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author | tslee | 2014-11-27 17:17:59 +0530 |
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committer | tslee | 2014-11-27 17:17:59 +0530 |
commit | 7b78be04fe05bf240417e22f74b3fc22e7a77d19 (patch) | |
tree | 1875acbe01f3225bbfcc1024266dc96e515f3ea0 /Optical_Fiber_Communications_Principles_and_Practice/Chapter_10.ipynb | |
parent | 8048392490bd2efe0fdfa001945f663cba969841 (diff) | |
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diff --git a/Optical_Fiber_Communications_Principles_and_Practice/Chapter_10.ipynb b/Optical_Fiber_Communications_Principles_and_Practice/Chapter_10.ipynb new file mode 100644 index 00000000..077ac9f5 --- /dev/null +++ b/Optical_Fiber_Communications_Principles_and_Practice/Chapter_10.ipynb @@ -0,0 +1,104 @@ +{ + "metadata": { + "name": "Chapter_10" + }, + "nbformat": 3, + "nbformat_minor": 0, + "worksheets": [ + { + "cells": [ + { + "cell_type": "heading", + "level": 1, + "metadata": {}, + "source": "Chapter 10 : Optical amplification, wavelength conversion and regeneration\n" + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": "Example 10.1, page 555" + }, + { + "cell_type": "code", + "collapsed": false, + "input": "import math\n\n#Variable declaration\nh=1.5*10**-6 #peak gain wavelength\ndelt=10**-9 #mode spacing\nl=300*10**-6 #length\nc=2.998*10**8 #speed of light\nr=0.09 #facet reflectivities\ngs=3.020\n\n#Calculation\nn=(h**2)/(2*delt*l) #refractive index\na=c/(math.pi*n*l)\nd=1-(math.sqrt(r)*gs)\nf=2*math.sqrt(math.sqrt(r)*gs)\nB=a*math.asin(d/f) #spectral bandwidth\n#Result\nprint'Refractive index of a medium = %.2f'%n\nprint'3dB spectral bandwidth = %.1f GHz'%(B*10**-9)", + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": "Refractive index of a medium = 3.75\n3dB spectral bandwidth = 4.2 GHz\n" + } + ], + "prompt_number": 1 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": "Example 10.3, page 562" + }, + { + "cell_type": "code", + "collapsed": false, + "input": "import math\n\n#Variable declaration\ngs=30 #gain in dB\ng=200 #net gain\nloge=0.434 #log(e)\ngs1=1000\nm=2.2 #mode no\nnsp=4 #spontaneous emission factor\nh1=6.626*10**-34 #plancks constant\nf=1.94*10**14\nB=1.0*10**12 #bandwidth\n\n#Calculation\nL=gs/(10*g*loge) #length of the device\nP=m*nsp*(gs1-1)*h1*f*B #noise power spectral density\n\n#Result\nprint'(a) Length of the device = %.2f mm'%(L*10**3)\nprint'(b) Noise power spectral density = %.2f mW'%(P*10**3)", + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": "(a) Length of the device = 34.56 mm\n(b) Noise power spectral density = 1.13 mW\n" + } + ], + "prompt_number": 2 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": "Example 10.4, page 580" + }, + { + "cell_type": "code", + "collapsed": false, + "input": "import math\n\n#Variable declaration\nGp=62.2 #parametric peak gain in dB\nlog=10*math.log10(0.25)\nPp=1.4 #signal power in watt\nL=500 #length in meter\nlog2=20*math.log10(2.7182818284)\n\n\n#Calculation\ny=(Gp-log)/(Pp*L*log2) #fiber nonlinear coefficient\nGp2=10*math.log10((y*Pp*L)**2) #parametric gain\n \n#Result\nprint'(a) Fiber nonlinear coefficient = %.2f x 10^-3 W^-1 km^-1'%(y*1000)\nprint'(b) Quadratic gain, Gp = %.2f dB'%(Gp2)", + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": "(a) Fiber nonlinear coefficient = 11.22 x 10^-3 W^-1 km^-1\n(b) Quadratic gain, Gp = 17.90 dB\n" + } + ], + "prompt_number": 3 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": "Example 10.5, page 589 " + }, + { + "cell_type": "code", + "collapsed": false, + "input": "import math\n\n#Variable declaration\npt=0.5*10**-3 #input signal power\ndpt=0.01*10**-6 #input signal power variation\nh=1.55*10**-6 #signal wavelength\na=-1 #linewidth enhancement factor\ndn=-1.2*10**-26 #differential refractive index\n\n#Calculation\ndelt=(-a*dpt)/(4*math.pi*pt) #frequency chirp\ndg=(4*math.pi*dn)/(h*a) #differential gain\n \n#Result\nprint'(a) Frequency chirp variation = %.2f MHz'%(delt*10**6)\nprint'(b) Differential gain = %.2f x10^-20 m^2'%(dg*10**20)", + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": "(a) Frequency chirp variation = 1.59 MHz\n(b) Differential gain = 9.73 x10^-20 m^2\n" + } + ], + "prompt_number": 4 + } + ], + "metadata": {} + } + ] +}
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