{ "metadata": { "name": "" }, "nbformat": 3, "nbformat_minor": 0, "worksheets": [ { "cells": [ { "cell_type": "heading", "level": 1, "metadata": {}, "source": [ "Chapter 2 : Operational Amplifier" ] }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.1 Page No.44" ] }, { "cell_type": "code", "collapsed": false, "input": [ "# Given Data\n", "\n", "R1 = 5*10**3\n", "Rf = 20*10**3\n", "vi = 1 \n", "RL = 5*10**3\n", "\n", "# calculating the values \n", "vo = float((1+(Rf/R1))*vi) \n", "ACL = int(vo/vi)\n", "iL = int((vo/RL)*10**3)\n", "i1 = float(((vo - vi)/Rf))*(10**3)\n", "io = iL+i1\n", " \n", " \n", "# printing the values\n", "print \"Output voltage vo = \",vo,\"V\"\n", "print \"Gain ACL = \",ACL\n", "print \"Load current iL = \",iL,\"mA\"\n", "print \"The value of i1 = \",i1,\"mA\"\n", "print \"Output current io = \", io,\"mA\"\n" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "Output voltage vo = 5.0 V\n", "Gain ACL = 5\n", "Load current iL = 1 mA\n", "The value of i1 = 0.2 mA\n", "Output current io = 1.2 mA\n" ] } ], "prompt_number": 2 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.2 Page No.44" ] }, { "cell_type": "code", "collapsed": false, "input": [ "# Given data\n", "\n", "R1 = 10*10**3 #R1 input resistance \n", "Rf = 100*10**3 # Rf feedback resistance\n", "vi = float(1) #input voltage \n", "RL = 25*10**3\n", "#calculating the values \n", "\n", "i1 = float((vi/R1)*10**3) # input resistace id the ratio of input voltage to the input resitance \n", "vo = float(-(Rf/R1)*vi) # finding the output voltage \n", "iL = float((abs(vo)/RL)*10**3) # calculating the load current \n", "io = float((i1+iL)) # calculating the output current which is equal to the sum of input current and load current\n", "\n", "#printing the values \n", "\n", "print \"The input current i1 =\",i1,\"mA\"\n", "print \"The output voltage vo =\",vo,\"V\"\n", "print \"The load current iL =\",iL,\"mA\"\n", "print \"The output current io =\",io,\"mA\"\n" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "The input current i1 = 0.1 mA\n", "The output voltage vo = -10.0 V\n", "The load current iL = 0.4 mA\n", "The output current io = 0.5 mA\n" ] } ], "prompt_number": 3 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.3 Page No.49" ] }, { "cell_type": "code", "collapsed": false, "input": [ "# Given data\n", "\n", "ACL = 5 # Gain of the amplifier\n", "R1 = 10*10**3 # input resisitance in ohms \n", "\n", "# calculations\n", "\n", "Rf = (5-1) * R1 # calculating the resistance of feedback resistor \n", "\n", "# printing the values \n", "\n", "print \"The value of feedback resistor = \", (Rf/10**3),\"KiloOhms\"" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "The value of feedback resistor = 40 KiloOhms\n" ] } ], "prompt_number": 4 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.4 Page No.49" ] }, { "cell_type": "code", "collapsed": false, "input": [ "\n", "# Given Data\n", "\n", "R1 = 5*10**3\n", "Rf = 20*10**3\n", "vi = 1 \n", "RL = 5*10**3\n", "\n", "# calculating the values \n", "vo = float((1+(Rf/R1))*vi) \n", "ACL = int(vo/vi)\n", "iL = int((vo/RL)*10**3)\n", "i1 = float(((vo - vi)/Rf))*(10**3)\n", "io = iL+i1\n", " \n", " \n", "# printing the values\n", "print \"Output voltage vo = \",vo,\"V\"\n", "print \"Gain ACL = \",ACL\n", "print \"Load current iL = \",iL,\"mA\"\n", "print \"The value of i1 = \",i1,\"mA\"\n", "print \"Output current io = \", io,\"mA\"\n" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "Output voltage vo = 5.0 V\n", "Gain ACL = 5\n", "Load current iL = 1 mA\n", "The value of i1 = 0.2 mA\n", "Output current io = 1.2 mA\n" ] } ], "prompt_number": 6 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.6 Page No.61" ] }, { "cell_type": "code", "collapsed": false, "input": [ "\n", "# Given Data\n", "from decimal import Decimal, ROUND_HALF_UP\n", "import math\n", "Beta = 200\n", "ICQ = 100*10**-6\n", "ADM = 100\n", "CMRR = 80\n", "\n", "# finding the solution \n", "# for VT =25 milli volt \n", "VT = 25*10**-3\n", "gm = float(ICQ/VT)\n", "Rc = (ADM/gm) \n", "CMRR = 10**(80/20) # log inverse is equal to powers of 10\n", "RE = float((CMRR-1)/gm)\n", "x = Decimal((RE/10**6))\n", "\n", "# printing the values \n", "\n", "print \" The value of gm =\",int(math.ceil((gm*10**3))),\"mMho\" #converting the answer into milli Mho\n", "print \" The value of Rc =\",int((Rc/10**3)),\"kiloOhm\" #converting the answer into Kilo Ohm\n", "print \" The value of RE =\", x.quantize(Decimal('2.5')),\"MegaOhm\" #converting the answer into MegaOhm" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ " The value of gm = 4 mMho\n", " The value of Rc = 25 kiloOhm\n", " The value of RE = 2.5 MegaOhm\n" ] } ], "prompt_number": 7 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.7 Page No.61" ] }, { "cell_type": "code", "collapsed": false, "input": [ "import math \n", "# Given Data\n", "RC = 2*10**3\n", "RE = 4.3*10**3\n", "VCC = VEE = 5\n", "beta0 = 200\n", "VBE = 0.7\n", "VT = 25*10**-3 # VT = 25 mV \n", "\n", "#calculations \n", "\n", "Ibq = (((VEE - VBE)/(2*(1+beta0)*RE)))*10**6 # converting the into mA\n", "IBQ = int(Ibq*10)/10.0 # rounding the answer 2.48 to 2.4\n", "ICQ = beta0 * IBQ*10**-3 # finding ICQ and convert it into milli Ambere\n", "V01 = V02 = VCC - (RC * ICQ*10**-3)\n", "VCEQ = V01 + VBE\n", "gm = ICQ / VT # Finding the gm value in milli Mho\n", "rpi = float(beta0/gm) # finding rpi interms of KiloOhms \n", "ADM = -(gm*RC)/10**3 # Calculating the gain \n", "ACM = float((-beta0*RC)/(rpi*10**3 + (2*beta0) * RE)) # Calulating the value of ACM and coverting it into a float \n", "CMRR = float(round(ADM,2)/round(ACM,2)) # rounding ACM and ADM to 2 digits after decimals and taking the\n", " #ratio\n", "CMRRdb = float(20*math.log10(round(CMRR,1))) # Find the CMRR in dB using equation 20*log(CMRR)\n", "\n", "# Printing all values \n", "\n", "print \"The IBQ =\",IBQ,\"uA\"\n", "print \"The ICQ =\",ICQ,\"mA\"\n", "print \"The V01 =\",V01,\"mV\"\n", "print \"The VCEQ =\",VCEQ,\"V\"\n", "print \"The gm =\",gm,\"m Mho\"\n", "print \"The rpi =\",round(rpi,1),\"kilo Ohm\"\n", "print \"The ADM =\",round(ADM,2)\n", "print \"The ACM =\",round(ACM,2)\n", "print \"The CMRR =\",round(CMRR,1)\n", "print \"The CMRR in dB =\",int(CMRRdb*10)/10.0,\"dB\"\n", " " ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "The IBQ = 2.4 uA\n", "The ICQ = 0.48 mA\n", "The V01 = 4.04 mV\n", "The VCEQ = 4.74 V\n", "The gm = 19.2 m Mho\n", "The rpi = 10.4 kilo Ohm\n", "The ADM = -38.4\n", "The ACM = -0.23\n", "The CMRR = 167.0\n", "The CMRR in dB = 44.4 dB\n" ] } ], "prompt_number": 8 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.8 Page No.62" ] }, { "cell_type": "code", "collapsed": false, "input": [ "# v1 = 15*sin*2*pi(60)t + 5*sin*2*pi(1000)t mV\n", "# v1 = 15*sin*2*pi(60)t - 5*sin*2*pi(1000)t mV\n", "\n", "# Given data \n", "\n", "gm = 4*10**-3\n", "RC = 125*10*3\n", "RE = 1.25*10**3\n", "beta0 = 200\n", "\n", "# calculating the values\n", "\n", "rpi = beta0/gm # value is in ohms \n", "ADM =-500 # Given Value\n", "ACM = -((200*RC)/(402*RE)+rpi)*10**-6\n", "print \"ACM is =\",round(ACM,2)\n", "\n", "# derivation part is as follows \n", "# VDM = (v1 - v2)/2 = 5*sin*2*pi(1000)*t\n", "# VCM = (v1 - v2)/2 = 15*sin*2*pi(60)*t\n", "# VO1 = ADM*VDM + ACM*VCM\n", "# VO2 = ADM*VDM - ACM*VCM\n", "# V01 = -2500*sin*2*pi(1000)t - 0.75*sin*2*pi(60)t mV\n", "# V01 = 2500*sin*2*pi(1000)t - 0.75*sin*2*pi(60)t mV" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "ACM is = -0.05\n" ] } ], "prompt_number": 9 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.9 Page No.63" ] }, { "cell_type": "code", "collapsed": false, "input": [ "import math\n", "from fractions import Fraction \n", "# Given data\n", "\n", "beta0 = 100\n", "IQ = 5*10**-4\n", "RC = 10*10**3\n", "RE = 150\n", "VT = 25*10**-3 \n", "\n", "# calculations \n", "\n", "ICQ = float(IQ/2)\n", "gm = float(ICQ / VT)\n", "rpi = beta0/gm\n", "# calculaing the gain in Differential mode\n", "ADM = ((0.5)*(beta0*RC))/(rpi+((1+beta0)*RE))\n", "# To get the differentila mode gain multiply the value by 2\n", "ADM2 = (ADM*2)\n", "\n", "# print the values \n", "\n", "print \"ICQ value is =\",ICQ*10**3,\"mA\"\n", "print \"gm value is =\",Fraction(gm).limit_denominator(100),\"Mho\" \n", "print \"rpi value is =\",int(rpi/10**3),\"kilo Ohm\"\n", "print \"THe gain is =\",int(math.ceil(ADM2)),\"V/V\"" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "ICQ value is = 0.25 mA\n", "gm value is = 1/100 Mho\n", "rpi value is = 10 kilo Ohm\n", "THe gain is = 40 V/V\n" ] } ], "prompt_number": 10 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.10 Page No.67" ] }, { "cell_type": "code", "collapsed": false, "input": [ "# Given Data \n", "VCC = 10.0 # initializing as floats \n", "beta = 125.0\n", "VBE = 0.7\n", "\n", "# calculations \n", "# Define a function for calculating the value of R1 according to the equation given in 2.67\n", "def R1(I):\n", " R1 = (beta/(2+beta))*((VCC-VBE)/I) \n", " return (R1/1000)\n", "# Cosisdering Ic = 1mA\n", "print \"The value of R1 when I is 1 mA = \",round(R1(10**-3),2),\"Kilo Ohm\" # calling the function R1 with arguiment as current value 1 mA\n", "print \"The value of R1 when I is 10 uA = \",int(round(R1(10*10**-6),0)),\"Kilo Ohm\" # calling the function R1 with arguiment as current value 10 uA" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "The value of R1 when I is 1 mA = 9.15 Kilo Ohm\n", "The value of R1 when I is 10 uA = 915 Kilo Ohm\n" ] } ], "prompt_number": 12 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.11 Page No.69" ] }, { "cell_type": "code", "collapsed": false, "input": [ "# Given data\n", "import math\n", "I0 = 10*10**-6\n", "VCC =10\n", "VBE = 0.7\n", "beta = 125\n", "VT = 25*10**-3\n", "\n", "# Solution of the problem is \n", "Iref = 10**-3 # Assumption\n", "\n", "R1 = (VCC - VBE)/Iref\n", "# Finding the value RE from the equation 2.74\n", "RE = (VT/(1+(1/beta)*I0))*math.log(Iref/I0)\n", "\n", "# printing the values \n", "\n", "print \"The value of R1 =\",R1/10**3,\"Kilo Ohms\"\n", "print \"The value of RE =\",round(RE*100,1),\"Kilo Ohms\"" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "The value of R1 = 9.3 Kilo Ohms\n", "The value of RE = 11.5 Kilo Ohms\n" ] } ], "prompt_number": 13 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.13 Page No.74" ] }, { "cell_type": "code", "collapsed": false, "input": [ "# Given data \n", "\n", "VCC = 10.0\n", "beta = 100\n", "VBE = 0.7\n", "RE = 10*10**3\n", "\n", "# solution\n", "# fom the KVL loop1\n", "Iref = ((VCC - VBE)/RE) # Finding the Iref \n", "# Assuming the transistor are identical \n", "# Iref = 2IE\n", "# IE = IC + IB\n", "IC = (beta*Iref/(2*(1+beta)))\n", "I0 = IC\n", "#Displaying the values \n", "\n", "print \"The value of Iref =\",Iref*10**3,\"mA\" # Converting the value into mA\n", "print \"The value of IC =\",round(IC*10**3,2),\"mA\" # Converting the value into mA and rounding the answer\n", "print \"The value of I0 =\",round(I0*10**3,2),\"mA\" # Converting the value into mA and rounding the answer" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "The value of Iref = 0.93 mA\n", "The value of IC = 0.46 mA\n", "The value of I0 = 0.46 mA\n" ] } ], "prompt_number": 15 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.14 Page No.75" ] }, { "cell_type": "code", "collapsed": false, "input": [ "# Given data \n", "\n", "VCC = 12.0\n", "Rref = 15*10**3 \n", "R1 = 2.8*10**3\n", "beta = 200\n", "VBE = 0.7\n", "V0 = 6.0\n", "\n", "#Calculations \n", "#Calculations for finding the IC1 and IC2\n", "Iref = (VCC - VBE)/Rref\n", "I1 = VBE / R1\n", "IC1 = (Iref - I1)/(1+(2/beta))\n", "IC2 = IC1 # Due to mirror effect \n", "RC = (VCC - V0)/IC1\n", "\n", "# Displaying the values \n", "\n", "print \"The value of Iref =\",round(Iref*10**3,2),\"mA\" # convert into milli amps and rounding the output\n", "print \"The value of I1 =\",round(I1*10**3,2),\"mA\" # convert into milli amps and rounding the output\n", "print \"The value of IC1 =\",round(IC1*10**3,1),\"mA\" # convert into milli amps and rounding the output\n", "print \"The value of Rc =\",int(round(RC*10**-3,0)),\"Kilo Ohm\" # convert into kilo Ohms and rounding the output" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "The value of Iref = 0.75 mA\n", "The value of I1 = 0.25 mA\n", "The value of IC1 = 0.5 mA\n", "The value of Rc = 12 Kilo Ohm\n" ] } ], "prompt_number": 16 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.15 Page No.75" ] }, { "cell_type": "code", "collapsed": false, "input": [ "# Given data \n", "\n", "VCC = 10.0\n", "VBE = 0.75\n", "R1 = 4.7*10**3\n", "\n", "# solution \n", "# I is approximately equals to Ic(2 + (1/beta)), since 1/beta is a small value its considerd as 2Ics \n", "I = (VCC - VBE)/R1\n", "# IE3 is approxiamtly equal to IC3 = I/2\n", "#finding the value of IC \n", "IC = I /2\n", "print \" The value of I =\",round(I*10**3,2),\"mA\"\n", "print \" The value of IC =\",round(IC*10**3,2),\"mA\"\n" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ " The value of I = 1.97 mA\n", " The value of IC = 0.98 mA\n" ] } ], "prompt_number": 17 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.16 Page No.80" ] }, { "cell_type": "code", "collapsed": false, "input": [ "# Given data\n", "VCC = 15.0\n", "VBE = 0.7\n", "R = 10*10**3\n", "RC2 = 5*10**3\n", "# consider beta is a large value \n", "I = (VCC - VBE)/R\n", "IC1 = IC2 = I\n", "#V12 = V1 - V2\n", "V12 = VBE + IC2 * RC2 \n", "\n", "# displaying the values\n", "print \"The value of I =\",round(I*10**3,2),\"mA\"\n", "print \"The value of V1 - V2 =\",V12,\"V\"\n" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "The value of I = 1.43 mA\n", "The value of V1 - V2 = 7.85 V\n" ] } ], "prompt_number": 18 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.17 Page No.83" ] }, { "cell_type": "code", "collapsed": false, "input": [ "import math\n", "# Given data\n", "\n", "VEE = 6.0\n", "VCC = 6.0\n", "VD = VD1 = VD2 = VD3 = VD4 = 0.7\n", "R5 = 3.2*10**3\n", "R4 = 1.5*10**3\n", "VBE1 = VBE2 =VBE3 = VBE4 = VBE5 = VBE6 = VBE7 = VBE8 = 0.7\n", "R1 = 2.2*10**3\n", "R2 = 7.75*10**3\n", "R3 = 5.2*10**3\n", "R6 = 1.5*10**3\n", "R7 = 3*10**3\n", "R8 = 3.4*10**3\n", "R9 = 6*10**3\n", "R10 =30*10**3\n", "hfe = 100\n", "VT = 26*10**-3\n", "\n", "# Solution for part A\n", "\n", "VBN1 = round((-VEE+VD+VD)*R5/(R4+R5),2)\n", "I1 = (VEE+VBN1-VBE1)/R1\n", "IQ = I1 # If the base current of Q1 is neglected\n", "IC2 = IC3 = IQ2 = round(IQ/2,6)\n", "VC2 = VC3 = round((VCC - R2*IC2),2)\n", "VE4 = VC2 - VBE4 \n", "I6 = round(VE4/R6,6)\n", "IC4 = IC5 = round((I6/2),6)\n", "VC5 = round(VCC - IC5*R7,2)\n", "VE6 = round(VC5 - VBE6,2)\n", "IC7 = I8 = round((VEE - VD3)/R8,5)\n", "VB8 = VBE8 + VD4 - VEE\n", "I9 = round((VE6 - VB8)/R9,5)\n", "I10 = IC7 - I9\n", "Vo = (I10 * R10) + VB8\n", "V0 = int(Vo) # Vo value is assumed to be very small\n", "\n", "# Displaying the values \n", "print \"PART A\"\n", "print \"==================\"\n", "print \"the value of VBN1 =\",VBN1,\"V\"\n", "print \"The value of I1 =\",I1*10**3,\"mA\"\n", "print \"The value of IQ =\",IQ*10**3,\"mA\"\n", "print \"The value of IC2 =\",IC2*10**3,\"mA\"\n", "print \"The value of VC3 =\",VC3,\"V\"\n", "print \"The value of VE4 =\",VE4,\"V\"\n", "print \"The value of IC4 =\",IC4*10**3,\"mA\"\n", "print \"The value of VC5 =\",VC5,\"V\"\n", "print \"The value of VE6 =\",VE6,\"V\"\n", "print \"The value of IC7 =\",IC7*10**3,\"mA\"\n", "print \"The value of VB8 =\",VB8,\"V\"\n", "print \"The value of I9 =\",I9*10**3,\"mA\"\n", "print \"The value of I10 =\",I10*10**3,\"mA\"\n", "print \"The value of V0 =\",V0,\"V\"\n", "\n", "# Solution for part B\n", "VT = 26*10**-3 #the volt equivalent of temperature \n", "IC2 = IC3 = IC4 = IC5 = IC = 0.5*10**-3\n", "hie = (hfe*VT)/IC\n", "RL2 = RL3 = (R2*R3)/(R2+R3)\n", "AV1 = round((hfe*RL2)/hie,0)\n", "AV2 = round(-(hfe*R7)/(2*hie),2)\n", "AV3 = 1 # the thrid stage emitter follower differential gain \n", "AV4 = int(-R10/R9)\n", "AV = AV1*round(AV2,1)*AV4 # again rounding AV2 to get the desired value\n", "\n", "# Displaying the values\n", "print \"PART B\"\n", "print \"==================\"\n", "print \"The value of hie =\",int(hie)\n", "print \"The value of RL2 =\",RL2*10**-3,\"Kilo Ohms\"\n", "print \"The value of AV1 =\",int(AV1)\n", "print \"The value of AV2 =\",round(AV2,1)\n", "print \"The value of AV3 =\",AV3\n", "print \"The value of AV4 =\",AV4\n", "print \"The value of AV =\",int(AV)\n" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "PART A\n", "==================\n", "the value of VBN1 = -3.13 V\n", "The value of I1 = 0.986363636364 mA\n", "The value of IQ = 0.986363636364 mA\n", "The value of IC2 = 0.493 mA\n", "The value of VC3 = 2.18 V\n", "The value of VE4 = 1.48 V\n", "The value of IC4 = 0.494 mA\n", "The value of VC5 = 4.52 V\n", "The value of VE6 = 3.82 V\n", "The value of IC7 = 1.56 mA\n", "The value of VB8 = -4.6 V\n", "The value of I9 = 1.4 mA\n", "The value of I10 = 0.16 mA\n", "The value of V0 = 0 V\n", "PART B\n", "==================\n", "The value of hie = 5200\n", "The value of RL2 = 3.11196911197 Kilo Ohms\n", "The value of AV1 = 60\n", "The value of AV2 = -28.9\n", "The value of AV3 = 1\n", "The value of AV4 = -5\n", "The value of AV = 8670\n" ] } ], "prompt_number": 20 }, { "cell_type": "heading", "level": 2, "metadata": {}, "source": [ "Example 2.18 Page No.87" ] }, { "cell_type": "code", "collapsed": false, "input": [ "# Given data \n", "VEE = 15.0\n", "VCC = 15.0\n", "VBE1 = VBE2 = VBE3 = VBE4 = VBE5 = VBE= 0.7\n", "R = 28.6*10**3\n", "RC1 = 20*10**3\n", "RC6 = 3*10**3\n", "RC8 = 2.3*10**3\n", "RA = 15.7*10**3\n", "hfe = 100\n", "VT = 25*10**-3\n", "\n", "# Solution for part 1 DC - ANALYSIS\n", "\n", "I = (VEE - VBE3)/R\n", "ICQ4 = I\n", "ICQ1 = ICQ2 = ICQ4/2\n", "# Q1 and Q2 are biased at 0.25mA so their Collector voltages are\n", "IC1 = IC = ICQ1\n", "VCQ1 = VCQ2 = VCC - (IC1*RC1)\n", "VEQ5 = VEQ6 = VCQ1 - VBE\n", "IQ7 = 4*I\n", "# The collector current of Q5 and Q6 are \n", "ICQ5 = ICQ6 = IQ7/2\n", "VCQ6 = VCC - (ICQ6 * RC6)\n", "VEQ8 = VCQ6 + VBE\n", "IEQ8 = (VCC - VEQ8)/RC8\n", "# The voltage VA at the collector of Q8 is \n", "VA = -VCC + (IEQ8 * RA)\n", "IEQ9 = (0-(-VCC))/RC6\n", "\n", "# Displaying all values of Part 1\n", "\n", "print \"The value of I =\",int(I*10**3),\"mA\"\n", "print \"The value of ICQ1 =\",int(ICQ1*10**3),\"mA\"\n", "print \"The value of VCQ1 =\",int(VCQ1),\"V\"\n", "print \"The value of VEQ5 =\",int(VEQ5),\"V\"\n", "print \"The value of IQ7 =\",int(IQ7*10**3),\"mA\"\n", "print \"The value of ICQ5 =\",int(ICQ5*10**3),\"mA\"\n", "print \"The value of VCQ6 =\",int(VCQ6),\"V\"\n", "print \"The value of VEQ8 =\",int(VEQ8),\"V\"\n", "print \"The value of IEQ8 =\",int(IEQ8*10**3),\"mA\"\n", "print \"The value of VA =\",VA,\"V\"\n", "print \"The value of IEQ9 =\",int(IEQ9*10**3),\"mA\"\n", "\n", "# Part 2 AC -ANALYSIS\n", "\n", "hieQ12 = (hfe * VT)/IC\n", "# The ac emitter resistance of transister Q5 - Q6\n", "hieQ56 = (hfe * VT)/ICQ5\n", "RL1 = RL2 = (RC1*hieQ56)/(RC1 + hieQ56) # parallel combination of resistor RC1 and hieQ56\n", "ADM1 = (hfe * RL2)/hieQ12\n", "ADM2 = -(hfe * RC6)/(2*hieQ56)\n", "\n", "\n", "# Displaying the values \n", "\n", "print \"The value of ac emiiter resistace of the transistor Q1-Q2 = \",int(round(hieQ12*10**-3,0)),\"Kilo Ohm\"\n", "print \"The value of ac emiiter resistace of the transistor Q5-Q6 = \",round(hieQ56*10**-3,1),\"Kilo Ohm\"\n", "print \"The value of effective load of Q1-Q2 = \",round(RL1*10**-3,1),\"Kilo Ohm\"\n", "print \"The value of voltage gain of first differential pair = \",int(round(ADM1,0)),\"Kilo Ohm\"\n", "print \"The value of voltage gain of second differential pair = \",int(ADM2),\"Kilo Ohm\"\n" ], "language": "python", "metadata": {}, "outputs": [ { "output_type": "stream", "stream": "stdout", "text": [ "The value of I = 0 mA\n", "The value of ICQ1 = 0 mA\n", "The value of VCQ1 = 10 V\n", "The value of VEQ5 = 9 V\n", "The value of IQ7 = 2 mA\n", "The value of ICQ5 = 1 mA\n", "The value of VCQ6 = 12 V\n", "The value of VEQ8 = 12 V\n", "The value of IEQ8 = 1 mA\n", "The value of VA = 0.7 V\n", "The value of IEQ9 = 5 mA\n", "The value of ac emiiter resistace of the transistor Q1-Q2 = 10 Kilo Ohm\n", "The value of ac emiiter resistace of the transistor Q5-Q6 = 2.5 Kilo Ohm\n", "The value of effective load of Q1-Q2 = 2.2 Kilo Ohm\n", "The value of voltage gain of first differential pair = 22 Kilo Ohm\n", "The value of voltage gain of second differential pair = -60 Kilo Ohm\n" ] } ], "prompt_number": 21 }, { "cell_type": "code", "collapsed": false, "input": [], "language": "python", "metadata": {}, "outputs": [] } ], "metadata": {} } ] }