From 856d4f871db9401d568629b88509a8aaf4c20626 Mon Sep 17 00:00:00 2001 From: Trupti Kini Date: Tue, 7 Mar 2017 09:55:18 +0600 Subject: Added(A)/Deleted(D) following books A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_0cfmKH1.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_0vE2Agb.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_1pO6mlQ.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_2DVKX4L.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_2tbXSIz.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_4DFRgPd.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_5BlMA37.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_6BpYQtS.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_7oQcI9D.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_7osIJcS.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_BljETDD.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_BrFEmk0.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_Cde70Gn.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_DGhuTd1.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_DnIfPiv.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_Ekp0nuF.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_HETTD7r.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_KlAE574.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_PjpHu09.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_PxZ5uHj.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_Q4fBBjq.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_T4mzLHI.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_UAITY0U.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_VEDuU8Y.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_WUGl4w9.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_a1WJQcD.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_bH5qWgx.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_e3fJkOS.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_eA2iMeu.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_eYNgYIE.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_gBECinX.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_k1gQDvp.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_kA9oA4k.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_kMX1E4Y.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_ludD60G.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_nK3AyHX.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_nbFgz6I.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_qJkWZ89.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_qaQF6hK.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_tuNOeJT.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_vEF8v8F.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_w1kpJlA.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_wmNEbtc.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_x8Hd3Fi.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A._K._Theraja,_B.L_Thereja/c_zAHS5nJ.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_2xS3kzU.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_38fwENU.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_5kVbclY.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_7O92CYB.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_7qFSSzO.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_87EQl05.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_8HPcuEd.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_ASNXGJK.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_BQB3vIT.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_BdKInur.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_CK1r2By.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_EIfrtvz.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_EnoiEf8.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_GocmY97.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_Gw8rqEI.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_HDB18kP.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_IdqLKrq.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_InkBya3.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_K9q4NLY.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_M6VOIpZ.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_MATCOZO.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_ObFCoay.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_PD3CwbT.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_PVVeE6Y.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_PdPqoEJ.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_QritHDf.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_SUaeUO3.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_TkYEtJb.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_UDdHMGf.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_VZgSOpH.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_Yj265eH.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_ZDKRJ4L.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_ZyyCtEx.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_dGjHrPW.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_egC1oo4.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_enqQgpr.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_gD58ZqH.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_gETWb31.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_gSjl2uf.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_hnPoOrk.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_hoBkBgf.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_i133Mfc.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_lFaQS0L.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_lsoSAFi.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_n2YSl8Q.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_ntrOIw3.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_nxmLE4m.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_qxxk2Xv.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_r9cPZxQ.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_tIs0JkF.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_uJFb1kJ.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_uwh7oAV.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_vwGXJQF.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_wA2NdKL.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_wXUDs09.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_x0i8ax0.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_xD8c7xw.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_xKNxc2D.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_ye04nNO.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chap_zy8Cvqw.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter25.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter26.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter27.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter28.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter29.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter30.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter31.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter32.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter33.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter34.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter35.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter36.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter37.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter38.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/chapter39.ipynb A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/screenshots/29.png A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/screenshots/32.png A A_Textbook_of_Electrical_Technology_AC_and_DC_Machines_by_A_K_Theraja_B_L_Thereja/screenshots/5.png A BSc_1st_Year_Physics_by_P._Balabhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter1.ipynb A BSc_1st_Year_Physics_by_P._Balabhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter10.ipynb A BSc_1st_Year_Physics_by_P._Balabhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter11.ipynb A BSc_1st_Year_Physics_by_P._Balabhaskar,_N._Srinivasa_Rao,_B._Sanjeeva_Rao/Chapter12.ipynb A 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BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter1.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter10.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter11.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter12.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter13.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter14.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter15.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter2.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter3.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter4.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter5.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter6.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter7.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter8.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/Chapter9.ipynb A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/screenshots/11.png A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/screenshots/22.png A BSc_3rd_Year_Physics(Paper-4)_by_Sanjeeva_Rao,_Bhikshmaiah,_Ramakrishna_Reddy,_Ananta_Ramaiah/screenshots/33.png A Electric_Drives_Concepts_And_Applications_by_Vedam_Subrahmanyam/Chapter01.ipynb A Electric_Drives_Concepts_And_Applications_by_Vedam_Subrahmanyam/Chapter03.ipynb A Electric_Drives_Concepts_And_Applications_by_Vedam_Subrahmanyam/Chapter04.ipynb A Electric_Drives_Concepts_And_Applications_by_Vedam_Subrahmanyam/Chapter05.ipynb A Electric_Drives_Concepts_And_Applications_by_Vedam_Subrahmanyam/screenshots/Ex3.4.png A Electric_Drives_Concepts_And_Applications_by_Vedam_Subrahmanyam/screenshots/Ex4.4.png A Electric_Drives_Concepts_And_Applications_by_Vedam_Subrahmanyam/screenshots/Ex4.8.png A Electronic_Communication_Systems_by_Roy_Blake/Chapter1.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter12.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter13.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter14.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter15.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter16.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter17.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter18.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter19.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter2.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter20.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter21.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter22.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter23.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter24.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter25.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter3.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter4.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter5.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter6.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter7.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter8.ipynb A Electronic_Communication_Systems_by_Roy_Blake/Chapter9.ipynb A Electronic_Communication_Systems_by_Roy_Blake/screenshots/Chapter12.png A Electronic_Communication_Systems_by_Roy_Blake/screenshots/Chapter13.png A Electronic_Communication_Systems_by_Roy_Blake/screenshots/chapter1.png A Engineering_Mechanics:_Statics_&_Engineering_Mechanics:_Dynamics_by_Meriam,_J._L.,_&_Kraige,_L._G./CHAPTER1.ipynb A Engineering_Mechanics:_Statics_&_Engineering_Mechanics:_Dynamics_by_Meriam,_J._L.,_&_Kraige,_L._G./CHAPTER2.ipynb A Engineering_Mechanics:_Statics_&_Engineering_Mechanics:_Dynamics_by_Meriam,_J._L.,_&_Kraige,_L._G./CHAPTER3.ipynb A Engineering_Mechanics:_Statics_&_Engineering_Mechanics:_Dynamics_by_Meriam,_J._L.,_&_Kraige,_L._G./CHAPTER4.ipynb A Engineering_Mechanics:_Statics_&_Engineering_Mechanics:_Dynamics_by_Meriam,_J._L.,_&_Kraige,_L._G./CHAPTER5.ipynb A Engineering_Mechanics:_Statics_&_Engineering_Mechanics:_Dynamics_by_Meriam,_J._L.,_&_Kraige,_L._G./CHAPTER6.ipynb A Engineering_Mechanics:_Statics_&_Engineering_Mechanics:_Dynamics_by_Meriam,_J._L.,_&_Kraige,_L._G./CHAPTER7.ipynb A Engineering_Mechanics:_Statics_&_Engineering_Mechanics:_Dynamics_by_Meriam,_J._L.,_&_Kraige,_L._G./CHAPTER8.ipynb A Engineering_Mechanics:_Statics_&_Engineering_Mechanics:_Dynamics_by_Meriam,_J._L.,_&_Kraige,_L._G./screenshots/figure1.png A Engineering_Mechanics:_Statics_&_Engineering_Mechanics:_Dynamics_by_Meriam,_J._L.,_&_Kraige,_L._G./screenshots/figure2.png A Engineering_Mechanics:_Statics_&_Engineering_Mechanics:_Dynamics_by_Meriam,_J._L.,_&_Kraige,_L._G./screenshots/figure3.png A 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The_Elements_of_Physical_Chemistry_by_S._Glasstone/Chapter19.ipynb A The_Elements_of_Physical_Chemistry_by_S._Glasstone/Chapter4.ipynb A The_Elements_of_Physical_Chemistry_by_S._Glasstone/Chapter5.ipynb A The_Elements_of_Physical_Chemistry_by_S._Glasstone/Chapter6.ipynb A The_Elements_of_Physical_Chemistry_by_S._Glasstone/Chapter7.ipynb A The_Elements_of_Physical_Chemistry_by_S._Glasstone/Chapter8.ipynb A The_Elements_of_Physical_Chemistry_by_S._Glasstone/Chapter9.ipynb A The_Elements_of_Physical_Chemistry_by_S._Glasstone/screenshots/Chapter4.png A The_Elements_of_Physical_Chemistry_by_S._Glasstone/screenshots/Chapter5.png A The_Elements_of_Physical_Chemistry_by_S._Glasstone/screenshots/Chapter6.png A "sample_notebooks/Sushovan Jena/Chapter1.ipynb" --- .../chapter_14.ipynb | 1083 ++++++++++++++++++++ 1 file changed, 1083 insertions(+) create mode 100644 Engineering_Mechanics_by_R.K_Bansal/chapter_14.ipynb (limited to 'Engineering_Mechanics_by_R.K_Bansal/chapter_14.ipynb') diff --git a/Engineering_Mechanics_by_R.K_Bansal/chapter_14.ipynb b/Engineering_Mechanics_by_R.K_Bansal/chapter_14.ipynb new file mode 100644 index 00000000..405ac8f2 --- /dev/null +++ b/Engineering_Mechanics_by_R.K_Bansal/chapter_14.ipynb @@ -0,0 +1,1083 @@ +{ + "metadata": { + "name": "chapter 14.ipynb" + }, + "nbformat": 3, + "nbformat_minor": 0, + "worksheets": [ + { + "cells": [ + { + "cell_type": "heading", + "level": 1, + "metadata": {}, + "source": [ + "Chapter 14:Projectiles" + ] + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.1,Page No.507 " + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "alpha=60 #Degrees\n", + "R=5000 #m #Horizontal Range\n", + "g=9.81 #m/s**2 #Acceleration due to gravity\n", + "\n", + "#Calculation\n", + "\n", + "#By equation of Horizontal Range,we get\n", + "u=((R*g)*(sin(2*alpha*pi*180**-1))**-1)**0.5 #m/s\n", + "\n", + "#Max Height attained by projectile\n", + "h_max=u**2*(sin(alpha*pi*180**-1))**2*(2*g)**-1\n", + "\n", + "#Result\n", + "print\"Velocity of projection is\",round(u,2),\"m/s\"\n", + "print\"Max Height attained by projectile is\",round(h_max,2),\"m\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Velocity of projection is 237.99 m/s\n", + "Max Height attained by projectile is 2165.06 m\n" + ] + } + ], + "prompt_number": 1 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.2,Page No.507" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "u=100 #m/s #Velocity\n", + "alpha=30 #Degrees #Angle made by projectile with horizontal\n", + "g=9.81 #m/s #Acceleration due to gravity\n", + "\n", + "#Calculation\n", + "\n", + "#Horizontal Range\n", + "R=u**2*sin(2*alpha*pi*180**-1)*g**-1 #m\n", + "\n", + "#MAx height attained\n", + "h_max=u**2*sin(alpha*pi*180**-1)*g**-1 #m\n", + "\n", + "#Time of flight\n", + "T=2*u*sin(alpha*pi*180**-1)*g**-1 #s\n", + "\n", + "#Result\n", + "print\"Horizontal Range is\",round(R,2),\"m\"\n", + "print\"MAx Height attained is\",round(h_max,2),\"m\"\n", + "print\"Time of Flight is\",round(T,2),\"s\" " + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Horizontal Range is 882.8 m\n", + "MAx Height attained is 509.68 m\n", + "Time of Flight is 10.19 s\n" + ] + } + ], + "prompt_number": 2 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.3,Page No.508" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "#R=4*h_max\n", + "\n", + "#Calculation\n", + "\n", + "#Equation ofhorizontal Range is\n", + "#R=u**2*sin(2*alpha)*g**-1 .........1\n", + "\n", + "#Equation of MAx height \n", + "#h_max=u**2*sin(alpha)**2*(2*g)**-1 .........2\n", + "\n", + "#After simplifying both equations,we get\n", + "alpha=arctan(1)*(pi**-1*180)\n", + "\n", + "#Result\n", + "print\"Angle of projections is\",round(alpha,2),\"degrees\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Angle of projections is 45.0 degrees\n" + ] + } + ], + "prompt_number": 3 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.4,Page No.508" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "u=20 #m/s #Velocity\n", + "x=20 #m #X cordinate of trajectory\n", + "y=8 #m #Y cordinate of trajectory\n", + "\n", + "#Calculation\n", + "\n", + "#equation of trajectory\n", + "#y=x*tan(alpha)-g*x**2*(2*u**2*cos(alpha)**2)**-1\n", + "#After substituting values and further simplifying we get quadratic equation\n", + "#4.905*(tan(alpha))**2-20*tan(alpha)+12.905=0\n", + "a=4.905\n", + "b=-20\n", + "c=12.905\n", + "\n", + "X=b**2-4*a*c\n", + "\n", + "y1=(-b+X**0.5)*(2*a)**-1\n", + "y2=(-b-X**0.5)*(2*a)**-1\n", + "\n", + "alpha1=arctan(y1)*(pi**-1*180) #Degrees\n", + "alpha2=arctan(y2)*(pi**-1*180) #Degrees\n", + "\n", + "#Result\n", + "print\"Angle of projection of particle is:alpha1\",round(alpha1,2),\"Degrees\"\n", + "print\" :alpha2\",round(alpha2,2),\"Degrees\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Angle of projection of particle is:alpha1 73.01 Degrees\n", + " :alpha2 38.79 Degrees\n" + ] + } + ], + "prompt_number": 4 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.5,Page No.509" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "\n", + "x=4.8 #m #X-cord of projectile\n", + "y=3.6 #m #y-cord of projectile\n", + "alpha=60 #Degrees #Inclination of jet\n", + "g=9.81 #m/s**2\n", + "\n", + "#Calculation\n", + "\n", + "#Equation of trajectory\n", + "#y=x*tan(alpha)-g*x**2*(2*u**2*cos(alpha)**2)**-1\n", + "#After further simplifying we get\n", + "u=((g*x**2)*(2*(cos(alpha*pi*180**-1))**2*((x*tan(alpha*pi*180**-1))-y))**-1)**0.5 #m/s\n", + "\n", + "#Result\n", + "print\"required velocity of jet at nozzle exit is\",round(u,2),\"m/s\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "required velocity of jet at nozzle exit is 9.79 m/s\n" + ] + } + ], + "prompt_number": 5 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.6,Page No.510" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "\n", + "u=250 #m/s #Velocity\n", + "x=4000 #m #x-cord\n", + "y=700 #m #y-cord\n", + "\n", + "#Calculation\n", + "\n", + "#equation of trajectory\n", + "#y=x*tan(alpha)-g*x**2*(2*u**2*cos(alpha)**2)**-1\n", + "#After substituting values and further simplifying we get quadratic equation\n", + "#1255.68*tan(alpha)**2-4000*tan(alpha)+1955.68=0\n", + "a=1255.68\n", + "b=-4000\n", + "c=1955.68\n", + "\n", + "X=b**2-4*a*c\n", + "\n", + "y1=(-b+X**0.5)*(2*a)**-1\n", + "y2=(-b-X**0.5)*(2*a)**-1\n", + "\n", + "alpha1=arctan(y1)*(pi**-1*180) #Degrees\n", + "alpha2=arctan(y2)*(pi**-1*180) #Degrees\n", + "\n", + "#Result\n", + "print\"Firing angle to hit the target is:alpha1\",round(alpha1,2),\"Degrees\"\n", + "print\" :alpha2\",round(alpha2,2),\"Degrees\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Firing angle to hit the target is:alpha1 68.83 Degrees\n", + " :alpha2 31.09 Degrees\n" + ] + } + ], + "prompt_number": 6 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.7,Page No.511" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "\n", + "alpha1=15 #Degrees #Angle of projectile 1\n", + "alpha2=45 #Degrees #Angle of projectile2\n", + "g=9.81 #m/s**2\n", + "#R1=R-12\n", + "#R2=R+24\n", + "\n", + "#Calculation\n", + "\n", + "#form Equation of horizontal Range we get,\n", + "#R-12=u**2*sin(2*alpha1)*g**-1 ..................1\n", + "\n", + "#R+24=u**2*sin(2*alpha2)*g**-1 ....................2\n", + "\n", + "#Dividing equation 1 by 2 and further simplifying we get\n", + "R=24+24 #m\n", + "\n", + "#Sub value of R in equation 2 we get\n", + "#u**2=g*72\n", + "\n", + "#Sub values of R and u**2 in equation of horizontal range we get\n", + "#sin(2*alpha)=R*g*(g*72)**-1\n", + "#LEt sin(2*alpha)=X\n", + "X=R*g*(g*72)**-1\n", + "alpha=(arcsin(X)*(180*pi**-1))*2**-1\n", + "\n", + "#Result\n", + "print\"Angle of projection to hit the mark is\",round(alpha,2)" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Angle of projection to hit the mark is 20.91\n" + ] + } + ], + "prompt_number": 7 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.8,Page No.512" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "\n", + "u=100 #m/s #initial Velocity\n", + "alpha=30 #DEgrees #Angle of projection\n", + "g=9.81 #m/s**2\n", + "h=80 #m #Height below B\n", + "\n", + "#Calculation\n", + "\n", + "#Max Height \n", + "H=u**2*(sin(alpha*pi*180**-1))**2*(2*g)**-1 #m\n", + "\n", + "#Vertical Distance\n", + "S=H+h #m\n", + "\n", + "#Vertical Component of velocity striking the target\n", + "v2=(2*g*S)**0.5 #m/s\n", + "\n", + "#Horizontal component of velocity\n", + "v=u*cos(alpha*pi*180**-1)\n", + "\n", + "#Actual Velocity with which bullet strikes the target\n", + "V=(v2**2+v**2)**0.5\n", + "\n", + "#Angle made by actual velocity striking velocity\n", + "theta=arctan(v2*v**-1)*(pi**-1*180)\n", + "\n", + "#Result\n", + "print\"Max height attained by bullet\",round(H,2),\"m\"\n", + "print\"Actual Velocity with which it will strike the target\",round(theta,2),\"Degrees\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Max height attained by bullet 127.42 m\n", + "Actual Velocity with which it will strike the target 36.38 Degrees\n" + ] + } + ], + "prompt_number": 8 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.9,Page No.514" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "h=150 #m #Height of cliff\n", + "u=180 #m/s #Initial Velocity\n", + "alpha=30 #ANgle of projection\n", + "\n", + "#Calculation\n", + "\n", + "#From equation of vertical Distance\n", + "#y=u*sin(Alpha)*t-0.5*g*t**2\n", + "#Sub values and further simplifying we get\n", + "#4.905t**2-90*t-150=0\n", + "a=4.905 \n", + "b=-90\n", + "c=-150\n", + "\n", + "X=(b**2-4*a*c)**0.5\n", + "\n", + "#Total time of flight\n", + "t=(-b+(X))*(2*a)**-1\n", + "\n", + "#Horizontal Distance \n", + "h1=u*cos(alpha*pi*180**-1)*t\n", + "\n", + "#MAx Height \n", + "H=u**2*sin(alpha*pi*180**-1)**2*(2*g)**-1 #m\n", + "\n", + "#ELEvation above the ground\n", + "H2=h+H #m\n", + "\n", + "#Result\n", + "print\"Horizontal Distance from gun is\",round(h1,2),\"m\"\n", + "print\"Elevation above the ground\",round(H2,2),\"m\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Horizontal Distance from gun is 3099.98 m\n", + "Elevation above the ground 562.84 m\n" + ] + } + ], + "prompt_number": 9 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.10,Page No.515" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "\n", + "h=6 #m #Height of tunnel\n", + "u=50 #m/s #Initial Velocity\n", + "g=9.81\n", + "\n", + "#Calculation\n", + "\n", + "alpha=arcsin(((h*2*g)*((u**2)**-1))**0.5)*(pi**-1*180)\n", + "\n", + "#Horizontal Range \n", + "R=u**2*sin(2*alpha*pi*180**-1)*g**-1\n", + "\n", + "#Result\n", + "print\"Angle of projection is\",round(alpha,2),\"DEgrees\"\n", + "print\"Horizontal Range is\",round(R,2),\"m\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Angle of projection is 12.53 DEgrees\n", + "Horizontal Range is 107.96 m\n" + ] + } + ], + "prompt_number": 10 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.11,Page No.516" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "alpha1=30 #Degrees #Angle of projection1\n", + "alpha2=30 #Degrees #Angle of projection2\n", + "u1=350 #m/s #Velocity of projection at A\n", + "u2=300 #m/s #Velocity of projection at B\n", + "L_AB=30 #m #distance between A nd B\n", + "g=9.81 #m/s**2 \n", + "\n", + "#Calculation\n", + "\n", + "#Length AD\n", + "L_AD=L_AB*cos(alpha1*pi*180**-1)\n", + "\n", + "#Horizontal component of velocity at A\n", + "V_A=u1*cos(alpha1*pi*180) #m/s\n", + "\n", + "#Horizontal component of velocity at B\n", + "V_B=u2*cos(alpha2*pi*180) #m/s\n", + "\n", + "#Horizontal Distance covered by shot A\n", + "#x=(u1*cos(alpha1)*t ..........................1\n", + "\n", + "#Horizontal Distance covered by shot B\n", + "#15*(3)**0.5-x=(u2*cos(alpha2))*t ................2\n", + "\n", + "#Adding Equations 1 and 2 we get\n", + "t=15*(3)**0.5*((u1+u2)*cos(alpha1*pi*180**-1))**-1\n", + "\n", + "#sub values in equation 1 we get\n", + "x=(u1*cos(alpha1*pi*180**-1))*t\n", + "\n", + "#Intial velocity shot in vertical direction\n", + "V2=u1*sin(alpha1*pi*180**-1) #m/s\n", + "\n", + "#Distance in vertical direction\n", + "y=V2*t-g*t**2*2**-1\n", + "\n", + "#Result\n", + "print\"Time when these two shots meet\",round(t,2),\"s\"\n", + "print\"Vertical Distance at which they meet\",round(y,3),\"m\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Time when these two shots meet 0.05 s\n", + "Vertical Distance at which they meet 8.066 m\n" + ] + } + ], + "prompt_number": 11 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.12,Page No.518" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "v=720*10**3*3600**-1 #m/s #Speed of air craft\n", + "u=200 #m/s #Velocity of bomb\n", + "H=1000 #m #Height\n", + "\n", + "#Calculation\n", + "\n", + "#Time requaired by bomb\n", + "t=(H*2*g**-1)**0.5 #s\n", + "\n", + "#Horizontal distance of air craft\n", + "h=u*round(t,3) #m\n", + "\n", + "#Result\n", + "print\"Time requaired by bomb to reach the ground\",round(t,2),\"s\"\n", + "print\"Horizontal distance of air craft\",round(h,2),\"m\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Time requaired by bomb to reach the ground 14.28 s\n", + "Horizontal distance of air craft 2855.6 m\n" + ] + } + ], + "prompt_number": 12 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.13,Page No.519" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "\n", + "v=108*10**3*3600**-1 #m/s #Spedd of air craft\n", + "u=30 #m/s #Horizontal Velocity\n", + "H=1000 #m #Height\n", + "g=9.81 #m/s**2\n", + "\n", + "#Calculation\n", + "\n", + "#Time taken by bomb\n", + "t=(H*2*g**-1)**0.5 #s\n", + "\n", + "#Horizontal Distance OB\n", + "h=u*t #m\n", + "\n", + "#Velocity of bomb hitting the ground\n", + "V=g*t #m/s**2\n", + "\n", + "#Resultant Velocity\n", + "V2=(u**2+V**2)**0.5 #m/s\n", + "\n", + "#Direction in which the bomb hits the ground\n", + "theta=arctan(V*u**-1)*(180*pi**-1)\n", + "\n", + "#Result\n", + "print\"HOrizontal Distance of air craft from target\",round(h,2),\"m\"\n", + "print\"Velocity of bomb\",round(V2,2),\"m/s\"\n", + "print\"Direction of bomb\",round(theta,2),\"Degrees\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "HOrizontal Distance of air craft from target 428.35 m\n", + "Velocity of bomb 143.25 m/s\n", + "Direction of bomb 77.91 Degrees\n" + ] + } + ], + "prompt_number": 13 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.14,Page No.520" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "H=2000 #m #Height of aeroplane\n", + "u=10**6*3600**-1 #Velocity of plane #m/s\n", + "g=9.8 #m/s**2\n", + "\n", + "#Calculation\n", + "\n", + "#Time required by bomb\n", + "t=(2*H*g**-1)**0.5 #s\n", + "\n", + "#Horizontal Distance travelled by bomb\n", + "h=u*t #m\n", + "\n", + "#Result\n", + "print\"Time required by bomb to reach the ground\",round(t,2),\"s\"\n", + "print\"Horizontal Distance travelled by bomb\",round(h,2),\"m\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Time required by bomb to reach the ground 20.2 s\n", + "Horizontal Distance travelled by bomb 5611.96 m\n" + ] + } + ], + "prompt_number": 14 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.16,Page No.521" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "L_AB1=4 #m #LEngth of AB in Horizontal Distance\n", + "L_AB2=2 #m #LEngth of AB in Vertical Distance\n", + "g=9.81 #m/s**2 \n", + "\n", + "#Calculation\n", + "\n", + "#time\n", + "t=((L_AB2*2)*(9.81)**-1)**0.5\n", + "\n", + "#Minimum veloacity of motorcyclye at A in Horizontal Direction\n", + "u=L_AB1*t**-1 #m/s\n", + "\n", + "#Vertical Component of velocity\n", + "v=g*t #m/s\n", + "\n", + "#Resultant velocity at B\n", + "V=(u**2+v**2)**0.5*3600*(10**3)**-1 #km/hr\n", + "\n", + "#Inclination\n", + "theta=arctan(v*u**-1)*(180*pi**-1)\n", + "\n", + "#Result\n", + "print\"Inclination of motorcycle clearing the ditch\",round(theta,2),\"Degrees\"\n", + "print\"MAgnitude of velocity of motorcycleafter clearing ditch\",round(V,2),\"km/hr\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Inclination of motorcycle clearing the ditch 45.0 Degrees\n", + "MAgnitude of velocity of motorcycleafter clearing ditch 31.89 km/hr\n" + ] + } + ], + "prompt_number": 15 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.17,Page No.522" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "alpha=25 #Degrees #Angle of ramp\n", + "L_BC1=4 #m #Horizontal Distance between B and C\n", + "L_BC2=2 #m #vertical Distance between B and C\n", + "g=9.81 #m/s**2\n", + "\n", + "#Calculation\n", + "\n", + "##From equation of path \n", + "X=(L_BC2+L_BC1*tan(alpha*pi*180**-1))\n", + "Y=(g*L_BC1**2)*(2*(cos(alpha*pi*180**-1))**2)**-1\n", + "u=(X**-1*Y)**0.5\n", + "\n", + "#Result\n", + "print\"Minimum speed of motorcycle is\",round(u,2),\"m/s\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Minimum speed of motorcycle is 4.97 m/s\n" + ] + } + ], + "prompt_number": 16 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.18,Page No.526" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "u=40 #m/s #Velocity of projection\n", + "alpha=50 #Degrees #Angle of projection\n", + "beta=20 #degrees #Ang;e if incline plane\n", + "\n", + "#Calculation\n", + "\n", + "#Time of flight\n", + "T=2*u*sin((alpha-beta)*pi*180**-1)*(g*cos(beta*pi*180**-1))**-1\n", + "\n", + "#Range \n", + "R=2*u**2*cos(alpha*pi*180**-1)*sin((alpha-beta)*pi*180**-1)*(g*(cos(beta*pi*180**-1))**2)**-1\n", + "\n", + "#Let alpha2 be the angle of projection for max range\n", + "alpha2=(90+beta)*2**-1\n", + "\n", + "#MAx range up the plane\n", + "R2=u**2*(g*(1+sin(beta*pi*180**-1)))**-1\n", + "\n", + "#Result\n", + "print\"Time of flight is\",round(T,2),\"s\"\n", + "print\"range up the plane is\",round(R,2),\"m\"\n", + "print\"Max range up the plane\",round(R2,2),\"m\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Time of flight is 4.34 s\n", + "range up the plane is 118.73 m\n", + "Max range up the plane 121.53 m\n" + ] + } + ], + "prompt_number": 17 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.19,Page No.527" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "\n", + "u=30 #m/s #velocity\n", + "alpha=55 #angle of projection\n", + "beta=20 #angle of plane\n", + "g=9.81\n", + "\n", + "#Calculation\n", + "#Maximum Range\n", + "R=u**2*(g*(1+sin(beta*pi*180**-1)))**-1 #m\n", + "\n", + "#Time of Flight\n", + "T=2*u*sin((alpha-beta)*pi*180**-1)*(g*cos(beta*pi*180**-1))**-1\n", + "\n", + "#Result\n", + "print\"Time of Fliight is\",round(T,2),\"s\"\n", + "print\"Maximum Range is \",round(R,2),\"m\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Time of Fliight is 3.73 s\n", + "Maximum Range is 68.36 m\n" + ] + } + ], + "prompt_number": 18 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.20,Page No.527" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "\n", + "u=3 #m/s #Velocity of projection\n", + "alpha=25 #Degrees #Angle of projection\n", + "beta=25 #degrees #Angle of plane with horizontal\n", + "g=9.81 #m/s**2\n", + "\n", + "#Calculation\n", + "\n", + "#Range\n", + "R=2*u**2*cos(alpha*pi*180**-1)*sin((alpha+beta)*pi*180**-1)*(g*(cos(beta*pi*180**-1))**2)**-1\n", + "\n", + "#L_BC=y\n", + "#L_AC=x\n", + "\n", + "#From tan(beta) we get\n", + "#y=0.466*x .................(1)\n", + "\n", + "#From Equation (L_AB)**2=(L_BC**2+L_AC)**2\n", + "#After sub values and further simplifying we get\n", + "x=(2.4*(1.217)**-1)**0.5 #m\n", + "\n", + "#Sub in equation 1 we get\n", + "y=0.466*x\n", + "\n", + "#Result\n", + "print\"Co-ordinates of point B are:x\",round(x,2),\"m\"\n", + "print\" :y\",round(y,2),\"m\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Co-ordinates of point B are:x 1.4 m\n", + " :y 0.65 m\n" + ] + } + ], + "prompt_number": 12 + }, + { + "cell_type": "heading", + "level": 2, + "metadata": {}, + "source": [ + "Example 14.21,Page No.528" + ] + }, + { + "cell_type": "code", + "collapsed": false, + "input": [ + "import math\n", + "\n", + "#Initilization of Variables\n", + "\n", + "L_AB=75 #m #LEngth of AB\n", + "h=19.6 #m #Height of point of release\n", + "beta=26.564 #Degrees #angle of plane \n", + "\n", + "#Calculation\n", + "\n", + "#Length AC\n", + "L_AC=L_AB*cos(beta*pi*180**-1) #m\n", + "\n", + "#From horizontal Distance \n", + "#u*cos(alpha)=L_AC*t**-1 .............1\n", + "\n", + "#Vertical motion motion from point of release\n", + "#u*sin(alpha)=19.6 ....................2\n", + "\n", + "#vertical Distance\n", + "y=L_AB*sin(beta*pi*180**-1) #m\n", + "\n", + "#Vertical distance from point of release travelled by ball\n", + "#y=u*sin(alpha)*t-0.5*g*t**2\n", + "\n", + "#sub value of y in above equation and further simplifyin we get\n", + "#t**2-4t-6.84=0\n", + "a=1\n", + "b=-4\n", + "c=-6.84\n", + "\n", + "X=b**2-4*a*c\n", + "\n", + "t=(-b+X**0.5)*(2*a)**-1\n", + "\n", + "#sub value in equation 1 we get\n", + "#Let ucos(alpha)=X\n", + "X=67.08*t**-1 #..........................3\n", + "\n", + "#Dividing equation 1 by 3 we get\n", + "alpha=arctan(19.6*12.68**-1)*(180*pi**-1)\n", + "\n", + "#sub in equation 1 we get\n", + "u=12.68*cos(alpha*pi*180**-1)**-1\n", + "\n", + "#Result\n", + "print\"Initial Velocity\",round(u,2),\"m/s\"\n", + "print\"Inclination is\",round(alpha,4),\"Degrees\"" + ], + "language": "python", + "metadata": {}, + "outputs": [ + { + "output_type": "stream", + "stream": "stdout", + "text": [ + "Initial Velocity 23.34 m/s\n", + "Inclination is 57.0996 Degrees\n" + ] + } + ], + "prompt_number": 10 + } + ], + "metadata": {} + } + ] +} \ No newline at end of file -- cgit