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| author | kinitrupti | 2017-05-12 18:40:35 +0530 |
|---|---|---|
| committer | kinitrupti | 2017-05-12 18:40:35 +0530 |
| commit | d36fc3b8f88cc3108ffff6151e376b619b9abb01 (patch) | |
| tree | 9806b0d68a708d2cfc4efc8ae3751423c56b7721 /Optical_Fiber_Communication/Chapter9.ipynb | |
| parent | 1b1bb67e9ea912be5c8591523c8b328766e3680f (diff) | |
| download | Python-Textbook-Companions-d36fc3b8f88cc3108ffff6151e376b619b9abb01.tar.gz Python-Textbook-Companions-d36fc3b8f88cc3108ffff6151e376b619b9abb01.tar.bz2 Python-Textbook-Companions-d36fc3b8f88cc3108ffff6151e376b619b9abb01.zip | |
Revised list of TBCs
Diffstat (limited to 'Optical_Fiber_Communication/Chapter9.ipynb')
| -rwxr-xr-x | Optical_Fiber_Communication/Chapter9.ipynb | 1146 |
1 files changed, 0 insertions, 1146 deletions
diff --git a/Optical_Fiber_Communication/Chapter9.ipynb b/Optical_Fiber_Communication/Chapter9.ipynb deleted file mode 100755 index 367cadc1..00000000 --- a/Optical_Fiber_Communication/Chapter9.ipynb +++ /dev/null @@ -1,1146 +0,0 @@ -{
- "metadata": {
- "name": "",
- "signature": "sha256:e11123ba8b6bbada16d8c62d198839756136e69c9f0cc93a98384db776536508"
- },
- "nbformat": 3,
- "nbformat_minor": 0,
- "worksheets": [
- {
- "cells": [
- {
- "cell_type": "heading",
- "level": 1,
- "metadata": {},
- "source": [
- "Chapter 9 : Optical Fiber System-I"
- ]
- },
- {
- "cell_type": "heading",
- "level": 1,
- "metadata": {},
- "source": [
- "Example 1: PgNo-424"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Initialisation of variables\n",
- "e_c=550.0 # number of electron collected\n",
- "p=800.0 # number of photon incident\n",
- "n=e_c/p # quantum efficiency\n",
- "eq=1.602*math.pow(10,-19)# charge\n",
- "h=6.626*math.pow(10,-34)# plank constant\n",
- "c=3*math.pow(10,8)# speed of light in m/s\n",
- "y=1.3*math.pow(10,-6) #wavelength in m\n",
- "R=(n*eq*y)/(h*c)# responsivity in A/W\n",
- "\n",
- "# Results\n",
- "print ('%s %.2f %s' %(\" The responsivity = \",R,\"Amp/Watt\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The responsivity = 0.72 Amp/Watt\n"
- ]
- }
- ],
- "prompt_number": 31
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 2: PgNo-427"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable initialisation\n",
- "eq=1.602*math.pow(10,-19)# charge\n",
- "h=6.626*math.pow(10,-34)# plank constant\n",
- "c=3*math.pow(10,8)# speed of light in m/s\n",
- "y=0.85*math.pow(10,-6) # wavelength in m\n",
- "R=0.274 # responsivity in A/W\n",
- "n=(R*h*c)/(eq*y) # quantum efficiency\n",
- "n1=n*100 # % of quantum efficiency\n",
- "# Results\n",
- "print ('%s %.2f %s' %(\" The quantum efficiency = \",n1,\"%\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The quantum efficiency = 40.00 %\n"
- ]
- }
- ],
- "prompt_number": 32
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 3: PgNo-429"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable declaration\n",
- "e_c=1.0 # number of electron collected\n",
- "p=3.0 # number of photon incident\n",
- "n=e_c/p # quantum efficiency\n",
- "eq=1.602*math.pow(10,-19) # charge\n",
- "h=6.626*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "y=0.8*math.pow(10,-6) # wavelength in m\n",
- "Eg=(h*c)/y # band gap energy in J\n",
- "R=(n*eq*y)/(h*c)# responsivity in A/W\n",
- "Po=math.pow(10,-7) # in W\n",
- "Ip=R*Po # output photo current\n",
- "\n",
- "# Results\n",
- "print ('%s %.2f %s' %(\" The quantum efficiency = \",n*100,\"%\"))\n",
- "print ('%s %.2f %s' %(\"\\n band gap energy = \",Eg*pow(10,20),\"*10^-20 J\"))\n",
- "print ('%s %.2f %s' %(\"\\n The output photo current = \",Ip*pow(10,9),\"nA\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The quantum efficiency = 33.33 %\n",
- "\n",
- " band gap energy = 24.85 *10^-20 J\n",
- "\n",
- " The output photo current = 21.49 nA\n"
- ]
- }
- ],
- "prompt_number": 33
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 4: PgNo-432"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable initialisation\n",
- "n=0.50 # quantum efficiency\n",
- "eq=1.602*math.pow(10,-19)# charge\n",
- "h=6.626*math.pow(10,-34)# plank constant\n",
- "c=3*math.pow(10,8)# speed of light in m/s\n",
- "y=0.85*math.pow(10,-6) # wavelength in m\n",
- "R=(n*eq*y)/(h*c)# responsivity in A/W\n",
- "Ip=math.pow(10,-6)# mean photo current\n",
- "Po=Ip/R # received optical power in W\n",
- "f=c/y\n",
- "re=(n*Po)/(h*f)\n",
- "rp=re/n # number of received photons\n",
- "\n",
- "# Results\n",
- "print ('%s %.2f %s' %(\" The responsivity = \",R,\"A/W\"))\n",
- "print ('%s %.2f %s' %(\"\\n The received optical power = \",Po*pow(10,6),\"uW\"))\n",
- "print ('%s %.2f %s' %(\"\\n The number of received photons = \",rp/pow(10,13),\"*10^13 photons/sec\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The responsivity = 0.34 A/W\n",
- "\n",
- " The received optical power = 2.92 uW\n",
- "\n",
- " The number of received photons = 1.25 *10^13 photons/sec\n"
- ]
- }
- ],
- "prompt_number": 34
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 5: PgNo-435"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable initialisation\n",
- "h=6.626*math.pow(10,-34)# plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "Eg=1.43 # in eV\n",
- "Eg1=Eg*1.602*math.pow(10,-19) # in J\n",
- "y=(h*c)/Eg1 # cut off wavelength in m\n",
- "# Results\n",
- "print ('%s %.2f %s' %(\" The cut off wavelength = \",y*pow(10,6),\"um\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The cut off wavelength = 0.87 um\n"
- ]
- }
- ],
- "prompt_number": 35
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 6: PgNo-437"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Initialisation of variables\n",
- "vd=2.5*math.pow(10,4)# carrier velocity in m/s\n",
- "w=30*math.pow(10,-6)# width in m\n",
- "Bm=vd/(2*math.pi*w)\n",
- "Tm=1/Bm # max response time in sec\n",
- "Tm1=Tm*math.pow(10,9) # max response time in ns\n",
- "# Results\n",
- "print ('%s %.2f %s' %(\" The max response time = \",Tm1,\"ns\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The max response time = 7.54 ns\n"
- ]
- }
- ],
- "prompt_number": 36
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 7: PgNo-440"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable initialisation\n",
- "n=0.65 # quantum efficiency\n",
- "eq=1.602*math.pow(10,-19) # charge\n",
- "h=6.626*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "y=0.85*math.pow(10,-6)# wavelength in m\n",
- "R=(n*eq*y)/(h*c)# responsivity in A/W\n",
- "Po=0.35*math.pow(10,-6) # in W\n",
- "Ip=R*Po # output photo current\n",
- "I=9*math.pow(10,-6) # output current in A\n",
- "M=I/Ip # multiplication factor\n",
- "M1=math.ceil(M)\n",
- "# Results\n",
- "print \" The multiplication factor = \",int(M1)"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The multiplication factor = 58\n"
- ]
- }
- ],
- "prompt_number": 37
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 8: PgNo-442"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable declaration\n",
- "n=0.50 # quantum efficiency\n",
- "eq=1.602*math.pow(10,-19) # charge\n",
- "h=6.626*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "Eg=1.5*math.pow(10,-19) # in J\n",
- "y=(h*c)/Eg # cut off wavelength in m\n",
- "f=c/y\n",
- "R=(n*eq)/(h*f) # responsivity in A/W\n",
- "Ip=2.7*math.pow(10,-6) # photo current in A\n",
- "Po=Ip/R # incident optical power in W\n",
- "Po1=Po*math.pow(10,6) # incident optical power in uW\n",
- "\n",
- "# results\n",
- "print ('%s %.2f %s' %( \" The cut off wavelength = \",y*pow(10,6),\"um\"))\n",
- "print ('%s %.2f %s' %(\"\\n The responsivity = \",R,\"A/W \"))\n",
- "print ('%s %.2f %s' %(\"\\n The incident optical power = \",Po1,\"uW\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The cut off wavelength = 1.33 um\n",
- "\n",
- " The responsivity = 0.53 A/W \n",
- "\n",
- " The incident optical power = 5.06 uW\n"
- ]
- }
- ],
- "prompt_number": 38
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 9: PgNo-445"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "#Variable declaration\n",
- "n=0.15 # quantum efficiency\n",
- "eq=1.6*math.pow(10,-19) # charge\n",
- "h=6.63*math.pow(10,-34)# plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "y=0.85*math.pow(10,-6) # cut off wavelength in m\n",
- "f=c/y # frequency in Hz\n",
- "R=(n*eq)/(h*f) # responsivity in A/W\n",
- "# Results\n",
- "print ('%s %.3f %s' %(\" The responsivity = \",R,\"A/W\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The responsivity = 0.103 A/W\n"
- ]
- }
- ],
- "prompt_number": 39
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 10: PgNo-448"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable initialisation\n",
- "Iph=75*math.pow(10,-6) # output photocurrent in A\n",
- "y=0.85 # operating wavelength in um\n",
- "Pie=750*math.pow(10,-6) # incident optical power in uW\n",
- "R=Iph/Pie # responsivity in A/W\n",
- "n=1.24*R/y # external quantum efficiency\n",
- "n1=n*100 # percentage of external quantum efficiency\n",
- "\n",
- "# Results\n",
- "print ('%s %.2f %s' %(\" The responsivity = \",R,\"A/W\"))\n",
- "print ('%s %.2f %s' %(\"\\n The external quantum efficiency = \",n1,\"%\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The responsivity = 0.10 A/W\n",
- "\n",
- " The external quantum efficiency = 14.59 %\n"
- ]
- }
- ],
- "prompt_number": 40
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 11: PgNo-451"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable initialisation\n",
- "Vs=math.pow(10,5) # saturation in m/s\n",
- "W=7*math.pow(10,-6) # depletion layer width in m\n",
- "tr=W/Vs # transit time in sec\n",
- "\n",
- "# Results\n",
- "print ('%s %.1f %s' %(\" The transit time = \",tr*pow(10,12),\"ps\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The transit time = 70.0 ps\n"
- ]
- }
- ],
- "prompt_number": 41
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 12: PgNo-454"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable initialisation\n",
- "Vs=3*math.pow(10,4)# saturation in m/s\n",
- "W=25*math.pow(10,-6) # depletion layer width in m\n",
- "tr=W/Vs # transit time in sec\n",
- "f=0.35/tr # max 3 dB bandwidth Hz\n",
- "f1=f/math.pow(10,6) # max 3 dB bandwidth Hz\n",
- "\n",
- "# results\n",
- "print ('%s %.f %s' %(\" The max 3 dB bandwidth = \",f1,\"MHz\"))\n",
- "print (\"\\n The answer is wrong in the textbook \")"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The max 3 dB bandwidth = 420 MHz\n",
- "\n",
- " The answer is wrong in the textbook \n"
- ]
- }
- ],
- "prompt_number": 42
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 13: PgNo-456"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# variable initialisation\n",
- "Vs=3*math.pow(10,4) # saturation in m/s\n",
- "W=25*math.pow(10,-6) # depletion layer width in m\n",
- "E=10.5*math.pow(10,-11) # in F/m\n",
- "RL=15*math.pow(10,6) # load resister in ohm\n",
- "A=0.25*math.pow(10,-6) # area in m^2\n",
- "tr=W/Vs # transit time in sec\n",
- "Cj=E*A/W # junction capacitance in F\n",
- "t=RL*Cj # time constant in sec\n",
- "\n",
- "# Results\n",
- "print ('%s %.3f %s' %(\" The transit time = \",tr*pow(10,9),\"ns\"))\n",
- "print ('%s %.2f %s' %(\"\\n The junction capacitance = \",Cj*pow(10,12),\"pF\"))\n",
- "print ('%s %.2f %s' %(\"\\n The time constant = \",t*pow(10,6),\"us\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The transit time = 0.833 ns\n",
- "\n",
- " The junction capacitance = 1.05 pF\n",
- "\n",
- " The time constant = 15.75 us\n"
- ]
- }
- ],
- "prompt_number": 43
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 14: PgNo-459"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Initialisation of variables\n",
- "Eg1=1.12 # band gap for Si in eV\n",
- "Eg2=0.667 # band gap for Ge in eV\n",
- "y_si=1.24/Eg1 # cut off wavelength for Si in um\n",
- "y_he=1.24/Eg2 # cut off wavelength for Ge in um\n",
- "\n",
- "# Results\n",
- "print ('%s %.3f %s' %(\" The cut off wavelength for Si = \",y_si,\"um\"))\n",
- "print ('%s %.3f %s' %(\"\\n The cut off wavelength for Ge = \",y_he,\"um\"))\n"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The cut off wavelength for Si = 1.107 um\n",
- "\n",
- " The cut off wavelength for Ge = 1.859 um\n"
- ]
- }
- ],
- "prompt_number": 44
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 15: PgNo-463"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# variable declaration\n",
- "n=0.50 # quantum efficiency\n",
- "eq=1.6*math.pow(10,-19)# charge\n",
- "h=6.626*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "y=0.9*math.pow(10,-6) # wavelength in m\n",
- "R=(n*eq*y)/(h*c) # responsivity in A/W\n",
- "Ip=math.pow(10,-6) # mean photo current\n",
- "Po=Ip/R # received optical power in W\n",
- "f=c/y\n",
- "re=(n*Po)/(h*f)\n",
- "rp=re/n # number of received photons\n",
- "\n",
- "# Results\n",
- "print ('%s %.2f %s' %(\" The responsivity = \",R,\"A/W\"))\n",
- "print ('%s %.2f %s' %(\"\\n The received optical power = \",Po*pow(10,6),\"uW\"))\n",
- "print ('%s %.2f %s' %(\"\\n The number of received photons = \",rp/pow(10,13),\"*10^13 photons/sec\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The responsivity = 0.36 A/W\n",
- "\n",
- " The received optical power = 2.76 uW\n",
- "\n",
- " The number of received photons = 1.25 *10^13 photons/sec\n"
- ]
- }
- ],
- "prompt_number": 45
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 16: PgNo-466"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Initialisation of variables\n",
- "R=0.40 # Responsivity in A/W\n",
- "m=100*math.pow(10,-6) # incident flux in W/m-m\n",
- "A=2 # area in m-m\n",
- "Po=m*A # incident power in W\n",
- "Ip=R*Po # photon current in A\n",
- "\n",
- "# Results\n",
- "print ('%s %.f %s' %(\" The photon current = \",Ip*math.pow(10,6),\"uA\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The photon current = 80 uA\n"
- ]
- }
- ],
- "prompt_number": 46
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 17: PgNo-470"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable declaration\n",
- "n=0.65 # quantum efficiency\n",
- "eq=1.602*math.pow(10,-19) # charge\n",
- "h=6.626*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "Eg=1.5*math.pow(10,-19) # in J\n",
- "y=(h*c)/Eg # cut off wavelength in m\n",
- "f=c/y\n",
- "R=(n*eq)/(h*f) # responsivity in A/W\n",
- "Ip=2.5*math.pow(10,-6) # photo current in A\n",
- "Po=Ip/R # incident optical power in W\n",
- "Po1=Po*math.pow(10,6) # incident optical power in uW\n",
- "\n",
- "# Results\n",
- "print ('%s %.2f %s' %(\" The cut off wavelength = \",y*math.pow(10,6),\"um\"))\n",
- "print ('%s %.2f %s' %(\"\\n The responsivity = \",R,\"A/W\"))\n",
- "print ('%s %.2f %s' %(\"\\n The incident optical power = \",Po1,\"uW\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The cut off wavelength = 1.33 um\n",
- "\n",
- " The responsivity = 0.69 A/W\n",
- "\n",
- " The incident optical power = 3.60 uW\n"
- ]
- }
- ],
- "prompt_number": 47
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 18: PgNo-472"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable declaration\n",
- "h=6.626*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "Eg=1.43 # in eV\n",
- "Eg1=Eg*1.602*math.pow(10,-19) # in J\n",
- "y=(h*c)/Eg1 # cut off wavelength in m\n",
- "\n",
- "# Results\n",
- "print ('%s %.3f %s' %(\" The cut off wavelength = \",y*math.pow(10,6),\"um\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The cut off wavelength = 0.868 um\n"
- ]
- }
- ],
- "prompt_number": 48
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 19: PgNo-474"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable declaration\n",
- "n=0.45 # quantum efficiency\n",
- "h=6.62*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "y=1.2*math.pow(10,-6) # cut off wavelength in m\n",
- "Ic=20*math.pow(10,-6) # collector current in A\n",
- "Po=120*math.pow(10,-6)# incident optical power in W\n",
- "eq=1.602*math.pow(10,-19)# charge\n",
- "Go=(h*c*Ic)/(y*Po*eq) # optical gain\n",
- "h_e=Go/n # common emitter gain\n",
- "\n",
- "# Results\n",
- "print ('%s %.3f ' %(\" The optical gain = \",Go))\n",
- "print ('%s %.3f ' %(\"\\n The common emitter gain = \",h_e))\n"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The optical gain = 0.172 \n",
- "\n",
- " The common emitter gain = 0.383 \n"
- ]
- }
- ],
- "prompt_number": 49
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 20: PgNo-477"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Initialisation of variables\n",
- "n=0.5 # quantum efficiency\n",
- "eq=1.602*math.pow(10,-19) # charge\n",
- "h=6.626*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "y=1.3*math.pow(10,-6) # wavelength in m\n",
- "R=(n*eq*y)/(h*c)# responsivity in A/W\n",
- "Po=0.4*math.pow(10,-6) # in W\n",
- "Ip=R*Po # output photo current\n",
- "I=8*math.pow(10,-6) # output current in A\n",
- "M=I/Ip # multiplication factor\n",
- "\n",
- "# Results\n",
- "print \" The multiplication factor = \",int(M)"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The multiplication factor = 38\n"
- ]
- }
- ],
- "prompt_number": 50
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 21: PgNo-481"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Initialisation of variables\n",
- "n=0.85 # quantum efficiency\n",
- "eq=1.6*math.pow(10,-19) # charge\n",
- "h=6.625*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "y=0.9*math.pow(10,-6) # wavelength in m\n",
- "R=(n*eq*y)/(h*c)# responsivity in A/W\n",
- "Po=0.6*math.pow(10,-6) # in W\n",
- "Ip=R*Po # output photo current\n",
- "I=10*math.pow(10,-6) # output current in A\n",
- "M=I/Ip # multiplication factor\n",
- "\n",
- "# Results\n",
- "print \" The multiplication factor = \",int(M)"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The multiplication factor = 27\n"
- ]
- }
- ],
- "prompt_number": 51
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 22: PgNo-483"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable initialisation\n",
- "e_c=1.2*math.pow(10,11) # number of electron collected\n",
- "p=2*math.pow(10,11) # number of photon incident\n",
- "n=e_c/p # quantum efficiency\n",
- "eq=1.602*math.pow(10,-19) # charge\n",
- "h=6.626*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "E=1.5*math.pow(10,-19) # energy in J\n",
- "\n",
- "# Calculations\n",
- "y=(h*c)/E # wavelength in m\n",
- "R=(n*eq*y)/(h*c) # responsivity in A/W\n",
- "Ip=2.6*math.pow(10,-6) # photocurrent in A\n",
- "Po=Ip/R # incident optical power in W\n",
- "\n",
- "# Results\n",
- "print ('%s %.2f %s' %(\" The quantum efficiency = \",n*100,\"%\"))\n",
- "print ('%s %.2f %s' %(\"\\n The wavelength = \",y*pow(10,6),\"um\"))\n",
- "print ('%s %.2f %s' %(\"\\n The responsivity = \",R,\"Amp/Watt\"))\n",
- "print ('%s %.2f %s' %(\"\\n The incident optical power = \",Po*math.pow(10,6),\"uW\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The quantum efficiency = 60.00 %\n",
- "\n",
- " The wavelength = 1.33 um\n",
- "\n",
- " The responsivity = 0.64 Amp/Watt\n",
- "\n",
- " The incident optical power = 4.06 uW\n"
- ]
- }
- ],
- "prompt_number": 52
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 23: PgNo-485"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable initialisation\n",
- "n=0.40 # quantum efficiency\n",
- "eq=1.602*math.pow(10,-19) # charge\n",
- "h=6.626*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "y=1.35*math.pow(10,-6) # wavelength in m\n",
- "R=(n*eq*y)/(h*c) # responsivity in A/W\n",
- "Po=0.2*math.pow(10,-6) # in W\n",
- "Ip=R*Po # output photo current\n",
- "I=4.9*math.pow(10,-6) # output current in A\n",
- "M=I/Ip # multiplication factor\n",
- "\n",
- "# Results\n",
- "print \" The multiplication factor = \",int(M)"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The multiplication factor = 56\n"
- ]
- }
- ],
- "prompt_number": 53
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 24: PgNo-489"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable initialisation\n",
- "n=0.55 # quantum efficiency\n",
- "eq=1.6*math.pow(10,-19) # charge\n",
- "h=6.626*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "y=0.85*math.pow(10,-6) # wavelength in m\n",
- "R=(n*eq*y)/(h*c) # responsivity in A/W\n",
- "Ip=2*math.pow(10,-6) # mean photo current\n",
- "Po=Ip/R # received optical power in W\n",
- "re=(n*Po*y)/(h*c) # number of received photons\n",
- "\n",
- "# Results\n",
- "print ('%s %.3f %s' %(\" The responsivity = \",R,\"A/W\"))\n",
- "print ('%s %.3f %s' %(\"\\n The received optical power = \",Po*math.pow(10,6),\"uW\"))\n",
- "print ('%s %.2f %s' %(\"\\n The number of received photons = \",re/math.pow(10,13),\"*10^13 photons/sec\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The responsivity = 0.376 A/W\n",
- "\n",
- " The received optical power = 5.315 uW\n",
- "\n",
- " The number of received photons = 1.25 *10^13 photons/sec\n"
- ]
- }
- ],
- "prompt_number": 54
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 25: PgNo-494"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable declaration\n",
- "h=6.625*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8) # speed of light in m/s\n",
- "n=1 # quantum efficiency\n",
- "eq=1.602*math.pow(10,-19) # charge\n",
- "E=1.3*math.pow(10,-19) # energy in J\n",
- "y=(h*c)/E # wavelength in m\n",
- "M=18 # multiplication factor\n",
- "rp=math.pow(10,13) # no. of photon per sec\n",
- "Po=rp*E # output power in w\n",
- "Ip=(n*Po*eq)/E # output photocurrent in A\n",
- "I=M*Ip # photocurrent in A\n",
- "\n",
- "# Results\n",
- "print ('%s %.3f %s' %(\" The wavelength = \",y*math.pow(10,6),\"um\"))\n",
- "print ('%s %.1f %s' %(\"\\n The output power = \",Po*math.pow(10,6),\"uW\"))\n",
- "print ('%s %.3f %s' %(\"\\n The photocurrent = \",I*math.pow(10,6),\"uA\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The wavelength = 1.529 um\n",
- "\n",
- " The output power = 1.3 uW\n",
- "\n",
- " The photocurrent = 28.836 uA\n"
- ]
- }
- ],
- "prompt_number": 55
- },
- {
- "cell_type": "heading",
- "level": 2,
- "metadata": {},
- "source": [
- "Example 26: PgNo-497"
- ]
- },
- {
- "cell_type": "code",
- "collapsed": false,
- "input": [
- "import math\n",
- "\n",
- "# Variable declaration\n",
- "e_c=2*math.pow(10,10) # number of electron collected\n",
- "p=5*math.pow(10,10) # number of photon incident\n",
- "n=e_c/p # quantum efficiency\n",
- "eq=1.602*math.pow(10,-19) # charge\n",
- "h=6.626*math.pow(10,-34) # plank constant\n",
- "c=3*math.pow(10,8)# speed of light in m/s\n",
- "y=0.85*math.pow(10,-6) # wavelength in m\n",
- "y1=0.85 # wavelength in um\n",
- "Eg=(h*c)/y # bandgap energy in J\n",
- "Eg1=1.24/y1 # bandgap energy in terms of eV\n",
- "Po=10*math.pow(10,-6) # incident power in W\n",
- "Ip=(n*eq*Po)/Eg # mean output photocurrent in A\n",
- "\n",
- "# Results\n",
- "print ('%s %.2f %s' %(\" The quantum efficiency = \",n*100,\"%\"))\n",
- "print ('%s %.3f %s' %(\"\\n The bandgap energy = \",Eg*math.pow(10,19),\"*10^-19 J\"))\n",
- "print ('%s %.2f %s' %(\"\\n The bandgap energy = \",Eg1,\"eV\"))\n",
- "print ('%s %.3f %s' %(\"\\n The mean output photocurrent = \",Ip*math.pow(10,6),\"uA\"))"
- ],
- "language": "python",
- "metadata": {},
- "outputs": [
- {
- "output_type": "stream",
- "stream": "stdout",
- "text": [
- " The quantum efficiency = 40.00 %\n",
- "\n",
- " The bandgap energy = 2.339 *10^-19 J\n",
- "\n",
- " The bandgap energy = 1.46 eV\n",
- "\n",
- " The mean output photocurrent = 2.740 uA\n"
- ]
- }
- ],
- "prompt_number": 56
- }
- ],
- "metadata": {}
- }
- ]
-}
\ No newline at end of file |