{ "cells": [ { "cell_type": "markdown", "metadata": {}, "source": [ "# Chapter 3 - Bipolar Junction Transistor" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_1 Page No. 64" ] }, { "cell_type": "code", "execution_count": 1, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "Vcc = 15.00 volts\n", "VBB = 1.00 volts\n", "VBE = 0.70 volts\n", "resistance,RB = 5000.00 ohm\n", "resistance,RL = 650.00 ohm\n", "Gain,Bf = 200.00 \n", "IB =(VBB-VBE)/RB = 6.00e-05 ampere\n", "IC =IB*Bf= 0.01 ampere\n", "IE = IB+IC=0.01 ampere\n", "VCE =Vcc-IC*RL= 7.20 volts\n", "VCB = VCE-VBE=6.50 volts\n", "resistance,RB =(Vcc-VBE)/IB= 2.38e+05 ohm\n" ] } ], "source": [ "from __future__ import division \n", "Vcc=15\n", "print \"Vcc = %0.2f\"%(Vcc),\" volts\" #initialization\n", "VBB=1\n", "print \"VBB = %0.2f\"%(VBB),\" volts\" #initialization\n", "VBE=0.7\n", "print \"VBE = %0.2f\"%(VBE),\" volts\" #initialization\n", "RB=5*(10**3)\n", "print \"resistance,RB = %0.2f\"%(RB)+ \" ohm\" #initialization\n", "RL=650\n", "print \"resistance,RL = %0.2f\"%(RL)+ \" ohm\" #initialization\n", "Bf=200\n", "print \"Gain,Bf = %0.2f\"%(Bf)+ \" \" #initialization\n", "IB=(VBB-VBE)/RB #Formulae\n", "print \"IB =(VBB-VBE)/RB = %0.2e\"%(IB),\" ampere\" #calculation\n", "IC=IB*Bf #Formulae\n", "print \"IC =IB*Bf= %0.2f\"%(IC),\" ampere\"#calculation\n", "IE=IB+IC #Formulae\n", "print \"IE = IB+IC=%0.2f\"%(IE),\" ampere\"#calculation\n", "VCE=Vcc-IC*RL #Formulae\n", "print \"VCE =Vcc-IC*RL= %0.2f\"%(VCE),\" volts\" #calculation\n", "VCB=VCE-VBE #Formulae\n", "print \"VCB = VCE-VBE=%0.2f\"%(VCB),\" volts\"#calculation\n", "RB=(Vcc-VBE)/IB #Formulae\n", "print \"resistance,RB =(Vcc-VBE)/IB= %0.2e\"%(RB)+ \" ohm\" #calculation" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_2 Page No. 65" ] }, { "cell_type": "code", "execution_count": 2, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "Vbe1 = 0.03 volts\n", "Vbe2 = -0.03 volts\n", "ib1 = 2.00e-05 ampere\n", "ib2 = -2.00e-05 ampere\n", "IBQ = 6.00e-05 ampere\n", "ICP = 0.02 ampere\n", "ICR = 0.01 ampere\n", "VCEP = 5.00 volts\n", "VCER = 9.00 volts\n", "change_IC = 0.01 ampere\n", "change_VCE = 4.00 volts\n", "AV = 80.00 \n", "AI = 175.00 \n" ] } ], "source": [ "from __future__ import division \n", "Vbe1=0.025\n", "print \"Vbe1 = %0.2f\"%(Vbe1),\" volts\" # value of base-emitter voltage1\n", "Vbe2=(-0.025)\n", "print \"Vbe2 = %0.2f\"%(Vbe2),\" volts\" # value of base-emitter voltage2\n", "ib1=20*10**(-6)\n", "print \"ib1 = %0.2e\"%(ib1),\" ampere\" # value of base current1\n", "ib2=(-20*10**(-6))\n", "print \"ib2 = %0.2e\"%(ib2),\" ampere\"# value of base current2\n", "IBQ=60*10**(-6)\n", "print \"IBQ = %0.2e\"%(IBQ),\" ampere\" # operating point\n", "ICP=15.5*10**(-3)\n", "print \"ICP = %0.2f\"%(ICP),\" ampere\" # initialization\n", "ICR=8.5*10**(-3)\n", "print \"ICR = %0.2f\"%(ICR),\" ampere\" # initialization\n", "VCEP=5\n", "print \"VCEP = %0.2f\"%(VCEP),\" volts\" # value of collector-emitter voltage1\n", "VCER=9\n", "print \"VCER = %0.2f\"%(VCER),\" volts\" # value of collector-emitter voltage2\n", "change_IC=ICP-ICR #change in collector current\n", "print \"change_IC = %0.2f\"%(change_IC),\" ampere\"\n", "change_VCE=VCER-VCEP #change in collector voltage\n", "print \"change_VCE = %0.2f\"%(change_VCE),\" volts\" \n", "change_VBE=Vbe1-Vbe2\n", "change_IB=ib1-ib2\n", "AV=(change_VCE/change_VBE) #formulae voltage gain\n", "print \"AV = %0.2f\"%(AV),\" \"#voltage gain\n", "AI=change_IC/change_IB #formulae current gain\n", "print \"AI = %0.2f\"%(AI),\" \"" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_3 Page No. 68" ] }, { "cell_type": "code", "execution_count": 4, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "ICQ = 0.01 ampere\n", "B = 200.00 \n", "capacitance,Cbe = 1.00e-10 F \n", "VT = 0.03 volts\n", "gm =(ICQ/VT)= 0.46 A/V\n", "hie =(B/gm)= 433.33 ohm\n", "fT =((1/2)*(gm/Cbe)*(1/pi))= 7.35e+08 hertz\n" ] } ], "source": [ "from math import pi\n", "from __future__ import division \n", "ICQ=12*10**(-3)\n", "print \"ICQ = %0.2f\"%(ICQ),\" ampere\" # collector current\n", "B=200\n", "print \"B = %0.2f\"%(B),\" \" #BJT gain\n", "Cbe=100*10**(-12)# capacitance\n", "print \"capacitance,Cbe = %0.2e\"%(Cbe),\" F \"\n", "VT=26*10**(-3)\n", "print \"VT = %0.2f\"%(VT),\" volts\" # thermal voltage\n", "gm=(ICQ/VT) #transconductance\n", "print \"gm =(ICQ/VT)= %0.2f\"%(gm),\" A/V\"\n", "hie=B/gm #forward resistance hybrid parameter\n", "print \"hie =(B/gm)= %0.2f\"%(hie),\" ohm\"\n", "fT=((1/2)*(gm/Cbe)*(1/pi)) #unity gain frequency formulae\n", "print \"fT =((1/2)*(gm/Cbe)*(1/pi))= %0.2e\"%(fT),\" hertz\"" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_4 Page No. 71" ] }, { "cell_type": "code", "execution_count": 1, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "VCC = 20.00 volts\n", "RL= 5000.00 ohm\n", "RB = 9.65e+05 ohm\n", "VBE = 0.70 volts\n", "BF = 50.00 \n", "ICO = 1.00e-08 ampere\n", "Vi = 0.00e+00 volts\n", "IBQ = 2.00e-05 ampere\n", "ICQ =BF*IBQ= 1.00e-03 ampere\n", "VCEQ =VCC-ICQ*RL = 15.00 volts\n" ] } ], "source": [ "from __future__ import division \n", "VCC=20\n", "print \"VCC = %0.2f\"%(VCC),\" volts\" # collector supply voltage \n", "VBB=VCC\n", "RL=5*(10**3)\n", "print \"RL= %0.2f\"%(RL)+ \" ohm\" #resistance\n", "RB=965*(10**3)\n", "print \"RB = %0.2e\"%(RB)+ \" ohm\" #initialization base resistance\n", "VBE=(0.7)\n", "print \"VBE = %0.2f\"%(VBE),\" volts\" # value of base-emitter voltage\n", "BF=50\n", "print \"BF = %0.2f\"%(BF),\" \" #BJT gain\n", "ICO=10*10**(-9)\n", "print \"ICO = %0.2e\"%(ICO),\" ampere\" # collector reverse bias current\n", "Vi=0\n", "print \"Vi = %0.2e\"%(Vi),\" volts\" # value of input\n", "IBQ=(VCC-VBE)/RB #base current as operating point\n", "print \"IBQ = %0.2e\"%(IBQ),\" ampere\"\n", "ICQ=BF*IBQ #operating point (collector current)\n", "print \"ICQ =BF*IBQ= %0.2e\"%(ICQ),\" ampere\" # calculation\n", "VCEQ=VCC-ICQ*RL # collector-emitter voltage as operating point\n", "print \"VCEQ =VCC-ICQ*RL = %0.2f\"%(VCEQ),\" volts\" #calculation" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_5 Page No. 74" ] }, { "cell_type": "code", "execution_count": 2, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "BF1 = 100.00 \n", "VCC = 20.00 volts\n", "resistance,RL= 5.00e+03 ohm\n", "resistance,RB = 9.65e+05 ohm\n", "VBE = 0.70 volts\n", "ICO = 1.00e-08 ampere\n", "Vi = 0 volts\n", "IBQ = 2.00e-05 ampere\n", "ICQ1 =BF1*IBQ= 2.00e-03 ampere\n", "VCEQ1 =VCC-ICQ1*RL = 10.00 volts\n" ] } ], "source": [ "from __future__ import division \n", "BF1=100\n", "print \"BF1 = %0.2f\"%(BF1),\" \" #BJT gain\n", "VCC=20\n", "print \"VCC = %0.2f\"%(VCC),\" volts\" # collector supply voltage \n", "VBB=VCC\n", "RL=5*(10**3)\n", "print \"resistance,RL= %0.2e\"%(RL)+ \" ohm\" #initialization\n", "RB=965*(10**3)\n", "print \"resistance,RB = %0.2e\"%(RB)+ \" ohm\" #initialization\n", "VBE=(0.7)\n", "print \"VBE = %0.2f\"%(VBE),\" volts\" # value of base-emitter voltage\n", "ICO=10*10**(-9)\n", "print \"ICO = %0.2e\"%(ICO),\" ampere\" # collector reverse bias current\n", "Vi=0\n", "print \"Vi = %0.f\"%(Vi),\" volts\" # value of input\n", "IBQ=(VCC-VBE)/RB #base current as operating point\n", "print \"IBQ = %0.2e\"%(IBQ),\" ampere\"\n", "ICQ1=BF1*IBQ #operating point (collector current)\n", "print \"ICQ1 =BF1*IBQ= %0.2e\"%(ICQ1),\" ampere\" # calculation\n", "VCEQ1=VCC-ICQ1*RL # collector-emitter voltage as operating point\n", "print \"VCEQ1 =VCC-ICQ1*RL = %0.2f\"%(VCEQ1),\" volts\" #calculation" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_6 Page No. 75" ] }, { "cell_type": "code", "execution_count": 3, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "VBE2 = 0.50 volts\n", "VCC = 20.00 volts\n", "BF2 = 150.00 \n", "ICO2 = 5.00e-07 ampere\n", "RB = 9.65e+05 ohm\n", "RL= 5.00e+03 ohm\n", "IBQ2 = (VCC-VBE2)/RB=2.02e-05 ampere\n", "ICQ2 =BF2*IBQ2= 3.03e-03 ampere\n", "dICQ2 =BF2*ICO2= 7.50e-05 ampere\n", "ICQ3 =ICQ2+dICQ2= 3.11e-03 ampere\n", "VCEQ3 =VCC-ICQ3*RL = 4.47 volts\n" ] } ], "source": [ "from __future__ import division \n", "VBE2=(0.5)\n", "print \"VBE2 = %0.2f\"%(VBE2),\" volts\" # value of base-emitter voltage\n", "VCC=20\n", "print \"VCC = %0.2f\"%(VCC),\" volts\" # collector supply voltage \n", "BF2=150\n", "print \"BF2 = %0.2f\"%(BF2),\" \" #BJT gain\n", "ICO2=500*10**(-9)\n", "print \"ICO2 = %0.2e\"%(ICO2),\" ampere\" # collector reverse bias current\n", "RB=965*(10**3)\n", "print \"RB = %0.2e\"%(RB)+ \" ohm\" #initialization base resistance\n", "RL=5*(10**3)\n", "print \"RL= %0.2e\"%(RL)+ \" ohm\" # load resistance\n", "IBQ2=(VCC-VBE2)/RB #base current as operating point\n", "print \"IBQ2 = (VCC-VBE2)/RB=%0.2e\"%(IBQ2),\" ampere\"\n", "ICQ2=(BF2*IBQ2) #operating point (collector current)\n", "print \"ICQ2 =BF2*IBQ2= %0.2e\"%(ICQ2),\" ampere\" # \n", "dICQ2=BF2*ICO2 # increase in reverse bias current\n", "print \"dICQ2 =BF2*ICO2= %0.2e\"%(dICQ2),\" ampere\" # \n", "ICQ3=ICQ2+dICQ2\n", "print \"ICQ3 =ICQ2+dICQ2= %0.2e\"%(ICQ3),\" ampere\" # calculation\n", "VCEQ3=VCC-ICQ3*RL # collector-emitter voltage as operating point\n", "print \"VCEQ3 =VCC-ICQ3*RL = %0.2f\"%(VCEQ3),\" volts\" #calculation\n", "#NOTE: Calculated ans for VCEQ3=4.4695596 volts but in book it is given as 4.625volts(due to approximations done in) \n", " " ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_7 Page No. 76" ] }, { "cell_type": "code", "execution_count": 4, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "VCC = 20.00 volts\n", "resistance,RL= 5000.00 ohm\n", "resistance,R1 = 90000.00 ohm\n", "resistance,R2 = 10000.00 ohm\n", "resistance,Rc = 1000.00 ohm\n", "VBEmax = 0.70 volts\n", "VBEmin = 0.50 volts\n", "BFmax = 150.00 \n", "BFmin = 50.00 \n", "ICOmax = 5.00e-07 ampere\n", "ICOmin = 1.00e-08 ampere\n", "VBB = 2.00 volts\n", "RB = (R1*R2)/(R1+R2)=9000.00 ohm\n", "ICmin = 0.00 ampere\n", "VCEQmax =VCC-ICmin*RL = 14.58 volts\n", "ICmax = 1.41e-03 ampere\n", "VCEQmin =VCC-ICmax*RL = 12.95 volts\n", "change_IC= 3.28e-04 ampere\n" ] } ], "source": [ "from __future__ import division \n", "VCC=20\n", "print \"VCC = %0.2f\"%(VCC),\" volts\" # collector supply voltage \n", "RL=5*(10**3)\n", "print \"resistance,RL= %0.2f\"%(RL)+ \" ohm\" #initialization\n", "R1=90*(10**3)\n", "print \"resistance,R1 = %0.2f\"%(R1)+ \" ohm\" #initialization\n", "R2=10*(10**3)\n", "print \"resistance,R2 = %0.2f\"%(R2)+ \" ohm\" #initialization \n", "Rc=1*(10**3)\n", "print \"resistance,Rc = %0.2f\"%(Rc)+ \" ohm\" # resistance at collector\n", "VBEmax=(0.7)\n", "print \"VBEmax = %0.2f\"%(VBEmax),\" volts\" # maximum base-emitter voltage\n", "VBEmin=(0.5)\n", "print \"VBEmin = %0.2f\"%(VBEmin),\" volts\" # minimum base-emitter voltage\n", "BFmax=150\n", "print \"BFmax = %0.2f\"%(BFmax),\" \" #BJT gain maximum\n", "BFmin=50\n", "print \"BFmin = %0.2f\"%(BFmin),\" \" #BJT gain minimum\n", "ICOmax=500*10**(-9)\n", "print \"ICOmax = %0.2e\"%(ICOmax),\" ampere\" # maximum collector reverse bias current\n", "ICOmin=10*10**(-9)\n", "print \"ICOmin = %0.2e\"%(ICOmin),\" ampere\" # minimum collector reverse bias current\n", "VBB=(VCC*R2)/(R1+R2)\n", "print \"VBB = %0.2f\"%(VBB),\" volts\" # Base supply voltage \n", "RB=(R1*R2)/(R1+R2)\n", "print \"RB = (R1*R2)/(R1+R2)=%0.2f\"%(RB)+ \" ohm\" # eqivalent base resistance\n", "ICmin=((BFmin*(VBB-VBEmax)+(RB+Rc)*(1+BFmin)*ICOmin)/(RB+Rc*(1+BFmin))) # minimum collector current\n", "print \"ICmin = %0.2f\"%(ICmin),\" ampere\"\n", "VCEQmax=VCC-ICmin*RL # maximum collector-emitter voltage (d.c value)\n", "print \"VCEQmax =VCC-ICmin*RL = %0.2f\"%(VCEQmax),\" volts\" #calculation\n", "ICmax=((BFmax*(VBB-VBEmin)+(RB+Rc)*(1+BFmax)*ICOmax)/(RB+Rc*(1+BFmax))) # maximum collector current\n", "print \"ICmax = %0.2e\"%(ICmax),\" ampere\"\n", "VCEQmin=VCC-ICmax*RL # minimum collector-emitter voltage (d.c value)\n", "print \"VCEQmin =VCC-ICmax*RL = %0.2f\"%(VCEQmin),\" volts\" #calculation\n", "change_IC=ICmax-ICmin\n", "print \"change_IC= %0.2e\"%(change_IC),\" ampere\" # extreme variation in collector current\n", "# ERROR - NOTE: Extreme variation in collector current given in book is 0.397 mA but calculated correct ans is 0.3276 mA \n", " " ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_8 Page No. 79" ] }, { "cell_type": "code", "execution_count": 5, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "VCC = 20.00 volts\n", "RL= 2000.00 ohm\n", "R1 =R2= 100000.00 ohm\n", "VBE = 0.70 volts\n", "BF = 100.00 \n", "VBB = 10.00 volts\n", "RB = (R1*R2)/(R1+R2)=50000.00 ohm\n", "IC = 3.69e-03 ampere\n", "VE = 7.38 volts\n", "VB = 8.08 volts\n", "VCB = 11.92 volts\n" ] } ], "source": [ "from __future__ import division \n", "VCC=20\n", "print \"VCC = %0.2f\"%(VCC),\" volts\" # collector supply voltage \n", "RL=2*(10**3)\n", "print \"RL= %0.2f\"%(RL)+ \" ohm\" #resistance\n", "R1=100*(10**3)\n", "R2=R1\n", "print \"R1 =R2= %0.2f\"%(R1)+ \" ohm\" #resistance\n", "VBE=(0.7)\n", "print \"VBE = %0.2f\"%(VBE),\" volts\" # base-emitter voltage\n", "BF=100\n", "print \"BF = %0.2f\"%(BF),\" \" #BJT gain\n", "ICO=0\n", "VBB=(VCC*R2)/(R1+R2)\n", "print \"VBB = %0.2f\"%(VBB),\" volts\" # Base supply voltage \n", "RB=(R1*R2)/(R1+R2)\n", "print \"RB = (R1*R2)/(R1+R2)=%0.2f\"%(RB)+ \" ohm\" # eqivalent base resistance\n", "IC=((BF*(VBB-VBE))/(RB+RL*(1+BF))) # collector current\n", "print \"IC = %0.2e\"%(IC),\" ampere\"\n", "VE=IC*RL\n", "print \"VE = %0.2f\"%(VE),\" volts\" # emitter voltage\n", "VB=VBE+VE\n", "print \"VB = %0.2f\"%(VB),\" volts\" # base voltage\n", "VCB=VCC-VB\n", "print \"VCB = %0.2f\"%(VCB),\" volts\" # collector-base voltage\n", "#hence BJT in active region." ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_9 Page No. 84" ] }, { "cell_type": "code", "execution_count": 6, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "VCC = 5.00 volts\n", "RL= 250.00 ohm\n", "RB =25000.00 ohm\n", "VCS = 0.20 volts\n", "BF = 200.00 \n", "VBS = 0.80 volts\n", "VI = 5.00 volts\n", "VCON = 0.30 volts\n", "ICON = (VCC-VCON)/RL=0.02 ampere\n", "IBON = (ICON)/BF=9.40e-05 ampere\n", "IBS = (VI-VBS)/RB=1.68e-04 ampere\n", "ICS = (VCC-VCS)/RL=1.92e-02 ampere\n", "Bforced = ICS/IBS=114.29 \n" ] } ], "source": [ "from __future__ import division \n", "VCC=5\n", "print \"VCC = %0.2f\"%(VCC),\" volts\" # collector supply voltage \n", "RL=250\n", "print \"RL= %0.2f\"%(RL)+ \" ohm\" #initialization\n", "RB=25*10**(3)\n", "print \"RB =%0.2f\"%(RB)+ \" ohm\" # base resistance\n", "VCS=(0.2)\n", "print \"VCS = %0.2f\"%(VCS),\" volts\" # voltage\n", "BF=200\n", "print \"BF = %0.2f\"%(BF),\" \" #BJT gain\n", "VBS=(0.8)\n", "print \"VBS = %0.2f\"%(VBS),\" volts\" # base-emitter voltage for BJT switch\n", "VI=5\n", "print \"VI = %0.2f\"%(VI),\" volts\"# input voltage\n", "VCON=0.3\n", "print \"VCON = %0.2f\"%(VCON),\" volts\"\n", "ICON=(VCC-VCON)/RL\n", "print \"ICON = (VCC-VCON)/RL=%0.2f\"%(ICON),\" ampere\"#collector current for saturated BJT\n", "IBON=(ICON)/BF\n", "print \"IBON = (ICON)/BF=%0.2e\"%(IBON),\" ampere\"#Base current for saturated BJT\n", "IBS=(VI-VBS)/RB\n", "print \"IBS = (VI-VBS)/RB=%0.2e\"%(IBS),\" ampere\"#Base-emitter current for saturated BJT\n", "ICS=(VCC-VCS)/RL\n", "print \"ICS = (VCC-VCS)/RL=%0.2e\"%(ICS),\" ampere\"#Collector-emitter current for saturated BJT\n", "Bforced=ICS/IBS\n", "print \"Bforced = ICS/IBS=%0.2f\"%(Bforced),\" \" #BJT forced gain\n", "#IBS>>IBON hence BJT in saturation" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_10 Page No. 85" ] }, { "cell_type": "code", "execution_count": 7, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "TJmax= 175.00 degree celsius\n", "theta= 0.50 degree celsius/mW \n", "at 25 degree celsius,PDmax=(TJmax-25 )/theta = 300.00 mW \n", "at 75 degree celsius,PDmax2= (TJmax-75)/theta = 200.00 mW \n" ] } ], "source": [ "from __future__ import division \n", "TJmax=175\n", "print \"TJmax= %0.2f\"%(TJmax),\"degree celsius\" #maximum allowed junction temperature\n", "theta=0.5\n", "print \"theta= %0.2f\"%(theta),\"degree celsius/mW \" #thermal resistances b/w junction to ambient\n", "change_T=TJmax-25#temperature difference\n", "PDmax=change_T/theta\n", "print \"at 25 degree celsius,PDmax=(TJmax-25 )/theta = %0.2f\"%(PDmax)+ \" mW \" #maximum allowed power dissipation at TA=25 degree celsius\n", "change_T=TJmax-75\n", "PDmax2=change_T/theta\n", "print \"at 75 degree celsius,PDmax2= (TJmax-75)/theta = %0.2f\"%(PDmax2)+ \" mW \" #maximum allowed power dissipation at TA=75 degree celsius" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_11 Page No. 85" ] }, { "cell_type": "code", "execution_count": 8, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "TJmax= 175.00 degree celsius\n", "theta= 0.10 degree celsius/mW \n", "at 25 degree celsius,PDmax=(TJmax-25 )/theta = 1500.00 mW \n", "at 75 degree celsius,PDmax= (TJmax-75)/theta = 1000.00 mW \n" ] } ], "source": [ "from __future__ import division \n", "TJmax=175\n", "print \"TJmax= %0.2f\"%(TJmax),\" degree celsius\" #maximum allowed junction temperature\n", "theta=0.1\n", "print \"theta= %0.2f\"%(theta),\" degree celsius/mW \" #thermal resistances b/w junction to ambient\n", "change_T=TJmax-25 #temperature difference\n", "PDmax=change_T/theta\n", "print \"at 25 degree celsius,PDmax=(TJmax-25 )/theta = %0.2f\"%(PDmax)+ \" mW \" #maximum allowed power dissipation at TA=25 degree celsius\n", "change_T=TJmax-75 #temperature difference\n", "PDmax=change_T/theta\n", "print \"at 75 degree celsius,PDmax= (TJmax-75)/theta = %0.2f\"%(PDmax)+ \" mW \" #maximum allowed power dissipation at TA=75 degree celsius" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Example 3_12 Page No. 86" ] }, { "cell_type": "code", "execution_count": 9, "metadata": { "collapsed": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "VBE = 0.70 volts\n", "VCC = 10.00 volts\n", "IREF =IQ= 0.01 ampere\n", "R=(VCC-VBE)/(IREF)= 1860.00 ohm\n" ] } ], "source": [ "from __future__ import division \n", "VBE=(0.7)\n", "print \"VBE = %0.2f\"%(VBE),\" volts\" # value of base-emitter voltage\n", "VCC=10\n", "print \"VCC = %0.2f\"%(VCC),\" volts\" # collector supply voltage \n", "IREF=5*10**(-3)\n", "print \"IREF =IQ= %0.2f\"%(IREF),\" ampere\" # current mirror source current\n", "R=(VCC-VBE)/(IREF)# formulae\n", "print \"R=(VCC-VBE)/(IREF)= %0.2f\"%(R)+ \" ohm\" #resistance" ] } ], "metadata": { "kernelspec": { "display_name": "Python 2", "language": "python", "name": "python2" }, "language_info": { "codemirror_mode": { "name": "ipython", "version": 2 }, "file_extension": ".py", "mimetype": "text/x-python", "name": "python", "nbconvert_exporter": "python", "pygments_lexer": "ipython2", "version": "2.7.9" } }, "nbformat": 4, "nbformat_minor": 0 }