Chp 3 Physical Layer Cabling Fiber Optics

Question 1

Fiber Optic Network

Answer 1

1. A fiber optic transmission strand can carry the signal (in from a modulated light beam) a few feet or even hundreds or thousands of miles. A cable may contain three or four hair-like fibers or a bundle of hundreds of fibers.
2. A source of invisiable infared radiation, usually a light emitting diode (LED) or a solid-state laser - that can be modulated to impress digital data or an analog signal on the light beam
3. A photsenitive detector to convert the optical signal back into a electrical signal at the receiver.
4. Efficient optical connectors at the light source-to-cable interface and at the cable-to-photo detector interface. These connectors are also critical when splicing teh optical cable due to excessive loss that can occur at connections.

Question 2

ADAVANTAGES

OF

OPTICAL COMMUNICATION LINKS

COMPARED TO COPPER CONDUCTORS

Answer 2

1. EXTREMELY WIDE SYSTEM BANDWITH
2. IMMUNITY TO ELECTROSTATIC INTERFERENCE
3. ELIMINATION OF CROSS TALK
4. LOWER SIGNAL ATTENUATION THAN OTHER PROPAGATION SYSTEMS
5. LOWER COST
6. SAFETY
7. CORROSION
8. SECURITY

Question 3

EXTREMELY WIDE SYSTEM BANDWTIH

AS AN ADVANTAGE OF

OPTICAL COMMUNICATION LINKS

Answer 3

THE INTELLIGENCE IS IMPRESSED ON TEH LIGHT BY VERING THE LIGHT’S AMLITUDE. BECAUSE THE BEST LEDs HAVE A 5 NS RESPONSE TIME, THEY PROVIDE A MAXIMUM BANDWITH OF ABOUT 100MHZ. WITH LASER LIGHT SOURCES HOWEVER, DATA RATES ARE OVER 10GBPS ARE POSSIBLE WITH A SINGLE MODE FIBER. THE AMOUNT OF INFORMATION MUTIPLEXED ON SUCH A SYSTEM IN THE HUNDREDS OF GBPS, IS INDEED STAGGERING.

Question 4

IMMUNITY OF THE ELECTROSTATIC INTERFERENCE

AS AN ADVANTAGE TO OPTICAL COMMUNICATION

Answer 4

EXTERNAL ELECTRICAL NOISE AND LIGHTING DO NOT EFFECT ENERGY IN A FIBER OPTIC STRAND.

HOWEVER, THIS IS TRUE ONLY FOR THE OPTICAL STRANDS, NOT THE METALLIC CABLE COMPONENTS OR CONNECTING ELECTONICS.

Question 5

ELIMINATION OF CROSSTALK

AS AN ADVANTAGE OF

OPTICAL COMMUNICATION

Answer 5

The light in one glass fiber does not interfere with, nor is it suscepptible to, the light in an adjacent fiber. Recall that crosstalk results from the electromagnetic coupling between two adjacent copper wires.

Question 6

LOWER SIGNAL ATTENUATION THAN OTHER PROPAGATION SYSTEMS

BEING AN ADVANTAGE OF OPTICAL COMMUNICATION

Answer 6

Typical attenuation of 1GHz bandwith signal for optical fibers is 0.03db per 100ft compared to 4.0 dB for RG-58U coaxial

Question 7

LOWER COST

AS AN ADVANTAGE

OF OPTICAL COMMUNICATION

Answer 7

Optical fiber cost are continuing to decline. The cost of many systems are declining with the use of fiber, and that trend is accelerating.

Question 8

SAFETY

AS AN ADVANTAGE OF OPTIACL COMMUNICATION

Answer 8

In many wired systems, the potential hazard of short circuits requires precautionary designs. Additionaly, the dielectric nature of optic fibers elimnates the spark hazzard.

Question 9

• CORROSION*
• AS AN ADVANTAGE OF OPTICAL COMMUNICATION*

Answer 9

Given that glass is basically inert, the corrosive effects of certain environments are not a problem

Question 10

SECURITY

AS AN ADVANTAGE OF OPTICAL COMMUNICATION.

Answer 10

due to its immunity to and from electromagnetic coupling and radiation, optical fiber can be used in most secure environments. Although it can be intercepted or tapped, it is very difficult to do so.

Question 11

SPEED OF LIGHT IN FREE SPACE

Answer 11

3 X 10⁸ m / s

** is reduced in other media, including fiber optic cables

Question 12

MULTI MODE FIBER

Answer 12

850 AND 1310 nm

nano meters

Fibers that support many wave guide modes

Question 13

SINGLE MODE FIBER

Answer 13

1310 AND 1550 nm

nano meters

Fiber cable with core diameters of about 7 - 10 nm, light follows a sigle path

AKA mono mode

used to minimize pulse depression effects is to make the core extremely small

Typically used with higher power, highly directional modualated light sources such as a laser.

Question 14

CLADDING

Answer 14

Meterial surrounding the core, which must have a lower index of refraction to keep the light in the core.

Almost always glass sometimes plastic

Question 15

2 KEY DISTANCE LIMITING PARAMETERS IN FIBER OPTIC TRANSMISSION

Answer 15

Attenuation

and

Dispersion

Question 16

ATTENUATION

Answer 16

The loss of power introduced by the fiber.

This loss accumualtes as the light is propagated through the fiber strand

The loss is expressed in dB/km *decibals per kilometer

The loss or attenuation of a signal is due to a combination of 4 factors Scattering. Absorption, Macrobending, Microbending.

Question 17

SCATTERING

Answer 17

Primary loss factor over the three wavelength ranges.

Accounts for 96% of the loss and is the basis of the attenuation curves and values.

AKA Rayleigh scattering

Caused by refractive index fluctuations

Decreses as wavelength increases

Question 18

ABSORPTION

Answer 18

Second loss factor, a composite of light interaction with the atomic structure of glass.

Involves the conversion of optical power to heat

Question 19

MACROBENDING

Answer 19

LOSS DUE TO LIGHT BREAKING UP AND ESCAPING INTO THE CLADDING

Question 20

MICRO BENDING

Answer 20

LOSS CAUSED BY VERY SMALL MECHANICAL DEFLECTIONS AND STRESS ON THE FIBER

TOO MUCH FORCE BEING APLLIED TO THE CABLE

TOO TIGHT TIE WRAPS

Question 21

DISPERSION

OR

PULSE BROADENING

Answer 21

Broading of a light pulse as it propagates through the fiber strand

Question 22

ISOLATOR

Answer 22

AN INLINE PASSIVE DEVICE THAT ALLOWS OPTICAL POWER TO FLOW ONLY IN ONE DIRECTION

Question 23

ATTENUATORS

Answer 23

USED TO REDUCE TEH RECEIVED SIGNAL LEVEL

AVAILABLE IN FIXED AND VARIABLE CONFIGS

Question 24

BRANCHING DEVICESTS

Answer 24

USED IN SIMPLEX SYSTEMS WHER A SINGLE OPTICAL SIGNAL IS DIVIDED AND SENT TO SEVERAL RECIEVERS SUCH AS POINT TO MULTIPOINT DATA DISTRIBUTION SYS

Question 25

SPLITTERS

Answer 25

USED TO SPLIT OR DIVIDE TEH OPTICAL SIGNAL FOR DISTRIBUTION TO ANY NUMBER OF PLACES

Question 26

WAVELENGTH DIVISION MULTIPLEXERS

Answer 26

COMBINE

OR DIVIDE TWO OR MORE OPTICAL SIGNALS EACH HAVING A DIFFERENT WAVELENGTH

AKA OPTIACL BEAM SPLITTERS

Question 27

OPTICAL LINE AMPLIFIRES

Answer 27

ANALOG AMPLIFIERS. PLACEMENT CAN BE AT THE OPTICAL TRANSMITTER OUTPUT MIDSPAN OR NEAR RECIEVER

Question 28

FUSION SPLICING

Answer 28

A LONG TERM

METHOD WHERE TWO FIBERS ARE FUSED OR WELDED TOGETHER

Question 29

MECHANICAL SPLICES

Answer 29

TWO FIBERS JOINED TOGETHER WITH AN AIR GAP, THEREBY REQUIRING AN INDEX MATCHING GEL TO PROVIDE A GOOD SPLICE

Question 30

FTTC

FIBER TO THE CURB

Answer 30

PROVIDES HIGH BANDWITH TOA LOCATION PROXIMITY TO THE HOME AND PROVIDES A HIGH SPEED DATA LINK VIA COPPER TWISTED PAIR USING VDSL

COST EFFECTIVE WAY TO PROVIDE LARGE BANDWITH AT HOME

Question 31

FFTH

Answer 31

FIBER TO THE HOME

PROVIDES UNLIMITED BANDWITH TO THE HOME HOWEVER THE KEY TO ITS SUCCESS IS THE DEVELOPMENT OF LOW COST OPTICAL TO ELECTRONIC CONVERTER

Question 32

BACKBONE

Answer 32

MAIN FIBER DISTRIBUTION

BULD OF DATA TRANSFERS HERE