Part No. 212257-B  
January 2002  
4401 Great America Parkway  
Santa Clara, CA 95054  
Installation and Networking  
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Japan/Nippon requirements only  
Voluntary Control Council for Interference (VCCI) statement  
Taiwan requirements  
Bureau of Standards, Metrology and Inspection (BSMI) Statement  
Canada requirements only  
Canadian Department of Communications Radio Interference Regulations  
This digital apparatus does not exceed the Class A limits for radio-noise emissions from digital apparatus as set out in  
the Radio Interference Regulations of the Canadian Department of Communications.  
Règlement sur le brouillage radioélectrique du ministère des Communications  
Cet appareil numérique respecte les limites de bruits radioélectriques visant les appareils numériques de classe A  
prescrites dans le Règlement sur le brouillage radioélectrique du ministère des Communications du Canada.  
Canadian Department of Communications Radio Interference Regulations  
This digital apparatus does not exceed the Class B limits for radio-noise emissions from digital apparatus as set out in the  
Radio Interference Regulations of the Canadian Department of Communications.  
Règlement sur le brouillage radioélectrique du ministère des Communications  
Cet appareil numérique respecte les limites de bruits radioélectriques visant les appareils numériques de classe B  
prescrites dans le Règlement sur le brouillage radioélectrique du ministère des Communications du Canada.  
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Warning: Fiber optic equipment can emit laser or infrared light that can injure your eyes. Never look into  
an optical fiber or connector port. Always assume that fiber optic cables are connected to a light source.  
Warning: Vorsicht: Glasfaserkomponenten können Laserlicht bzw. Infrarotlicht abstrahlen, wodurch  
Ihre Augen geschädigt werden können. Schauen Sie niemals in einen Glasfaser-LWL oder ein Anschlußteil.  
Gehen Sie stets davon aus, daß das Glasfaserkabel an eine Lichtquelle angeschlossen ist.  
Warning: Avertissement: L’équipement à fibre optique peut émettre des rayons laser ou infrarouges  
qui risquent d’entraîner des lésions oculaires. Ne jamais regarder dans le port d’un connecteur ou d’un câble à  
fibre optique. Toujours supposer que les câbles à fibre optique sont raccordés à une source lumineuse.  
Warning: Advertencia: Los equipos de fibra óptica pueden emitir radiaciones de láser o infrarrojas que  
pueden dañar los ojos. No mire nunca en el interior de una fibra óptica ni de un puerto de conexión. Suponga  
siempre que los cables de fibra óptica están conectados a una fuente luminosa.  
Warning: Avvertenza: Le apparecchiature a fibre ottiche emettono raggi laser o infrarossi che possono  
risultare dannosi per gli occhi. Non guardare mai direttamente le fibre ottiche o le porte di collegamento.  
Tenere in considerazione il fatto che i cavi a fibre ottiche sono collegati a una sorgente luminosa.  
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Optical multiplexer/demultiplexer description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21  
Assumptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28  
Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29  
Point-to-point transmission distance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29  
Mesh ring transmission distance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30  
Hub and spoke transmission distance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33  
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Contents  
Cabling a CWDM OADM or a CWDM OMUX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39  
Cleaning Fiber Optic Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50  
Cleaning Duplex SC Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52  
Cleaning Receptacle or Duplex Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53  
Glossary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55  
Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67  
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Figure 14 Class 1M laser warning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36  
Figure 15 Shelf with plug-in module in 19-inch rack . . . . . . . . . . . . . . . . . . . . . . . . . 38  
Figure 16 Cabling a CWDM OADM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40  
Figure 17 Cabling a CWDM OMUX-4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41  
Figure 18 Cabling an CWDM OMUX-8 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43  
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10 Figures  
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Tables  
Table 5  
Table 6  
Table 7  
Table 8  
Table 9  
Table 10  
Mesh ring maximum transmission distance calculations . . . . . . . . . . . . . 32  
Hub and spoke signal loss values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34  
Hub and spoke maximum transmission distance calculations . . . . . . . . . 34  
CWDM OADM specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45  
CWDM OMUX specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47  
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12 Tables  
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13  
Preface  
Nortel Networks* optical routing system supports high-speed data  
communications in metropolitan area networks (MANs) by:  
Connecting Gigabit Ethernet ports with fiber optic networks.  
Combining multiple wavelengths on a single fiber to expand available  
bandwidth.  
The system components include:  
Component  
Function  
CWDM Gigabit interface  
converters (GBICs)  
Convert signals in a switch to laser light for connection to a  
fiber optic network.  
Passive optical  
multiplexing devices  
Combine laser light signals received from GBICs onto a  
single fiber for transport to the destination. Separates the  
wavelengths at the destination and routes them onto  
different fibers which terminate on separate GBICs.  
Passive optical shelf  
Houses the multiplexers.  
“Describing the optical routing system” on page 17  
“Calculating transmission distance” on page 27  
“Installing the shelf, OADM, and OMUX” on page 35  
“CWDM OADM specifications” on page 45  
“CWDM OMUX specifications” on page 47  
“Handling and cleaning fiber optic equipment” on page 49  
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14 Preface  
Before you begin  
This guide is intended for network administrators who have the following  
background:  
Basic knowledge of networks, and network hardware  
Familiarity with networking concepts and terminology  
Familiarity with Ethernet network administration and Fiber Channel  
networking  
Hard-copy technical manuals  
You can print selected technical manuals and release notes free, directly from the  
Internet. Go to the www.nortelnetworks.com/documentation URL. Find the  
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Preface 15  
How to get help  
If you purchased a service contract for your Nortel Networks product from a  
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If you purchased a Nortel Networks service program, contact one of the following  
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Technical Solutions Center  
Telephone  
Europe, Middle East, and Africa  
North America  
(33) (4) 92-966-968  
(800) 4NORTEL or (800) 466-7835  
(61) (2) 9927-8800  
Asia Pacific  
China  
(800) 810-5000  
Additional information about the Nortel Networks Technical Solutions Centers is  
An Express Routing Code (ERC) is available for many Nortel Networks products  
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16 Preface  
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Chapter 1  
Describing the optical routing system  
Nortel Networks* optical routing system uses coarse wavelength division  
multiplexing (CWDM) in a grid of eight optical wavelengths. CWDM Gigabit  
Interface Converters (GBICs) in the switch transmit optical signals from Gigabit  
Ethernet ports to multiplexers in a passive optical shelf. Multiplexers combine  
multiple wavelengths traveling on different fibers onto a single fiber (Figure 1).  
At the receiver end of the link, demultiplexers separate the wavelengths again and  
route them onto different fibers which terminate on separate CWDM GBICs at the  
destination. The system supports both ring and point-to-point configurations.  
Figure 1 Wavelength division multiplexing  
Multiplexer  
Demultiplexer  
signal  
signal  
signal  
signal  
signal  
signal  
signal  
signal  
1
2
3
4
1
2
3
4
Single Fiber  
= Wavelength  
“Parts of the optical routing system” next  
“Gigabit interface converter description” on page 18  
“Optical add drop multiplexer description” on page 19  
“Optical multiplexer/demultiplexer description” on page 21  
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18 Chapter 1 Describing the optical routing system  
Parts of the optical routing system  
The optical routing system includes the following parts:  
Gigabit interface converters (CWDM GBICs)  
Optical add/drop multiplexers (CWDM OADMs)  
Optical multiplexer/demultiplexers (CWDM OMUXs)  
Optical shelf to house the multiplexers  
Table 1 shows the parts of the optical routing system, and the color matching used  
to distinguish the eight wavelengths.  
Table 1 Parts of the optical routing system  
Multiplexer part number  
Wavelength  
GBIC  
Optical shelf  
part number  
(longwave) Color code part number OADM  
OMUX-4  
OMUX-8  
1470 nm  
1490 nm  
1510 nm  
1530 nm  
1550 nm  
1570 nm  
1590 nm  
1610 nm  
Gray  
AA1419017  
AA1419018  
AA1419019  
AA1419020  
AA1419021  
AA1419022  
AA1419023  
AA1419024  
AA1402002  
AA1402003  
AA1402004  
AA1402005  
AA1402006  
AA1402007  
AA1402008  
AA1402011  
AA1402010  
AA1402001  
Violet  
Blue  
AA1402009  
AA1402009  
AA1402009  
AA1402009  
Green  
Yellow  
Orange  
Red  
Brown  
Gigabit interface converter description  
Nortel Networks* coarse wavelength division multiplexed Gigabit Interface  
Converters (Figure 2) convert signals in a switch to laser light for connection to a  
fiber optic network. A CWDM GBIC transmits and receives optical signals at one  
of eight specific wavelengths.  
Nortel CWDM GBICs use Avalanche Photodiode (APD) technology to improve  
transmission distance and optical link budget.  
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Chapter 1 Describing the optical routing system 19  
Figure 2 CWDM GBIC transceiver and label  
Wavelength  
color code  
Model number  
Serial number  
Bar code  
Interface type  
Fiber mode  
Wavelength  
10396EA  
For more information about CWDM GBICs, including specifications, see  
Installing CWDM Gigabit Interface Converters, part number 212256-B.  
Optical add drop multiplexer description  
The passive CWDM optical add drop multiplexer (CWDM OADM) sends and  
receives signals to/from CWDM GBICs installed in the switch. It is set to a  
specific wavelength that matches the wavelength of the CWDM GBIC. It adds or  
drops this specific wavelength from the optical fiber and allows all other  
wavelengths to pass straight through. The Nortel Networks CWDM OADM  
supports two separate fiber pathways traveling in opposite directions (east and  
west) so that the network remains viable even if the fiber is broken at one point on  
the ring.  
Figure 3 shows the single wavelength CWDM OADM network and equipment  
side connections.  
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20 Chapter 1 Describing the optical routing system  
Figure 3 CWDM OADM network and equipment side connections  
Single-wavelength OADM  
RX  
TX  
TX  
RX  
RX TX  
RX TX  
To CWDM GBIC  
Equipment side  
The CWDM OADM (Figure 4) is installed in a 19-inch, rack-mounted 1RU  
optical shelf (Figure 15).  
Figure 4 CWDM OADM Front Panel  
For information about installing a CWDM OADM, see “Inserting a CWDM  
OADM or a CWDM OMUX” on page 38. For specifications, see “CWDM  
OADM specifications” on page 45.  
Network add/drop ring application  
The CWDM OADM pulls off a specific wavelength from an optical ring and  
passes it to a CWDM GBIC of the same wavelength in the switch, leaving all  
other wavelengths on the ring undisturbed. CWDM OADMs are set to one of  
eight supported wavelengths (Table 1).  
Note: The wavelength of the CWDM OADM and the corresponding  
CWDM GBIC must match (see Table 1).  
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Chapter 1 Describing the optical routing system 21  
Figure 5 shows an example of two separate fiber paths in a ring configuration  
traveling in opposite or east/west directions into the network.  
Figure 5 CWDM OADM ring configuration example  
CARRIER  
HOTEL SITE  
PP 8600  
PP 8600  
PP 8600  
PP 8600  
OFFICE  
BUILDING A  
OFFICE  
BUILDING B  
OADM  
OADM  
OMUX OMUX  
PP 8600  
OADM  
OFFICE  
BUILDING C  
For information on calculating network transmission distance, see Chapter 2,  
“Calculating transmission distance,” on page 27.  
Optical multiplexer/demultiplexer description  
The passive CWDM OMUX sends and receives signals to/from CWDM GBIC  
transceivers installed in the switch. It multiplexes and demultiplexes four or eight  
CWDM wavelengths from a two-fiber (east and west) circuit. It allows you to  
create uni-directional network traffic rings or point-to-point links.  
The CWDM OMUX (Figure 6) is installed in a 19-inch, rack-mounted 1RU  
optical shelf (Figure 15).  
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22 Chapter 1 Describing the optical routing system  
Figure 6 Four-channel CWDM OMUX front panel  
Connectors with color-coded labels (Table 1) simplify connection to color-coded  
CWDM GBICs in the switch.  
CWDM OMUX-4  
Figure 7 shows the CWDM OMUX-4 version, with four CWDM GBIC  
equipment side connections.  
Figure 7 CWDM OMUX-4 network and equipment side connections  
RX  
CWDM OMUX-4  
TX  
RX TX RX TX  
RX TX RX TX  
To Equipment side CWDM GBICs  
CWDM OMUX-8  
Figure 8 shows the CWDM OMUX-8 version, with eight CWDM GBIC  
equipment side connections.  
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Chapter 1 Describing the optical routing system 23  
Figure 8 CWDM OMUX-8 network and equipment side connections  
RX  
CWDM OMUX-8  
TX  
RX TXRX TXRX TX RX TX RX TX RX TX RX TX RX TX  
To Equipment side CWDM GBICs  
For information about installing a CWDM OMUX, see “Inserting a CWDM  
OADM or a CWDM OMUX” on page 38. For specifications, see “CWDM  
OMUX specifications” on page 47.  
CWDM OMUX in a point-to-point application  
Point-to-Point (PTP) optical networks carry data directly between two end points  
without branching out to other points or nodes. PTP connections (Figure 9) are  
made between mux/demuxs at each end. PTP connections transport many gigabits  
of data from one location to another, such as linking two data centers to become  
one virtual site, mirroring two sites for disaster recovery, or providing a large  
amount of bandwidth between two buildings. The key advantage of a PTP  
topology is the ability to deliver maximum bandwidth over a minimum amount of  
fiber.  
Each CWDM OMUX supports one network backbone connection and four or  
eight connections to CWDM GBICs in the switch. Typically, two CWDM  
OMUXs are installed in a chassis. The CWDM OMUX on the left is called the  
east path and the CWDM OMUX on the right is called the west path.  
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24 Chapter 1 Describing the optical routing system  
Figure 9 CWDM OMUX point-to-point configuration example  
CARRIER  
HOTEL SITE A  
CARRIER  
HOTEL SITE B  
PP 8600  
PP 8600  
PP 8600  
PP 8600  
OMUX  
OMUX  
OMUX  
OMUX  
10325EA  
For information about calculating network transmission distance, see Chapter 2,  
“Calculating transmission distance,” on page 27.  
CWDM OMUX in a ring application  
CWDM OMUXs are also used as the hub site in CWDM OMUX-based ring  
applications (Figure 10). Two CWDM OMUXs are installed in the optical shelf at  
the central site to create an east and a west fiber path. The CWDM OMUX on the  
left is typically called the east path and the one on the right is called the west path.  
This way the east CWDM OMUX terminates all the traffic from the east  
equipment port of each OADM on the ring and the west CWDM OMUX  
terminates all of the traffic from the west equipment port of each OADM on the  
ring. In this configuration the network remains viable even if the fiber is broken at  
any point on the ring.  
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Chapter 1 Describing the optical routing system 25  
Figure 10 CWDM OMUX ring configuration example  
CARRIER  
HOTEL SITE  
PP 8600  
PP 8600  
PP 8600  
PP 8600  
OFFICE  
BUILDING A  
OFFICE  
BUILDING B  
OADM  
OADM  
OMUX OMUX  
PP 8600  
OADM  
OFFICE  
BUILDING C  
10326EA  
For information about calculating network transmission distance, see Chapter 2,  
“Calculating transmission distance,” on page 27.  
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26 Chapter 1 Describing the optical routing system  
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27  
Chapter 2  
Calculating transmission distance  
“About transmission distance and optical link budget” next  
“Point-to-point transmission distance” on page 29  
“Mesh ring transmission distance” on page 30  
“Hub and spoke transmission distance” on page 33  
About transmission distance and optical link budget  
By calculating the optical link budget, you can determine a link’s transmission  
distance, or the amount of usable signal strength between the point where it  
originates and the point where it terminates. The loss budget, or optical link  
budget, is the amount of optical power launched into a system that is expected to  
be lost through various mechanisms acting on the system, such as the absorption  
of light by molecules in an optical fiber. Factors that affect transmission distance  
include:  
fiber optic cable attenuation (typically 0.25 dB - 0.3 dB per kilometer)  
network devices the signal passes through  
connectors  
repair margin (user-determined)  
Note: Insertion loss budget values for the optical routing system CWDM  
OADM and CWDM OMUX include connector loss.  
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28 Chapter 2 Calculating transmission distance  
How to calculate expected loss budget  
To calculate the expected loss budget for a proposed network configuration:  
1
2
3
Identify all points where signal strength will be lost.  
Calculate the expected loss for each point.  
Add the expected losses together.  
How to calculate maximum transmission distance  
The examples in this chapter use the following assumptions and procedure for  
calculating the maximum transmission distances for networks with CWDM  
GBICs, CWDM OADMs, and CWDM OMUXs.  
Assumptions  
The examples assume use of the values and information listed in Table 2.  
Table 2 Assumptions used in calculating maximum transmission distance  
Item  
Assumption  
Cable  
Single mode fiber optic cable (SMF)  
01  
Repair margin  
Maximum link budget  
System margin  
30 dB2  
3 dB (allowance for misc. network loss)  
.25 dB per kilometer  
Fiber attenuation  
Operating temperature  
CWDM OADM expected loss3  
CWDM OMUX expected loss3  
0 - 40°C (32 - 104°F)  
Use of “CWDM OADM specifications” on page 45  
Use of “CWDM OMUX specifications” on page 47  
1
Use your organization’s expected repair margin for percentage of the total fiber plant loss for each  
site-to-site fiber span.  
2
3
From specifications in Installing CWDM Gigabit Interface Converters, part number 212256-B  
Multiplexer loss values include connector loss.  
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Chapter 2 Calculating transmission distance 29  
Procedure  
To calculate the maximum transmission distance for a proposed network  
configuration:  
1
2
3
4
Identify all points where signal strength will be lost.  
Calculate the expected loss for each point.  
Find total passive loss by adding the expected losses together.  
Find remaining signal strength by subtracting passive loss, and system margin  
from total system budget.  
5
Find maximum transmission distance by dividing remaining signal strength  
by expected fiber attenuation/km.  
Point-to-point transmission distance  
The following factors affect signal strength, and determine point-to-point link  
budget and maximum transmission distance for the network in Figure 11:  
CWDM OMUX mux loss  
CWDM OMUX demux loss  
Fiber attenuation  
The Ethernet switch host does not have to be near the CWDM OMUX, and the  
CWDM OMUX does not regenerate signal. Therefore, maximum transmission  
distance is from GBIC to GBIC.  
Figure 11 Point-to-point network configuration example  
Transmission Distance  
(GBIC to GBIC)  
OMUX-8  
OMUX-8  
GBIC  
GBIC  
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30 Chapter 2 Calculating transmission distance  
Table 3 shows typical loss values that can be used to calculate the transmission  
distance for the point-to-point network in Figure 11.  
Table 3 Point-to-point signal loss values  
Signal loss element  
value (dB)  
Loss budget  
30 dB  
CWDM OMUX-8 mux loss  
CWDM OMUX-8 demux loss  
System margin  
3.5 dB  
4.5 dB  
3 dB  
Fiber attenuation  
.25 dB per km  
Table 4 shows calculations used to determine maximum transmission distance for  
the point-to-point network example in Figure 11.  
Table 4 Point-to-point maximum transmission distance calculations  
Result  
Calculation  
Passive loss  
mux loss + demux loss  
Implied fiber loss  
loss budget passive loss system margin  
implied fiber loss ÷ attenuation per kilometer  
Maximum transmission distance  
Transmission distance calculation for the point-to-point network example in  
Figure 11:  
3.5 dB + 4.5 dB= 8.0 dB Passive Loss  
30 dB 8 dB –3 dB= 19 dB Implied Fiber Loss  
19 dB ÷ .25 dB= 76 km Maximum Transmission Distance  
Mesh ring transmission distance  
The transmission distance calculation for the mesh ring configuration in Figure 12  
is similar to that of the point-to-point configuration with some additional loss  
generated in the passthrough of intermediate CWDM OADM nodes.  
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Chapter 2 Calculating transmission distance 31  
As it passes from point A to point B (the most remote points in the mesh ring  
network example in Figure 12), the signal is expected to lose strength in the fiber  
optic cable, and in each connection between the individual CWDM OADMs and  
CWDM GBICs.  
The following factors determine mesh ring link budget and transmission distance  
for the network in Figure 12:  
CWDM OADM insertion add loss  
CWDM OADM insertion drop loss  
Passthrough insertion loss at intermediate nodes  
Fiber attenuation of 0.25 dB per kilometer  
The Ethernet switch host does not have to be near the CWDM OADM, and the  
CWDM OADM does not regenerate signal. Therefore, maximum transmission  
distance is from GBIC to GBIC.  
The number of OADMs supported is based on loss budget calculations.  
Figure 12 Mesh ring network configuration  
Transmission Distance  
(GBIC to GBIC)  
OADM  
OADM  
OADM  
OADM  
OADM  
OADM  
OADM  
OADM  
A
B
GBIC  
GBIC  
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32 Chapter 2 Calculating transmission distance  
Table 5 shows typical loss values that can be used to calculate the transmission  
distance for the mesh ring network example in Figure 12.  
Table 5 Mesh ring signal loss values  
Signal loss element  
value  
Loss budget  
30 dB  
CWDM OADM insertion add loss  
CWDM OADM insertion passthrough loss  
CWDM OADM insertion drop loss  
System margin  
1.9 dB  
2.0 dB  
2.3 dB  
3 dB  
Fiber attenuation  
.25 dB per km  
Table 6 shows the calculations used to determine maximum transmission distance  
for the mesh ring network example in Figure 12.  
Table 6 Mesh ring maximum transmission distance calculations  
Result  
Calculation  
Passthrough nodes  
Passive loss  
nodes 2  
OADM add + OADM drop + (passthrough nodes × OADM passthrough loss)  
loss budget passive loss system margin  
implied fiber loss ÷ attenuation per kilometer  
Implied fiber loss  
Maximum transmission  
distance  
Transmission distance calculation for the mesh ring network example in  
Figure 12:  
8 nodes 2= 6 Passthrough nodes  
1.9 dB + 2.3 dB + (6 nodes × 2.0 dB)= 16.2 dB Passive Loss  
30 dB 16.2 dB –3 dB= 10.8 dB Implied Fiber Loss  
10.8 dB ÷ .25 dB= 43.2 km Maximum Transmission Distance  
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Chapter 2 Calculating transmission distance 33  
Hub and spoke transmission distance  
Hub and Spoke topologies are the most complex. The characteristics of all  
components designed into the network must be considered in calculating  
transmission distance. The following factors determine maximum transmission  
distance for the hub and spoke configuration in Figure 13:  
CWDM OADM insertion add loss  
CWDM OADM insertion drop loss  
Passthrough insertion loss for intermediate nodes  
Fiber attenuation of 0.25 per kilometer  
The Ethernet switch host does not have to be near the CWDM OADM, and the  
CWDM OADM does not regenerate signal. Therefore, maximum transmission  
distance is from GBIC to GBIC.  
As the signal in Figure 13 passes from point A to point B (the most remote points  
in the hub and spoke), it is expected to lose strength in the fiber optic cable, and in  
each connection between the individual CWDM OADMs, the CWDM OMUX-8,  
and the CWDM GBICs. The number of OADMs that can be supported is based on  
the loss budget calculations.  
Figure 13 Hub and spoke network configuration  
Transmission Distance  
(GBIC to GBIC)  
OADM  
OADM  
OADM  
OADM  
OADM  
OADM  
OADM  
OMUX-8  
OADM  
GBIC  
GBIC  
B
A
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34 Chapter 2 Calculating transmission distance  
Table 7 shows typical loss values that can be used to calculate the transmission  
distance for the hub and spoke network in Figure 13.  
Table 7 Hub and spoke signal loss values  
Signal loss element  
value  
Loss budget  
30 dB  
CWDM OADM insertion add loss  
CWDM OADM passthrough loss  
CWDM OMUX8 demux loss  
System margin  
1.9 dB  
2.0 dB  
4.5 dB  
3 dB  
Fiber attenuation  
.25 dB per km  
Table 8 shows the calculations used to determine maximum transmission distance  
for the hub and spoke network in Figure 13.  
Table 8 Hub and spoke maximum transmission distance calculations  
Result  
Calculation  
Passthrough nodes  
Passive loss  
the number of OADMs between add OADM and OMUX  
OADM add + OMUX8 demux + (passthrough nodes × OADM passthrough loss)  
loss budget passive loss system margin  
Implied fiber loss  
Maximum transmission  
distance  
implied fiber loss ÷ attenuation per kilometer  
Transmission distance calculation for the hub and spoke network example in  
Figure 13:  
7 Passthrough nodes  
1.9 dB + 4.5 dB + (7 × 2.0)= 20.4 dB Passive Loss  
30 dB 20.4 dB –3 dB= 6.6 dB Implied Fiber Loss  
6.6 dB ÷ .25 dB= 26.4 km Maximum Transmission Distance  
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35  
Chapter 3  
Installing the shelf, OADM, and OMUX  
The shelf and multiplexers are passive equipment and require no power or  
“Preparing for installation” next  
“Installing the shelf” on page 37  
“Inserting a CWDM OADM or a CWDM OMUX” on page 38  
“Removing a CWDM OADM or a CWDM OMUX” on page 44  
“Cabling a CWDM OADM or a CWDM OMUX” on page 39  
Preparing for installation  
“Exceeding class 1 power level warning” next  
“Environmental and physical requirements” on page 36  
“Electrostatic discharge” on page 36  
“Handling and cleaning fiber optic equipment” on page 49  
Exceeding class 1 power level warning  
Muxing together several CWDM GBICs can produce a radiant power level in the  
fiber which exceeds the class 1 laser Limit. The warning in Figure 14 appears on  
the CWDM OMUX.  
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Figure 14 Class 1M laser warning  
LASER RADIATION  
DO NOT VIEW DIRECTLY WITH OPTICAL  
INSTRUMENTS (MAGNIFIERS)  
CLASS 1M LASER PRODUCT  
TOTAL RADIANT POWER LEVEL 30 MILLIWATTS  
WAVELENGTH RANGE 1450 TO 1650 NM  
Warning: Never look directly at the output of a fiber which contains  
muxed CWDM GBICs, especially with a magnifier. Fiber optic  
equipment can emit laser light that can injure your eyes.  
Environmental and physical requirements  
The optical routing system is mounted in an optical shelf with connections at the  
front of the module. For user access to these connections, a minimum of 36 inches  
(90 cm) of clearance is required. Keep the area as dust-free as possible.  
Caution: To minimize contamination, keep protective caps on all fiber  
optic connectors when not in use. For more information about handling  
fiber optic cables, see “Handling and cleaning fiber optic equipment” on  
page 49.  
Electrostatic discharge  
To prevent equipment damage, observe the following electrostatic discharge  
(ESD) precautions when handling or installing the components.  
Ground yourself and the equipment to an earth or building ground. Use a  
grounded workbench mat (or foam that dissipates static charge) and a  
grounding wrist strap. The wrist strap should touch the skin and be grounded  
through a one megohm resistor.  
Do not touch anyone who is not grounded.  
Leave all components in their ESD-safe packaging until installation, and use  
only a static-shielding bag for all storage, transport, and handling.  
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Chapter 3 Installing the shelf, OADM, and OMUX 37  
Clear the area of synthetic materials such as polyester, plastic, vinyl, or  
styrofoam because these materials carry static electricity that damages the  
equipment.  
Installing the shelf  
To install the optical shelf (Figure 15) in a standard 19-inch equipment rack:  
1
Support the chassis so that all of the mounting holes in the optical shelf are  
aligned with the corresponding holes in the rack.  
2
3
Attach two rack mounting bolts to each side of the rack.  
Tighten all of the bolts in rotation.  
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38 Chapter 3 Installing the shelf, OADM, and OMUX  
Figure 15 Shelf with plug-in module in 19-inch rack  
Fail  
Pass  
Optical shelf  
10334FA  
Inserting a CWDM OADM or a CWDM OMUX  
CWDM OADMs and CWDM OMUXs are passive devices that require no power  
for their operation. You can insert them in the optical shelf (Figure 15) and then  
connect them into your network.  
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Chapter 3 Installing the shelf, OADM, and OMUX 39  
To insert a CWDM OADM or a CWDM OMUX in the optical shelf:  
2
3
Gently push the plug-in module into the shelf cavity.  
Tighten the captive screws.  
The module is installed. To cable equipment and network connections, see  
“Cabling a CWDM OADM or a CWDM OMUX” on page 39.  
This section includes the following cabling procedures:  
“Cabling a CWDM OADM” next  
“Cabling a four-channel CWDM OMUX” on page 41  
Before you attach fiber optic cable to an optical routing device, review the  
following:  
“Handling and cleaning fiber optic equipment” on page 49  
Table 1, Parts of the optical routing system  
Cabling a CWDM OADM  
This section describes how to cable the following:  
CWDM GBIC to CWDM OADM (Figure 16)  
CWDM OADM to network backbone interfaces (Figure 16)  
To connect the CWDM OADM plug-in module:  
1
Make sure you have the correct CWDM GBIC for your network configuration  
by matching the color of the CWDM GBIC label to the color of the connector  
label on the OADM (see Table 1 on page 18).  
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2
Insert the wavelength-specific CWDM GBICs into their respective network  
device(s). To install a CWDM GBIC, see Installing CWDM Gigabit Interface  
Converters, part number 212256-B.  
3
4
Clean all fiber optic connectors on the cabling (see “Handling and cleaning  
fiber optic equipment” on page 49).  
Connect the fiber optic cables from the CWDM GBIC transmit (TX) and  
receive (RX) connectors to the OADM Equipment RX and TX equipment  
connectors (Figure 16).  
5
Make the following network backbone connections (Figure 16):  
Connect the west network backbone fiber optic cable to the OADM west  
connector.  
Connect the east backbone fiber optic cable to the OADM east connector  
(Figure 16).  
Figure 16 Cabling a CWDM OADM  
TX  
TX  
WEST  
RX  
TX  
RX  
TX  
RX  
OADM-1-49  
1490nm  
EAST  
10332EA  
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Chapter 3 Installing the shelf, OADM, and OMUX 41  
Cabling a four-channel CWDM OMUX  
This section describes how to cable the following:  
CWDM GBIC to a CWDM OMUX-4 (Figure 17)  
CWDM OMUX-4 to west and east network backbone interfaces (Figure 17)  
To connect fiber optic cables to a CWDM OMUX-4:  
1
Insert the wavelength-specific CWDM GBICs into their respective network  
device(s). To install a CWDM GBIC, see Installing CWDM Gigabit Interface  
Converters, part number 212256-B.  
2
3
Clean all fiber optic connectors on the cabling (see “Handling and cleaning  
fiber optic equipment” on page 49).  
Connect the fiber optic cables from the CWDM GBIC TX and RX to the  
CWDM OMUX-4 Equipment RX and TX equipment connectors (Figure 17).  
Figure 17 Cabling a CWDM OMUX-4  
TX  
R
TX  
RX  
TX  
RX  
TX  
RX  
TX  
RX  
TX  
RX  
TX  
RX  
TX  
RX  
TX  
RX  
TX  
RX  
MUX/  
DEMUX-4  
MUX/  
DEMUX-4  
10329EA  
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Note: The CWDM GBIC wavelength must match the CWDM OMUX-4  
equipment connector wavelength.  
The TX of one device must always connect to the RX of the next device.  
4
Make the following network backbone connections (Figure 17):  
Connect the network backbone east fiber optic cables to the east (left)  
CWDM OMUX-4.  
Connect the network backbone west fiber optic cables to the west (right)  
CWDM OMUX-4.  
Cabling an eight-channel CWDM OMUX  
This section describes how to cable the following:  
CWDM GBIC to a CWDM OMUX-8 (Figure 18)  
CWDM OMUX-8 to network backbone interfaces (Figure 18)  
Note: The CWDM OMUX-8 located on the left side of the chassis  
terminates the east network backbone connection. The CWDM OMUX-8  
on the right side of the chassis terminates the west network backbone  
connection. See Figure 18.  
To connect a CWDM OMUX-8:  
1
Install the CWDM GBICs (wavelength specific) into the network device(s).  
To install a CWDM GBIC, see Installing CWDM Gigabit Interface  
Converters, part number 212256-B.  
2
3
Clean all fiber optic connectors on the cabling (see “Handling and cleaning  
fiber optic equipment” on page 49).  
Connect the fiber optic cables from the CWDM GBIC TX and RX connectors  
to the CWDM OMUX-8 RX and TX connectors (Figure 18).  
Note: The wavelength of the CWDM GBIC must match the wavelength  
of the CWDM OMUX-8 equipment connector.  
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Chapter 3 Installing the shelf, OADM, and OMUX 43  
Make the following network backbone connections (Figure 18):  
4
Connect the network backbone east fiber optic cables to the east (left)  
CWDM OMUX-8.  
Connect the network backbone west fiber optic cables to the west (right)  
CWDM OMUX-8.  
Figure 18 Cabling an CWDM OMUX-8  
TX  
TX  
MUX/  
DEMUX-8  
R
MUX/  
DEMUX-8  
RX  
10328EA  
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Removing a CWDM OADM or a CWDM OMUX  
CWDM OADMs and CWDM OMUXs are passive devices that require no power  
for their operation. You can remove them from the optical shelf (Figure 15) after  
disconnecting them from your network.  
To remove a CWDM OADM or a CWDM OMUX plug-in module from the  
optical shelf:  
1
2
3
4
Disconnect the network cabling from the multiplexer.  
Loosen the captive screws on both sides of the module.  
To release the module, gently pull on both screws at the same time.  
Slide the module out of the shelf.  
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45  
Appendix A  
CWDM OADM specifications  
Table 9 CWDM OADM specifications  
Item  
Specification  
Physical Dimensions  
Plug-in Module Size  
Rack Mount  
8.35” x 1.7" x 10.4"  
1RU  
Connectors  
Network Side  
Equipment Side  
2 dual SC/PC  
2 dual SC/PC  
Cabling  
SMF, 9 µm  
Environment  
Operating  
Storage  
0 to 600C  
40 to 850C  
Wavelength Usage  
Uni-directional  
Typical insertion loss*  
TX Equipment to RX Network (add)  
RX Equipment to TX Network (drop)  
Passthrough (Network to Network)  
1.2 dB  
1.6 dB  
1.5 dB  
Maximum insertion loss*  
Sigma  
TX Equipment to RX Network (add)  
RX Equipment to TX Network (drop)  
Passthrough (Network to Network)  
1.9 dB  
2.3 dB  
2.0 dB  
TX Equipment to RX Network (add)  
RX Equipment to TX Network (drop)  
Passthrough (Network to Network)  
.35 dB  
.35 dB  
.40 dB  
Isolation  
TX Equipment to RX Network (add)  
RX Equipment to TX Network (drop)  
Passthrough (Network to Network)  
> 25 dB  
> 50 dB  
> 28 dB  
Passband  
Directivity  
Optical  
Centerwavelength  
+/- 5nm  
< 55 dB  
Wavelengths†  
1471 nm  
1491 nm  
1511 nm  
1531 nm  
1551 nm  
1571 nm  
1591 nm  
1611 nm  
*
Multiplexer loss values include connector loss.  
There is a one nanometer offset between the stated wavelength for the CWDM GBICs and the CWDM OADMs  
due to a shift in the center wavelength of the CWDM GBIC as it reaches typical system operating temperature.  
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46 Appendix A CWDM OADM specifications  
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47  
Appendix B  
CWDM OMUX specifications  
Table 10 CWDM OMUX specifications  
Item  
Specification  
Physical Dimensions  
Plug-in Module Size  
Rack Mount  
8.35” x 1.75" x 8.7"  
1RU  
OMUX-4  
1 dual SC/PC  
4 dual SC/PC  
OMUX-8  
1 dual SC/PC  
8 dual SC/PC  
Connectors  
Network Side  
Equipment Side  
Cabling  
SMF, 9 µm  
Environment  
Operating  
Storage  
0 to 600C  
40 to 850C  
OMUX-4  
1.4 dB  
2.4 dB  
OMUX-8  
2.5 dB  
3.5 dB  
Typical insertion loss*  
TX Equipment to RX Network (Mux)  
RX Equipment to TX Network (Demux)  
OMUX-4  
2.2 dB  
OMUX-8  
3.5 dB  
Maximum insertion loss*  
Sigma  
TX Equipment to RX Network (Mux)  
RX Equipment to TX Network (Demux)  
3.2 dB  
4.5 dB  
OMUX-4  
0.4 dB  
0.4 dB  
OMUX-8  
0.5 dB  
0.5 dB  
TX Equipment to RX Network (Mux)  
RX Equipment to TX Network (Demux)  
OMUX-4  
> 10 dB  
> 50 dB  
OMUX-8  
> 10 dB  
> 50 dB  
Isolation  
Mux  
Demux  
Directivity  
< –55 dB  
Optical OMUX4  
Wavelengths†  
OMUX-4  
1491 nm  
1531 nm  
1571 nm  
1611 nm  
OMUX-8  
1471 nm  
1491 nm  
1511 nm  
1531 nm  
1551 nm  
1571 nm  
1591 nm  
1611 nm  
*
Multiplexer loss values include connector loss.  
There is a one nanometer offset between the stated wavelength for the CWDM GBICs and the CWDM OADMs  
due to a shift in the center wavelength of the CWDM GBIC as it reaches typical system operating temperature.  
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48 Appendix B CWDM OMUX specifications  
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49  
Appendix C  
Handling and cleaning fiber optic equipment  
Precautions  
Danger: Do not look into the end of fiber optic cable. The light source used in  
fiber optic cables can damage your eyes.  
Warning: To prevent damage to the glass fiber, make sure you know how to  
handle fiber optic cable correctly.  
Warning: Do not crush fiber optic cable. If fiber optic cable is in the same  
tray or duct with large, heavy electrical cables, it can be damaged by the  
weight of the electrical cable.  
Although the glass optical path of fiber optic cable is protected with reinforcing  
material and plastic insulation, it is subject to damage. Use the following  
precautions to avoid damaging the glass fiber.  
Do not kink, knot, or vigorously flex the cable.  
Do not bend the cable to less than a 40 mm (1.5-inch) radius.  
Do not stand on fiber optic cable; and keep the cable off the floor.  
Do not pull fiber optic cable any harder than you would a cable containing  
copper wire of comparable size.  
Do not allow a static load of more than a few pounds on any section of the  
cable.  
Place protective caps on fiber optic connectors that are not in use.  
Store unused fiber optic patch cables in a cabinet, on a cable rack, or flat on a  
shelf.  
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50 Appendix C Handling and cleaning fiber optic equipment  
Frequent overstressing of fiber optic cable causes progressive degeneration that  
leads to failure.  
If you suspect damage to a fiber optic cable, either due to mishandling or an  
abnormally high error rate observed in one direction, reverse the cable pairs. If the  
high error rate appears in the other direction, replace the cable.  
Tools and Materials  
You need the following tools and materials to clean fiber optic connectors.  
Lint-free, non-abrasive wiping cloths  
Cotton swabs, with a tightly wrapped and talcum-free tip  
Optical-grade isopropyl alcohol (IPA)  
Canned compressed gas with extension tube  
Warning: To prevent oil contamination of connectors, do not use  
commercial compressed air or house air in place of compressed gas.  
Cleaning Fiber Optic Connectors  
You must perform the following maintenance procedures to ensure that optical  
fiber assemblies function properly. To prevent them from collecting dust, make  
This section contains the following procedures for cleaning fiber optic assemblies:  
“Cleaning Single SC and FC Connectors” next  
“Cleaning Duplex SC Connectors” on page 52  
“Cleaning Receptacle or Duplex Devices” on page 53  
Danger: To avoid getting debris in your eyes, wear safety glasses when  
working with the canned air duster.  
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Appendix C Handling and cleaning fiber optic equipment 51  
Danger: To avoid eye irritation on contact, wear safety glasses when  
working with isopropyl alcohol.  
Caution: To prevent further contamination, clean fiber optic equipment  
only when there is evidence of contamination.  
Caution: To prevent contamination, make sure the optical ports of all  
active devices are covered with a dust cap or optical connector.  
Caution: To avoid the transfer of oil or other contaminants from your  
fingers to the end face of the ferrule, handle connectors with care.  
Before connecting them to transmission equipment, test equipment, patch panels,  
or other connectors, clean all fiber optic connectors. The performance of an  
optical fiber connector depends on how clean the connector and coupling are at  
the time of connection. Use the following cleaning procedures when analyzing  
fiber connector integrity.  
If a connector performs poorly after cleaning, visually inspect the connector to  
determine the possible cause of the problem and to determine if it needs replacing.  
Cleaning Single SC and FC Connectors  
To clean single SC and FC connectors:  
1
2
3
Remove dust or debris by applying canned air to the cylindrical and end-face  
surfaces of the connector.  
Gently wipe the cylindrical and end-face surfaces with a pad or a wipe  
dampened with optical-grade isopropyl alcohol.  
Gently wipe the cylindrical and end-face surfaces with a dry, lint-free tissue.  
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52 Appendix C Handling and cleaning fiber optic equipment  
Dry the connector surfaces by applying canned air or letting them air dry.  
4
Caution: To prevent contamination, do not touch the connector surfaces  
after cleaning; and cover them with dust caps if you are not going to use  
them right away.  
Cleaning Duplex SC Connectors  
To clean duplex connectors:  
1
To remove or retract the shroud, do one of the following.  
On removable shroud connectors, hold the shroud on the top and bottom  
at the letter designation, apply medium pressure, and pull it free from the  
connector body. Do not discard the shroud.  
On retractable shroud connectors, hold the shroud in its retracted position.  
2
3
4
Remove dust or debris from the ferrules and connector face with the canned  
air duster.  
Gently wipe the cylindrical and end-face surfaces of both ferrules using a  
wipe saturated with optical-grade isopropyl alcohol.  
Gently wipe the cylindrical and end-face surfaces of the connector with  
Texwipe cloth (or dry lint-free tissue).  
5
6
Blow dry the connector surfaces with canned air.  
Using care to not touch the clean ferrules, gently push the shroud back onto  
the connector until it seats and locks in place.  
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Appendix C Handling and cleaning fiber optic equipment 53  
Cleaning Receptacle or Duplex Devices  
Note: To avoid contamination, optical ports should only be cleaned when  
there is evidence of contamination or reduced performance, or during  
their initial installation.  
To clean receptacle or duplex devices:  
Warning: To prevent oil contamination, do not use commercial  
compressed air.  
Warning: Do not allow the tube to touch the bottom of the optical port.  
1
2
Remove dust or debris by blowing canned air into the optical port of the  
device using the canned air extension tube.  
Clean the optical port by inserting a small dry swab into the receptacle and  
rotating it.  
Note: Each cleaning wand should only be used to clean one optical port.  
3
Reconnect the optical connector and check for proper function.  
If problems persist, repeat steps 1 and 2.  
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54 Appendix C Handling and cleaning fiber optic equipment  
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55  
Glossary  
attenuation  
The decrease in signal strength in an optical fiber caused by absorption and  
scattering. Attenuation can be calculated to express  
signal loss between two points  
total signal loss of a telecommunications system or segment  
attenuator  
A device inserted into the electrical or optical path to lessen or weaken the  
signal.  
bandwidth  
The range of frequencies within which a fiber-optic medium or terminal  
device can transmit data or information.  
cable  
One or more optical fibers enclosed within protective covering(s) and strength  
members to provide mechanical and environmental protection for the optical  
fibers.  
cable assembly  
An optical-fiber cable with connectors installed on one or both ends. The  
general purpose of the cable assembly is to interconnect the cabling system  
with opto-electronic equipment at either end of the system. Cable assemblies  
with connectors on one end only are called pigtails. Assemblies with  
connectors on both ends are typically called jumpers or patch cords.  
cable plant  
The cable plant consists of all the optical elements such as fiber connectors  
and splices between a transmitter and a receiver.  
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56 Glossary  
CD-ROM  
compact disc read-only memory  
A compact disc with pre-recorded data, normally used in large database-type  
applications such as directory, reference, or data retrieval.  
channel  
A communications path or the signal sent over that path. By multiplexing  
several channels, voice channels can be transmitted over one optical channel.  
CO  
central office  
A major equipment center designed to serve the communication traffic of a  
specific geographical area.  
configuration  
The relative arrangements, options, or connection pattern of a system and its  
subcomponent parts and objects.  
configure  
The process of defining an appropriate set of collaborating hardware and  
software objects to solve a particular problem.  
CWDM  
coarse wavelength division multiplexing  
A technology that allows two or four optical signals with different  
wavelengths to be simultaneously transmitted in the same direction over one  
fiber, and then separated by wavelength at the distant end.  
dB  
decibel  
A unit of measure indicating relative optic power on a logarithmic scale.  
Often expressed to a fixed value, such as dBm (1 milliwatt) or dBµ  
(1 microwatt).  
dBm  
decibels above one milliwatt  
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Glossary 57  
demultiplexing  
The separating of different wavelengths in a wavelength-division  
multiplexing system. The opposite of multiplexing.  
dispersion  
The broadening of input pulses as they travel the length of an optical fiber.  
There are three major types of dispersion, as follows:  
modal dispersion, which is caused by the many optical path lengths in a  
multimode fiber  
chromatic dispersion, which is caused by the differential delay at various  
wavelengths in the optical fiber  
waveguide dispersion, which is caused by light traveling through both the  
core and cladding materials in single-mode fibers  
DWDM  
dense wavelength division multiplexing  
A technology that allows a large number of optical signals (usually 16 or  
more) with different wavelengths to be simultaneously transmitted in the  
same direction over one fiber, and then separated by wavelength at the distant  
end.  
ESD  
electrostatic discharge  
Discharge of stored static electricity that can damage electronic equipment  
and impair electrical circuitry, resulting in complete or intermittent failures.  
Ethernet  
A local area network data link protocol based on a packet frame. Ethernet,  
which usually operates at 10 Mbit/s, allows multiple devices to share access to  
the link.  
facility  
Any provisional configuration that provides a transmission path between two  
or more locations without terminating or signalling equipment. Also, the  
logical representation of a transport signal.  
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58 Glossary  
fiber  
See optical fiber.  
fiber loss  
Also optical fiber loss. The attenuation of the light signal in optical-fiber  
transmission.  
fiber-optic link  
A combination of transmitter, receiver, and fiber-optic cable capable of  
transmitting data.  
FO  
fiber optics  
The branch of optical technology dedicated to transmitting light through  
fibers made of transparent materials such as glass and plastic.  
GBIC  
Gigabit interface converter  
Allows Gigabit Ethernet ports to link with fiber optic networks.  
Gbit/s  
Gigabits per second  
A measure of the bandwidth on a data transmission medium. One Gbit/s  
equals 1,000,000,000 bps.  
Gigabit Ethernet  
Gigabit Ethernet  
A LAN transmission standard that provides a data rate of one billion bits per  
second (Gbit/s).  
ground  
An electrical term meaning to connect to the earth or other large conducting  
body to serve as an earth thus making a complete electrical circuit.  
GUI  
graphical user interface  
A graphical (rather than textual) interface to a computer.  
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hub  
A group of circuits connected at one point on a network.  
insertion loss  
In an optical fiber system, the total optical power loss caused by insertion of  
an optical component, such as a connector, splice, or coupler. Usually given in  
dB.  
kbps  
thousands of bits per second  
A measure of the bandwidth on a data transmission medium. One kbps equals  
1000 bps.  
lambda  
See wavelength.  
LAN  
local area network  
A data communications network that is geographically limited (typically to a  
1 km radius), allowing easy interconnection of terminals, microprocessors,  
and computers within adjacent buildings. Most notable of LAN topologies are  
Ethernet, token ring, and FDDI.  
laser  
An acronym for "Light Amplification by Stimulated Emission of Radiation".  
A laser is a monochromatic (same wavelength), coherent (waves in phase),  
beam of radiation.  
loss  
The ratio of optical output power to input power, usually given in units of dB.  
Usually represents a decrease in an optical signal. A negative loss means a  
gain of power.  
loss/attenuation  
In an optical fiber, the absorption of light by molecules in the fiber, causing  
some of the intensity of light to be lost from the signal. Usually measured in  
dB.  
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60 Glossary  
loss budget  
The amount of optical power launched into a system that will be lost through  
various mechanisms, such as insertion losses and fiber attenuation. Usually  
given in dB.  
MAN  
metropolitan area network  
A MAN consists of LANs interconnected within a radius of approximately  
80 km (50 miles). MANs typically use fiber-optic cable to connect LANs.  
margin  
The amount of loss, beyond the link budget amount, that can be tolerated in a  
link.  
MMF  
multimode fiber  
A fiber with core diameter much larger than the wavelength of light  
transmitted that allows many modes of light to propagate. Commonly used  
with LED sources for lower speed, short distance lengths. Typical core sizes  
(measured in microns) are 50/125, 62.5/125 and 100/140.  
mode  
An independent light path through an optical fiber. See SMF and MMF.  
multimode fiber  
See MMF.  
multiplexing  
Carriage of multiple channels over a single transmission medium; any process  
by which a dedicated circuit can be shared by multiple users. Typically, data  
streams are interspersed on a bit or byte basis (time division), or separated by  
different carrier frequencies (frequency division).  
MUX  
multiplexer  
A device that combines two or more signals into a signal composite data  
stream for transmission on a single channel.  
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NDSF  
non-dispersion-shifted fiber  
A type of optical fiber optimized for the 1310 nm transmission window.  
nanometer  
See nm.  
nm  
nanometer  
One billionth of a meter (10-9 meter). A unit of measure commonly used to  
express the wavelengths of light.  
node  
A point in an optical network where optical signals can be processed and  
switched among various links.  
NZDSF  
non-zero-dispersion-shifted fiber  
A type of optical fiber optimized for high bit-rate and dense  
wavelength-division-multiplexing applications.  
OADM  
optical add/drop multiplexer  
An optical multiplexer/demultiplexer (mux/demux) that adds or drops one  
CWDM channel of the same wavelength from the optical fiber and allows all  
other wavelengths to pass straight through.  
O/E  
OC  
optical to electrical  
Optical to electrical conversion.  
optical carrier  
Series of physical protocols, such as OC-1, OC-2, and OC-3, defined for  
SONET optical signal transmissions. OC signal levels put STS frames onto  
fiber-optic line at a variety of speeds. The base rate is 51.84 Mbit/s (OC-1);  
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62 Glossary  
each signal level thereafter operates at a speed divisible by that number. For  
example, OC-3 operates at 155.52 Mbit/s.  
OC-1  
optical carrier - level 1  
An optical SONET signal at 51.84 Mbit/s.  
OC-3  
optical carrier - level 3  
An optical SONET signal at 155.52 Mbit/s.  
OC-12  
optical carrier - level 12  
An optical SONET signal at 622.08 Mbit/s.  
OMUX  
optical multiplexer  
An optical multiplexer/demultiplexer that multiplexes and demultiplexes four  
or eight CWDM wavelength channels from a two-fiber circuit.  
optical channel  
An optical wavelength band for WDM optical communications.  
optical fiber  
Very thin strands of pure silica glass through which laser light travels in an  
optical network. Consists of a core surrounded by a less refractive index  
cladding.  
optical seam  
An optical seam occurs at any site in a network when there is no optical  
passthrough, that is, where information is dropped from but not added onto  
the ring.  
Optical Time Domain Reflectometer (OTDR)  
Device used to inspect optical fiber links by sending optical pulses down them  
and monitoring the light reflected back to the device. Can calculate overall  
fiber attenuation and highlight points of loss in the fiber, or even fiber breaks.  
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optical waveguide  
See optical fiber.  
passive device  
A device that does not require a source of energy to function.  
passthrough  
A signal bypass mechanism that allows the signal to pass through a device  
with little or no signal processing.  
point-to-point transmission  
Carrying a signal between two endpoints without branching to other points.  
protocol  
The procedure used to control the orderly exchange of information between  
stations on a data link or on a data-communications network or system.  
Protocols specify standards in three areas: the code set, usually ASCII or  
EBCDIC; the transmission mode, usually asynchronous or synchronous; and  
the non-data exchanges of information by which the two devices establish  
contact and control, detect failures or errors, and initiate corrective action.  
provisioning  
The process by which a requested service is designed, implemented, and  
tracked.  
ring architecture  
A network topology in which terminals are connected serially point-to-point  
in an unbroken circle.  
Rx  
receive  
A terminal device that includes a detector and signal processing electronics. It  
functions as an optical-to-electrical converter.  
scalable  
The ability to add power and capability to an existing system without  
significant expense or overhead.  
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64 Glossary  
single-mode fiber  
See SMF.  
SMF  
A mode is one of the various light waves that can be transmitted in an optical  
fiber. Each optical signal generates many different modes, but in single-mode  
fiber the aim is to only have one of them transmitted. This is achieved through  
having a core of a very small diameter (usually around 10 micrometers), with  
a cladding that is usually ten times the core diameter. These fibers have a  
potential bandwidth of 50 to 100 GHz per kilometer.  
Tx  
transmit  
A device that includes a LED or laser source and signal conditioning  
electronics that is used to inject a signal into optical fiber.  
U
(vertical) unit  
One U is 1.75 inches. Standard equipment racks have bolt holes spaced  
evenly on the mounting rails to permit equipment that is sized in multiples of  
this vertical unit to be mounted in the same rack.  
WAN  
wide area network  
A physical or logical network that provides data communications to a larger  
number of independent users than are usually served by a LAN and is usually  
spread over a larger geographic area than that of a LAN.  
wavelength  
All electromagnetic radiation (radio waves, microwaves, ultraviolet light,  
visible light, etc.) is transmitted in waves, and the wavelength is the distance  
between the successive crests of the waves. In optical networks, you can think  
of different wavelengths as being different colors of light. Wavelengths of  
light are measured in nanometers or microns.  
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Glossary 65  
WDM  
wavelength division multiplexing  
Transmitting many different colors (wavelengths) of laser light down the  
same optical fiber at the same time in order to increase the amount of  
information that can be transferred.  
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66 Glossary  
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67  
add/drop mux 20  
A
add/drop mux  
four-channel mux/demux 22  
connecting cables 39  
ring application 20  
CWDM OADM  
application  
point-to-point, mux/demux 23  
ring, add/drop mux 20  
attenuation 27  
CWDM OMUX  
B
cabling eight-channel 42  
cabling four-channel 41  
description 21  
block diagram, connections  
add/drop mux 20  
C
mux/demux 47  
directivity, specification  
add/drop mux 45  
duplex devices, cleaning 53  
SC, FC connectors 51  
tools and materials 50  
E
electrostatic discharge 36  
connecting cables  
add/drop mux 39  
eight-channel mux/demux 42  
four-channel mux/demux 41  
environment, specification  
add/drop mux 45  
mux/demux 47  
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68 Index  
equipment side connections  
M
mesh ring application  
eight-channel mux/demux 42  
calculating transmission distance for 30  
F
FC connectors, cleaning 51  
fiber optic cable  
attenuation and transmission 27  
cleaning connectors for 50  
precautions with 49  
connecting cables, eight-channel 42  
connecting cables, four-channel 41  
description 21  
insert in shelf 38  
front panel  
add/drop mux 20  
four-channel mux/demux 22  
N
G
network backbone connections  
add/drop mux 39  
H
hub and spoke  
connecting cables 39  
I
insertion loss, specification  
add/drop mux 45  
mux/demux 47  
isolation, specification  
connecting cables, eight-channel 42  
specifications 47  
L
link budget  
about 27  
hub and spoke example 33  
mesh ring example 30  
point-to-point example 29  
optical link budget  
about 27  
hub and spoke 33  
mesh ring 30  
point-to-point 29  
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transmission distance  
about 27  
shelf, installing 37  
hub and spoke example 33  
mesh ring example 30  
P
passband, specification  
wavelength  
add/drop mux 45  
add/drop mux 45  
mux/demux 47  
usage specification  
add/drop mux 45  
point-to-point application  
mux/demux 23  
network configuration example 29  
product support 15  
publications  
R
receptacle devices, cleaning 53  
add/drop mux 20  
S
shelf, optical  
insert mux in 38  
T
technical publications 14  
technical support 15  
tranceiver, CWDM GBIC 18  
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70 Index  
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