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EE 230: Optical Fiber Communication Lecture 17 From the movie Warriors of the Net System...
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Transcript of EE 230: Optical Fiber Communication Lecture 17 From the movie Warriors of the Net System...
![Page 1: EE 230: Optical Fiber Communication Lecture 17 From the movie Warriors of the Net System Considerations.](https://reader033.fdocuments.net/reader033/viewer/2022061618/55176f575503463e368b4bc7/html5/thumbnails/1.jpg)
EE 230: Optical Fiber Communication Lecture 17
From the movieWarriors of the Net
System Considerations
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Basic Network Topologies
![Page 3: EE 230: Optical Fiber Communication Lecture 17 From the movie Warriors of the Net System Considerations.](https://reader033.fdocuments.net/reader033/viewer/2022061618/55176f575503463e368b4bc7/html5/thumbnails/3.jpg)
Bitrate Distance Graph for various point to point link technologies
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System Design
• Determine wavelength, link distance, and bit-error rate
• Work out power budget
• Work out risetime budget
• Work out cost budget
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Power Budget Steps
• Start with BER and bit rate, determine B based on coding method
• B = 1/2RC gives the maximum load resistance R based on B and C
• Based on R and M, determine detector sensitivity (NEP), multiply by B1/2
• Add system margin, typically 6 dB, to determine necessary power at receiver
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Power budget steps, continued
• Add power penalties, if necessary, for extinction ratio, intensity noise (includes S/N degradation by amplifiers), timing jitter
• Add loss of fiber based on link distance• Include loss contributions from connections
and splices• End up with required power of transmitter, or
maximum length of fiber for a given transmitter power
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Power budget example
Imagine we want to set up a link operating at 1550 nm with a bit rate of 1 Gb/s using the RZ format and a BER of 10-9. We want to use a PIN photodiode, which at this wavelength should be InGaAs. The R0 for the diode is 0.9 A/W.
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Bandwidth required for bit rate
• For NRZ format, B=0.5 times bit rate
• For RZ format, B=bit rate
For this example, the bandwidth B is equal to the bit rate, 109 /s.
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Bandwidth limit
C=2 pF for this photodiode.
B = 1/2RC, so the load resistance R must be (2BC)-1 = 79.6
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Noise Equivalent Power (NEP)
Signal power where S/N=1Units are W/Hz1/2
In this case, M=1 and the dark current = 4 nA.
The factor outside the radical is 1/R0. We can thus determine the NEP, which is 5.1x10-7 W, which equals -33.0 dBm.
L
xD RM
kTMeI
e
hNEP
2
42
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Q Factor and BER
For our BER of 10-9, Q=6 and S/N=12
on
thon
off
offth VVVVQ
21
2
1 QerfBER
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Extinction ratio penalty
Extinction ratio rex=P0/P1
If our extinction ratio is 0.1, the penalty is 0.87 dB.
offonex
ex RP
r
rQ
2
1
1
ex
exex r
r
1
1log10
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Intensity noise penalty
rI=inverse of SNR of transmitted light
Since our S/N is 12, rI=0.83, which leads to a power penalty of 1.25 dB
221log10 QrII
II RPr
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Timing jitter penalty
Parameter B=fraction of bit period over which apparent clock time varies
If our jitter represents 10% of the bit period, the power penalty is 0.34 dB
22
83
4 Bb
2/2/1
2/1log10
222 Qbb
bJ
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Fiber attenuation
If the attenuation in the fiber is 0.2 dB/km and the link is 80 km long, the total loss in the fiber will be 16.0 dB
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Example results
• Minimum power required for receiver:
-33.0 dBm• Safety margin: 6.0 dB• Extinction ratio power penalty: 0.87 dB• S/N power penalty: 1.25 dB• Timing jitter power penalty: 0.34 dB• Fiber loss over 80 km: 16.0 dB• Total= minimum transmitter power=
-8.54 dBm=0.14 mW=140 W
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Further steps
Alternatively, previous data could be used with a fixed transmitter power to determine maximum length of a fiber link
If power budget does not add up, one can
• replace PIN photodiode with APD
• add an EDFA to the link
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Power Budget Example
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Risetime Budget
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Rise time budget components
• bit rate and coding format determine upper limit of rise time
• rise time of transmitter (from manufacturer; laser faster than LED)
• pulse spread due to dispersion• rise time of receiver (from manufacturer; PIN
faster than APD)
Rise time components are combined by taking the square root of sums of squares
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Upper limit for rise time
• For NRZ format, Tr=0.70/B
• For RZ format, Tr=0.35/B
In this case, choose RZ format. Tr must thus be less than or equal to 0.35/109 = 350 ps
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Group Velocity Dispersion-based rise time
Calculate from laser optical bandwidth if known, or from modulation rate:
In this case, D=17 ps/nm-km, L=80 km, and =0.016 nm, so tf=21.8 ps.
B
cc
cc 2
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Modal dispersion rise time
For multimode fiber, time spread due to modal dispersion is based on core index and fiber length L.
For step-index fiber:
For graded-index fiber:
1
2
2cn
NALt
31
4
8cn
NALt
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Total rise time
For this example, tMD=0, tTR=100 ps, tRC=0.5 ns, and tGVD= 21.8 ps as before. tr is therefore 510 ps, and the rise time budget does not meet the limit.
• Can use NRZ format• Use faster detector or transmitter• Use graded-index fiber for less dispersion
2222RCGVDMDTRr ttttt
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Computer Based Link Simulation
Computer Simulation is often used to model opticla links to account for the complex interaction between components and nonlinear effects
Commercial simulation tools are now available such as:
Linksim from RSoft
and the tools from VPI Systems
Fiber-Optic Communication Systems-G. Agrawal