Added(A)/Deleted(D) following books

 M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter1.ipynb
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter10.ipynb
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter11.ipynb
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter12.ipynb
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter2.ipynb
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter3.ipynb
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter4.ipynb
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter5.ipynb
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter6.ipynb
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter7.ipynb
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter8.ipynb
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/screenshots/2.png
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/screenshots/3.png
M  BSc_First_Year_Physics_by_P._BalaBhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/screenshots/4.png
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter01.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter02.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter03.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter04.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter05.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter10.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter11.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter12.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter13.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter14.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter15.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter16.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter17.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter18.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter19.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter20.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter21.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter22.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter6.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter7.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter8.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter9.ipynb
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/screenshots/16.11.png
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/screenshots/3.3.png
M  Basic_And_Applied_Thermodynamics_by_P._K._Nag/screenshots/7.10.png
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter1.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter1.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter10.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter10.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter13.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter13.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter14.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter14.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter15.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter15.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter2.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter2.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter3.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter3.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter4.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter4.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter5.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter5.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter6.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter6.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter7.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter7.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter8.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter8.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter9.ipynb -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/chapter9.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/screenshots/Screenshot_(88).png -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/screenshots/Screenshot_(88).png
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/screenshots/Screenshot_(89).png -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/screenshots/Screenshot_(89).png
R  Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/screenshots/Screenshot_(90).png -> Basic_Electronics_Electronics_Engineering_by_J_B_Gupta/screenshots/Screenshot_(90).png
M  Basic_Electronics_by_Rakesh_Kumar_Garg,_Ashish_Dixit_&_Paban_Yadav/chapter1.ipynb
M  Basic_Electronics_by_Rakesh_Kumar_Garg,_Ashish_Dixit_&_Paban_Yadav/chapter2.ipynb
M  Basic_Electronics_by_Rakesh_Kumar_Garg,_Ashish_Dixit_&_Paban_Yadav/chapter3.ipynb
M  Basic_Electronics_by_Rakesh_Kumar_Garg,_Ashish_Dixit_&_Paban_Yadav/chapter4.ipynb
M  Basic_Electronics_by_Rakesh_Kumar_Garg,_Ashish_Dixit_&_Paban_Yadav/chapter5.ipynb
M  Basic_Electronics_by_Rakesh_Kumar_Garg,_Ashish_Dixit_&_Paban_Yadav/chapter6.ipynb
M  Basic_Electronics_by_Rakesh_Kumar_Garg,_Ashish_Dixit_&_Paban_Yadav/chapter7.ipynb
M  Basic_Electronics_by_Rakesh_Kumar_Garg,_Ashish_Dixit_&_Paban_Yadav/chapter8.ipynb
M  Basic_Electronics_by_Rakesh_Kumar_Garg,_Ashish_Dixit_&_Paban_Yadav/screenshots/DCLOADLINEchapter4.png
M  Basic_Electronics_by_Rakesh_Kumar_Garg,_Ashish_Dixit_&_Paban_Yadav/screenshots/DCLOADLineCH4.png
M  Basic_Electronics_by_Rakesh_Kumar_Garg,_Ashish_Dixit_&_Paban_Yadav/screenshots/TransferCharofnchmosfetCH8.png
M  Electrical_Machines_-_I_by_M._Verma_And_V._Ahuja/ch1.ipynb
M  Electrical_Machines_-_I_by_M._Verma_And_V._Ahuja/ch2.ipynb
M  Electrical_Machines_-_I_by_M._Verma_And_V._Ahuja/ch3.ipynb
M  Electrical_Machines_-_I_by_M._Verma_And_V._Ahuja/ch4.ipynb
M  Electrical_Machines_-_I_by_M._Verma_And_V._Ahuja/screenshots/EffiOfTrans4.png
M  Electrical_Machines_-_I_by_M._Verma_And_V._Ahuja/screenshots/starDeltaNdeltaStar4.png
M  Electrical_Machines_-_I_by_M._Verma_And_V._Ahuja/screenshots/voltageReg4.png
M  Engineering_Mechanics_by_A._K._Tayal/Chapter10.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter12.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter13.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter14.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter15.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter16.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter17.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter18.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter19.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter2.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter20.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter21.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter22.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter23.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter24.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter25.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter26.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter3.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter4.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter5.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter6.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter7.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter8.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/Chapter9.ipynb
M  Engineering_Mechanics_by_A._K._Tayal/screenshots/1.png
M  Engineering_Mechanics_by_A._K._Tayal/screenshots/2.png
M  Engineering_Mechanics_by_A._K._Tayal/screenshots/3.png
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/Ch1.ipynb
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/Ch2.ipynb
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/Ch3.ipynb
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/Ch4.ipynb
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/Ch5.ipynb
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/Ch6.ipynb
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/Ch7.ipynb
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/Ch8.ipynb
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/README.txt
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/screenshots/6.1.png
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/screenshots/6.png
M  Fundamentals_Of_Electronic_Devices_by_J._B._Gupta/screenshots/7.png
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/Chapter_10_Heat_Exchangers.ipynb
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/Chapter_11_Mass_Transfer.ipynb
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/Chapter_1_Introduction.ipynb
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/Chapter_2_Steady_State_Conduction_One_Dimension.ipynb
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/Chapter_3_Steady_State_Conduction_Multiple_Dimension.ipynb
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/Chapter_4_Unsteady_State_Conduction.ipynb
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/Chapter_5_Principles_of_Convection.ipynb
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/Chapter_6_Empirical_and_Practical_Relations_for_Forced_Convection_Heat_Transfer.ipynb
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/Chapter_7_Natural_Convection_Systems.ipynb
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/Chapter_8_Radiation_Heat_Transfer.ipynb
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/Chapter_9_Condensation_and_Boiling_Heat_Transfer.ipynb
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/screenshots/9.1.png
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/screenshots/9.2.png
M  Heat_Transfer_(In_SI_Units)_by_J_P_Holman/screenshots/9.4.png
M  Heat_Transfer_Principles_And_Applications_by_Dutta/README.txt
M  Heat_Transfer_Principles_And_Applications_by_Dutta/ch10.ipynb
M  Heat_Transfer_Principles_And_Applications_by_Dutta/ch11.ipynb
M  Heat_Transfer_Principles_And_Applications_by_Dutta/ch2.ipynb
M  Heat_Transfer_Principles_And_Applications_by_Dutta/ch3.ipynb
M  Heat_Transfer_Principles_And_Applications_by_Dutta/ch4.ipynb
M  Heat_Transfer_Principles_And_Applications_by_Dutta/ch5.ipynb
M  Heat_Transfer_Principles_And_Applications_by_Dutta/ch6.ipynb
M  Heat_Transfer_Principles_And_Applications_by_Dutta/ch7.ipynb
M  Heat_Transfer_Principles_And_Applications_by_Dutta/ch8.ipynb
M  Heat_Transfer_Principles_And_Applications_by_Dutta/ch9.ipynb
M  Heat_Transfer_Principles_And_Applications_by_Dutta/screenshots/10.png
M  Heat_Transfer_Principles_And_Applications_by_Dutta/screenshots/5.png
M  Heat_Transfer_Principles_And_Applications_by_Dutta/screenshots/51.png
M  Heat_Transfer_in_SI_units_by_Holman/Chapter1.ipynb
M  Heat_Transfer_in_SI_units_by_Holman/Chapter10.ipynb
M  Heat_Transfer_in_SI_units_by_Holman/Chapter11.ipynb
M  Heat_Transfer_in_SI_units_by_Holman/Chapter2.ipynb
M  Heat_Transfer_in_SI_units_by_Holman/Chapter3.ipynb
M  Heat_Transfer_in_SI_units_by_Holman/Chapter4.ipynb
M  Heat_Transfer_in_SI_units_by_Holman/Chapter5.ipynb
M  Heat_Transfer_in_SI_units_by_Holman/Chapter6.ipynb
M  Heat_Transfer_in_SI_units_by_Holman/Chapter7.ipynb
M  Heat_Transfer_in_SI_units_by_Holman/Chapter8.ipynb
M  Heat_Transfer_in_SI_units_by_Holman/Chapter9.ipynb
M  Heat_Transfer_in_SI_units_by_Holman/README.txt
M  Heat_Transfer_in_SI_units_by_Holman/screenshots/9.1.png
M  Heat_Transfer_in_SI_units_by_Holman/screenshots/9.2.png
M  Heat_Transfer_in_SI_units_by_Holman/screenshots/9.4.png
M  Linear_Algebra_And_Its_Applications_by_G._Strang/CHAPTER1.ipynb
M  Linear_Algebra_And_Its_Applications_by_G._Strang/CHAPTER2.ipynb
M  Linear_Algebra_And_Its_Applications_by_G._Strang/CHAPTER3.ipynb
M  Linear_Algebra_And_Its_Applications_by_G._Strang/CHAPTER4.ipynb
M  Linear_Algebra_And_Its_Applications_by_G._Strang/CHAPTER5.ipynb
M  Linear_Algebra_And_Its_Applications_by_G._Strang/CHAPTER6.ipynb
M  Linear_Algebra_And_Its_Applications_by_G._Strang/CHAPTER7.ipynb
M  Linear_Algebra_And_Its_Applications_by_G._Strang/CHAPTER8.ipynb
M  Linear_Algebra_And_Its_Applications_by_G._Strang/screenshots/Ch5Eigenmatrix.png
M  Linear_Algebra_And_Its_Applications_by_G._Strang/screenshots/Ch5eigenVectors.png
M  Linear_Algebra_And_Its_Applications_by_G._Strang/screenshots/ch5eigenvaluematrix.png
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/Chapter1.ipynb
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/Chapter2.ipynb
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/Chapter3.ipynb
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/Chapter4.ipynb
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/Chapter5.ipynb
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/Chapter6.ipynb
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/Chapter7.ipynb
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/Chapter8.ipynb
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/Chapter9.ipynb
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/README.txt
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/screenshots/1.png
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/screenshots/2.png
M  OpAmps_And_Linear_Integrated_Circuits_by_Gayakwad/screenshots/8.png
M  Power_Electronics_Principles_and_Applications_by_Jacob/Chapter1.ipynb
M  Power_Electronics_Principles_and_Applications_by_Jacob/Chapter2.ipynb
M  Power_Electronics_Principles_and_Applications_by_Jacob/Chapter3.ipynb
M  Power_Electronics_Principles_and_Applications_by_Jacob/Chapter4.ipynb
M  Power_Electronics_Principles_and_Applications_by_Jacob/Chapter5.ipynb
M  Power_Electronics_Principles_and_Applications_by_Jacob/Chapter6.ipynb
M  Power_Electronics_Principles_and_Applications_by_Jacob/Chapter7.ipynb
M  Power_Electronics_Principles_and_Applications_by_Jacob/Chapter8.ipynb
M  Power_Electronics_Principles_and_Applications_by_Jacob/Chapter9.ipynb
M  Power_Electronics_Principles_and_Applications_by_Jacob/README.txt
M  Power_Electronics_Principles_and_Applications_by_Jacob/screenshots/4.png
M  Power_Electronics_Principles_and_Applications_by_Jacob/screenshots/5.png
M  Power_Electronics_Principles_and_Applications_by_Jacob/screenshots/6.png
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter10_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter11_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter12_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter13_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter14_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter15_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter16_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter17_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter18_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter19_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter1_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter20_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter21_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter22_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter23_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter24_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter25_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter26_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter2_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter6_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter7_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter8_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/chapter9_6.ipynb
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/screenshots/chapter10_ac_load_line_5.png
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/screenshots/chapter18_clipping_ckt_output_6.png
M  Principles_of_Electronics_____by_V.K._Mehta_and_Rohit_Mehta/screenshots/chapter8_dc_load_line_6.png
M  Principles_of_Physics_by_F.J.Bueche/README.txt
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch10.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch11.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch12.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch14.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch16.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch2.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch3.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch4.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch5.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch6.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch7.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch8.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/ch9.ipynb
M  Semiconductor_circuit_approximations_by_A.P._Malvino/screenshots/ACloadLineChapter10.png
M  Semiconductor_circuit_approximations_by_A.P._Malvino/screenshots/DCandACloadlinechapter9.png
M  Semiconductor_circuit_approximations_by_A.P._Malvino/screenshots/Powerratingchapter9.png
M  Strength_Of_Materials_by_S_S_Bhavikatti/chapter_no.10_8.ipynb
M  Strength_Of_Materials_by_S_S_Bhavikatti/chapter_no.2_8.ipynb
M  Strength_Of_Materials_by_S_S_Bhavikatti/chapter_no.3_8.ipynb
M  Strength_Of_Materials_by_S_S_Bhavikatti/chapter_no.4_8.ipynb
M  Strength_Of_Materials_by_S_S_Bhavikatti/chapter_no.5_8.ipynb
M  Strength_Of_Materials_by_S_S_Bhavikatti/chapter_no.6_8.ipynb
M  Strength_Of_Materials_by_S_S_Bhavikatti/chapter_no.7_8.ipynb
M  Strength_Of_Materials_by_S_S_Bhavikatti/chapter_no.8_8.ipynb
M  Strength_Of_Materials_by_S_S_Bhavikatti/chapter_no.9_8.ipynb
M  Strength_Of_Materials_by_S_S_Bhavikatti/screenshots/BMD.JPG
M  Strength_Of_Materials_by_S_S_Bhavikatti/screenshots/SFD2.JPG
M  Strength_Of_Materials_by_S_S_Bhavikatti/screenshots/S_F_D_1.JPG
A  Theory_of_Alternating_Current_Machinery_by_A._S._Langsdorf/README.txt
M  sample_notebooks/AviralYadav/Chapter5.ipynb
A  sample_notebooks/RONAKBANSAL/chapter_1.ipynb

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+{
+ "cells": [
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "# Chapter 1: Semiconductor Diodes"
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.1"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 8,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      " Thermal Voltage= 25.875 mV\n"
+     ]
+    }
+   ],
+   "source": [
+    "k=1.38*(10**(-23))      #boltzmann's constant\n",
+    "t=273+27                #converting given temperature to Kelvin\n",
+    "q=1.6*(10**(-19))       #charge on an electron\n",
+    "\n",
+    "# V=(k*t)/q\n",
+    "\n",
+    "V=(k*t)/q\n",
+    "V=V*1000                #converting result in millivolts\n",
+    "print \"Thermal Voltage=\",V,\"mV\"\n"
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.2 (a)"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 10,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "Voltage across Germanium diode= 0.2 V\n",
+      "Voltage across Silicon diode  = 0.6 V\n",
+      "Voltage across GaAs diode     = 1.1 V\n"
+     ]
+    }
+   ],
+   "source": [
+    "Id= 1              #in mA, current across diodes\n",
+    "#from the standard graph for Ge,Si, and GaAs diodes\n",
+    "Vge=0.2\n",
+    "Vsi=0.6\n",
+    "Vgaas=1.1\n",
+    "print \"Voltage across Germanium diode=\",Vge,\"V\"\n",
+    "print \"Voltage across Silicon diode  =\",Vsi,\"V\"\n",
+    "print \"Voltage across GaAs diode     =\",Vgaas,\"V\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.2 (b)"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 11,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "Voltage across Germanium diode= 0.3 V\n",
+      "Voltage across Silicon diode  = 0.7 V\n",
+      "Voltage across GaAs diode     = 1.2 V\n"
+     ]
+    }
+   ],
+   "source": [
+    "Id= 4               #in mA, current across diodes\n",
+    "#from the standard graph for Ge,Si, and GaAs diodes\n",
+    "Vge=0.3\n",
+    "Vsi=0.7\n",
+    "Vgaas=1.2\n",
+    "print \"Voltage across Germanium diode=\",Vge,\"V\"\n",
+    "print \"Voltage across Silicon diode  =\",Vsi,\"V\"\n",
+    "print \"Voltage across GaAs diode     =\",Vgaas,\"V\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.2 (c)"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 12,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "Voltage across Germanium diode= 0.42 V\n",
+      "Voltage across Silicon diode  = 0.82 V\n",
+      "Voltage across GaAs diode     = 1.33 V\n"
+     ]
+    }
+   ],
+   "source": [
+    "Id=30               #in mA, current across diodes\n",
+    "#from the standard graph for Ge,Si, and GaAs diodes\n",
+    "Vge=0.42\n",
+    "Vsi=0.82\n",
+    "Vgaas=1.33\n",
+    "print \"Voltage across Germanium diode=\",Vge,\"V\"\n",
+    "print \"Voltage across Silicon diode  =\",Vsi,\"V\"\n",
+    "print \"Voltage across GaAs diode     =\",Vgaas,\"V\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.2 (d)"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 18,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "Average Volatge value for Germanium Diode= 0.307 V\n",
+      "Average Volatge value for Silicon Diode= 0.707 V\n",
+      "Average Volatge value for GaAs Diode= 1.21 V\n"
+     ]
+    }
+   ],
+   "source": [
+    "#Average value for Germanium\n",
+    "Vg=(0.2+0.3+0.42)/3\n",
+    "#Average value for Silicon\n",
+    "Vs=(0.6+0.7+0.82)/3\n",
+    "#Average value for GaAs\n",
+    "Vgs=(1.1+1.2+1.33)/3\n",
+    "print \"Average Volatge value for Germanium Diode=\",round(Vg,3),\"V\"\n",
+    "print \"Average Volatge value for Silicon Diode=\",round(Vs,3),\"V\"\n",
+    "print \"Average Volatge value for GaAs Diode=\",round(Vgs,3),\"V\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.2 (e)"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 22,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "Very close correspondence between knee voltage and average voltage\n",
+      "Germanium 0.3 V vs 0.307 V\n",
+      "Silicon 0.7 V vs 0.707 V\n",
+      "GaAs 1.2 V vs 1.21 V\n"
+     ]
+    }
+   ],
+   "source": [
+    "#comparing average values in d with the standard knee voltages\n",
+    "#Average value for Germanium\n",
+    "Vg=(0.2+0.3+0.42)/3\n",
+    "#Average value for Silicon\n",
+    "Vs=(0.6+0.7+0.82)/3\n",
+    "#Average value for GaAs\n",
+    "Vgs=(1.1+1.2+1.33)/3\n",
+    "kge=0.3\n",
+    "ksi=0.7\n",
+    "kgaas=1.2\n",
+    "print \"Very close correspondence between knee voltage and average voltage\"\n",
+    "print \"Germanium\",kge,\"V vs\",round(Vg,3),\"V\"\n",
+    "print \"Silicon\",ksi,\"V vs\",round(Vs,3),\"V\"\n",
+    "print \"GaAs\",kgaas,\"V vs\",round(Vgs,3),\"V\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {
+    "collapsed": true
+   },
+   "source": [
+    "## There is a Repeatation of Example 1.2"
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.2(a)"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 4,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "dc resistance= 250.0 ohms\n"
+     ]
+    }
+   ],
+   "source": [
+    "Id=2*(10**(-3))        #in ampere\n",
+    "Vd=0.5                 #in volts\n",
+    "rd=Vd/Id\n",
+    "print \"dc resistance=\",rd,\"ohms\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.2(b)"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 3,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "dc resistance 40.0 ohms\n"
+     ]
+    }
+   ],
+   "source": [
+    "Id=20*(10**(-3))          #in ampere\n",
+    "Vd=0.8                    #in volts\n",
+    "rd=Vd/Id\n",
+    "print \"dc resistance=\",rd,\"ohms\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.2(c)"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 7,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "dc resistance= 10.0 Mohms\n"
+     ]
+    }
+   ],
+   "source": [
+    "#Id=-Is\n",
+    "Id=1*(10**(-6))          #in ampere\n",
+    "Vd=-10                    #in volts\n",
+    "rd=abs(Vd)/Id\n",
+    "rd=rd/(10**(6))\n",
+    "print \"dc resistance=\",rd,\"Mohms\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.3(a)"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 2,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "ac resistance= 27.5 ohms\n"
+     ]
+    }
+   ],
+   "source": [
+    "# drawing tangent at Id=2mA and choosing any random points n the tangent to gwt two set of values of Id and Vd\n",
+    "Id1=4*(10**(-3))        #IN ampere\n",
+    "Id2=0                   #IN ampere\n",
+    "Vd1=0.76                #IN VOLTS\n",
+    "Vd2=0.65                #IN VOLTS \n",
+    "X=Id1-Id2\n",
+    "Y=Vd1-Vd2\n",
+    "rd=Y/X\n",
+    "print \"ac resistance=\",rd,\"ohms\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.3(b)"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 3,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "ac resistance= 2.0 ohms\n"
+     ]
+    }
+   ],
+   "source": [
+    "# drawing tangent at Id=2mA and choosing any random points n the tangent to gwt two set of values of Id and Vd\n",
+    "Id1=30*(10**(-3))        #IN ampere\n",
+    "Id2=20*(10**(-3))       #IN ampere\n",
+    "Vd1=0.80                #IN VOLTS\n",
+    "Vd2=0.78               #IN VOLTS \n",
+    "X=Id1-Id2\n",
+    "Y=Vd1-Vd2\n",
+    "rd=Y/X\n",
+    "print \"ac resistance=\",rd,\"ohms\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.3(c)"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 8,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "Dc resistance= 350.0 ohms exceeds ac resistance= 27.5 ohms\n",
+      "Dc resistance= 31.6 ohms exceeds ac resistance= 2 ohms\n"
+     ]
+    }
+   ],
+   "source": [
+    "#calculating Dc resistance\n",
+    "#Case-1\n",
+    "Id1=2*(10**(-3))      #in ampere\n",
+    "Vd1=0.7               #in volts\n",
+    "Rd=Vd1/Id1\n",
+    "rd=27.5               #ac resistance in ohms\n",
+    "if Rd>rd:\n",
+    " print \"Dc resistance=\",Rd,\"ohms exceeds ac resistance=\",rd,\"ohms\"\n",
+    "else:\n",
+    " print \"Dc resistance=\",Rd,\"ohms didnot exceeds ac resistance=\",rd,\"ohms\"\n",
+    "\n",
+    "#Case-2\n",
+    "Id1=25*(10**(-3))      #in ampere\n",
+    "Vd1=0.79               #in volts\n",
+    "Rd=Vd1/Id1\n",
+    "rd=2                   #ac resistance in ohms\n",
+    "if Rd>rd:\n",
+    " print \"Dc resistance=\",Rd,\"ohms exceeds ac resistance=\",rd,\"ohms\"\n",
+    "else:\n",
+    " print \"Dc resistance=\",Rd,\"ohms didnot exceeds ac resistance=\",rd,\"ohms\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.4"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 9,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "New potential across zener diode= 10.54 V\n"
+     ]
+    }
+   ],
+   "source": [
+    "#Equation- change in Cvz=(Tc*Vz*(t1-t0))/100%\n",
+    "Tc=0.072            #unit %/celsius\n",
+    "t1=100              #in celsius\n",
+    "t0=25               #in celsius\n",
+    "Vz=10               #in volts\n",
+    "Cvz=(Tc*Vz*(t1-t0))/100\n",
+    "nVz=Vz+Cvz          #new Vz\n",
+    "print \"New potential across zener diode=\",nVz,\"V\""
+   ]
+  },
+  {
+   "cell_type": "markdown",
+   "metadata": {},
+   "source": [
+    "## Example 1.5"
+   ]
+  },
+  {
+   "cell_type": "code",
+   "execution_count": 15,
+   "metadata": {
+    "collapsed": false
+   },
+   "outputs": [
+    {
+     "name": "stdout",
+     "output_type": "stream",
+     "text": [
+      "The range of Wavelength for the frequency of Visible lightis 750 nm to 400 nm\n"
+     ]
+    }
+   ],
+   "source": [
+    "#Equation wavelength(x)=c/f,where c=speed of light and f=frequency of the light\n",
+    "c=3*(10**(8))*(10**(9))                #in nm/s\n",
+    "x1=(c/(400*(10**12)))                   #in nm\n",
+    "x2=c/(750*(10**12))                   #in nm\n",
+    "print \"The range of Wavelength for the frequency of Visible lightis\",x1,\"nm to\",x2,\"nm\""
+   ]
+  }
+ ],
+ "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": "2.7.11"
+  },
+  "widgets": {
+   "state": {},
+   "version": "1.1.2"
+  }
+ },
+ "nbformat": 4,
+ "nbformat_minor": 0
+}