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| author | Trupti Kini | 2016-10-25 23:31:17 +0600 |
|---|---|---|
| committer | Trupti Kini | 2016-10-25 23:31:17 +0600 |
| commit | a1cd3e3486d6c501d0f934f425c261e193fc2b9b (patch) | |
| tree | 6e4daca1f03eeb8356003cca01147b600ec539a6 /Introduction_to_Power_Electronics_by_V._Jagannathan/chapter3.ipynb | |
| parent | a95949f9246daebf7a6549387701b105e35a4226 (diff) | |
| download | Python-Textbook-Companions-a1cd3e3486d6c501d0f934f425c261e193fc2b9b.tar.gz Python-Textbook-Companions-a1cd3e3486d6c501d0f934f425c261e193fc2b9b.tar.bz2 Python-Textbook-Companions-a1cd3e3486d6c501d0f934f425c261e193fc2b9b.zip | |
Added(A)/Deleted(D) following books
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter25.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter25_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter25_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter25_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter25_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter25_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter25_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter25_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter26.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter26_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter26_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter26_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter26_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter26_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter26_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter26_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter27.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter27_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter27_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter27_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter27_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter27_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter27_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter27_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter28.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter28_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter28_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter28_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter28_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter28_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter28_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter28_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter29.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter29_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter29_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter29_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter29_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter29_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter29_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter29_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter30.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter30_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter30_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter30_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter30_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter30_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter30_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter30_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter31.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter31_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter31_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter31_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter31_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter31_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter31_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter31_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter32.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter32_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter32_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter32_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter32_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter32_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter32_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter32_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter33.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter33_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter33_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter33_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter33_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter33_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter33_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter33_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter34.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter34_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter34_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter34_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter34_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter34_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter34_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter34_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter35.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter35_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter35_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter35_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter35_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter35_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter35_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter35_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter36.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter36_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter36_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter36_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter36_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter36_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter36_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter36_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter37.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter37_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter37_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter37_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter37_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter37_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter37_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter37_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter38.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter38_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter38_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter38_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter38_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter38_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter38_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter38_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter39.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter39_1.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter39_2.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter39_3.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter39_4.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter39_5.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter39_6.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter39_7.ipynb
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter29example32.png
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D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter32example30.png
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter32example30_1.png
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter32example30_2.png
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter32example30_3.png
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter32example30_4.png
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter32example30_5.png
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter32example30_6.png
D A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter32example30_7.png
A Introduction_to_Power_Electronics_by_V._Jagannathan/chapter2.ipynb
A Introduction_to_Power_Electronics_by_V._Jagannathan/chapter3.ipynb
A Introduction_to_Power_Electronics_by_V._Jagannathan/chapter4.ipynb
A Introduction_to_Power_Electronics_by_V._Jagannathan/chapter5.ipynb
A Introduction_to_Power_Electronics_by_V._Jagannathan/chapter7.ipynb
A Introduction_to_Power_Electronics_by_V._Jagannathan/screenshots/avgArmCurr7_.png
A Introduction_to_Power_Electronics_by_V._Jagannathan/screenshots/speedmotor7.png
A Introduction_to_Power_Electronics_by_V._Jagannathan/screenshots/triggeringangle7.png
A "sample_notebooks/ArchanaDharmasagar Kalidas/Chapter1.ipynb"
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diff --git a/Introduction_to_Power_Electronics_by_V._Jagannathan/chapter3.ipynb b/Introduction_to_Power_Electronics_by_V._Jagannathan/chapter3.ipynb new file mode 100644 index 00000000..ee71b34f --- /dev/null +++ b/Introduction_to_Power_Electronics_by_V._Jagannathan/chapter3.ipynb @@ -0,0 +1,893 @@ +{ + "cells": [ + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "# Chapter 3 - AC to DC Converters" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.1 page 117" + ] + }, + { + "cell_type": "code", + "execution_count": 1, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "Power delivered = 199.11 W\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "R=100 # ohm\n", + "Vs=230 # V\n", + "f=50 # Hz\n", + "alpha=45 # degree\n", + "\n", + "Vo=Vs*sqrt(2)/2/pi*(1+cos(pi/180*alpha)) # V\n", + "Io=Vo/R # A\n", + "Vor=Vs/sqrt(2)*sqrt(1/180*((180-alpha)+sin(pi/180*2*alpha)/2)) # V\n", + "Ior=Vor/R # A\n", + "P=Ior**2*R # W\n", + "print 'Power delivered = %.2f W'%(P)\n", + "\n", + "#Ans in the textbook is not accurate." + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.2 page 118" + ] + }, + { + "cell_type": "code", + "execution_count": 2, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "Power supplied to battery = 593 W\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,asin,cos,sin\n", + "\n", + "R=10 # ohm\n", + "E=165 # V\n", + "#vt=330*sin(314*t)\n", + "Vm=330 # V\n", + "f=314/2/pi # Hz\n", + "alpha1=asin(E/Vm) # radian\n", + "alpha2=pi-alpha1 # radian\n", + "Io=1/2/pi/R*(2*Vm*cos(alpha1)-E*(alpha2-alpha1)) # A\n", + "P=E*Io # W\n", + "\n", + "print 'Power supplied to battery = %d W'%(P)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.3 page 119" + ] + }, + { + "cell_type": "code", + "execution_count": 3, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "part (a)\n", + "\n", + " dc voltage Vo = 88.3 V\n", + "\n", + " & Current Io = 4.415 A\n", + "\n", + "\n", + " part (b)\n", + "\n", + " rms voltage Vor = 154.943 V\n", + "\n", + " & Current Ior = 7.747 A\n", + "\n", + "\n", + " part (c)\n", + "\n", + " dc Power = 389.85 W\n", + "\n", + " ac Power = 1200.37 W\n", + "\n", + " Rectification efficiency = 0.3248\n", + "\n", + "\n", + " part (d)\n", + "\n", + " Form factor = 1.755 \n", + "\n", + " Ripple factor = 1.442 \n", + "\n", + "\n", + " part (e)\n", + "\n", + " VA rating = 1781.8 VA\n", + "\n", + " Transformer Utilization factor = 0.2188\n", + "\n", + "\n", + " part (f)\n", + "\n", + " Peak inverse voltage = 325 V\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "#v2t = 325*sin(w*t)\n", + "R=20 # ohm\n", + "alfa=45 # degree\n", + "vm=325 # V\n", + "V=230 # V\n", + "print 'part (a)\\n'\n", + "Vo=vm/2/pi*(1+cos(pi/180*alfa)) # V\n", + "Io=Vo/R # A\n", + "print ' dc voltage Vo = %.1f V'%(Vo)\n", + "print '\\n & Current Io = %.3f A'%(Io)\n", + "print '\\n\\n part (b)\\n'\n", + "Vor=vm/2/sqrt(pi)*sqrt((pi-pi/180*alfa)+1/2*sin(pi/180*2*alfa)) # V\n", + "Ior=Vor/R # A\n", + "print ' rms voltage Vor = %.3f V'%(Vor)\n", + "print '\\n & Current Ior = %.3f A'%(Ior)\n", + "print '\\n\\n part (c)'\n", + "Pdc=Vo*Io # W\n", + "Pac=Vor*Ior # W\n", + "eta=Pdc/Pac # rectification efficiency\n", + "print \"\\n dc Power = %.2f W\"%(Pdc)\n", + "print \"\\n ac Power = %.2f W\"%(Pac)\n", + "print \"\\n Rectification efficiency = %.4f\"% (eta)\n", + "print '\\n\\n part (d)'\n", + "FF=Vor/Vo # form factor\n", + "RF=sqrt(FF**2-1)\n", + "print '\\n Form factor = %.3f '%(FF)\n", + "print '\\n Ripple factor = %.3f '%(RF)\n", + "print '\\n\\n part (e)'\n", + "VA=V*Ior # VA\n", + "TUF=Pdc/V/Ior # Transformer Utilization factor\n", + "print \"\\n VA rating = %.1f VA\"%(VA)\n", + "print \"\\n Transformer Utilization factor = %.4f\"%TUF\n", + "print '\\n\\n part (f)'\n", + "Vp=vm # V\n", + "print \"\\n Peak inverse voltage = %d V\"%Vp" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.4 page 120" + ] + }, + { + "cell_type": "code", + "execution_count": 4, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "(a) Average value of current = 3.60 A\n", + "\n", + " (b) Power supplied to battery = 593 W\n", + "\n", + " (c) Power dissipated in the resistor = 1216.14 W\n", + "\n", + " (d) Power factor = 0.7043\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin,asin\n", + "\n", + "R=10 # ohm\n", + "E=165 # V\n", + "#vt=330*sin(314*t)\n", + "Vm=330 # V\n", + "Vs=233 # V\n", + "f=314/2/pi # Hz\n", + "theta1=asin(E/Vm) # radian\n", + "#alpha2=pi-alpha1 # radian\n", + "Io=1/2/pi/R*(2*Vm*cos(theta1)-E*(pi-2*theta1)) # A\n", + "print '(a) Average value of current = %.2f A'%(Io)\n", + "P=E*Io # W\n", + "print '\\n (b) Power supplied to battery = %d W'%(P)\n", + "Ior=sqrt(1/2/pi/R**2*((pi-2*theta1)*(Vs**2+E**2)+Vm**2*sin(2*theta1)-4*Vm*E*cos(theta1))) # A\n", + "Pr=Ior**2*R # W\n", + "print '\\n (c) Power dissipated in the resistor = %.2f W'%(Pr)\n", + "pf=(Pr+P)/Vs/Ior # power factor\n", + "print '\\n (d) Power factor = %.4f'%(pf)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.5 page 122" + ] + }, + { + "cell_type": "code", + "execution_count": 5, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "Average load voltage = 193.2 V\n", + "\n", + " Average load current = 9.66 A\n", + "\n", + " rms load current = 11.33 A\n", + "\n", + " Average thyristor current = 4.83 A\n", + "\n", + " rms thyristor current = 8.014 A\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "R=20 # ohm\n", + "V=230 # V\n", + "f=50 # Hz\n", + "alpha=30 # degree\n", + "Vm=V*sqrt(2) # V\n", + "Vo=Vm/pi*(1+cos(alpha*pi/180)) # V\n", + "print 'Average load voltage = %.1f V'%(Vo)\n", + "Io=Vo/R # A\n", + "print '\\n Average load current = %.2f A'%( Io)\n", + "Vor=V/sqrt(pi)*sqrt((pi-alpha*pi/180)+sin(2*alpha*pi/180)/2) # V\n", + "Ior=Vor/R # A\n", + "print '\\n rms load current = %.2f A'%( Ior)\n", + "Iav=Io/2 # A\n", + "print '\\n Average thyristor current = %.2f A'%( Iav)\n", + "Irms=Ior/sqrt(2) # A\n", + "print '\\n rms thyristor current = %.3f A'%( Irms)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.6 page 122" + ] + }, + { + "cell_type": "code", + "execution_count": 6, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "Average load current = 4.642 A\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "R=10 # ohm\n", + "L=100/1000 # H\n", + "E=100 # V\n", + "Vs=230 # V\n", + "f=50 # Hz\n", + "alpha = 45 # degree\n", + "Vm=Vs*sqrt(2) # V\n", + "Vo=2*Vm/pi*cos(alpha*pi/180) # V\n", + "Io=(Vo-E)/R # A\n", + "print 'Average load current = %.3f A'%(Io)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.7 page 123" + ] + }, + { + "cell_type": "code", + "execution_count": 7, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + " Average load voltage = 179.33 V\n", + "\n", + " Average load current = 89.67 A\n", + "\n", + " Power factor = 0.7797\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "R=2 # ohm\n", + "L=0.3 # H\n", + "E=100 # V\n", + "Vs=230 # V\n", + "f=50 # Hz\n", + "alpha = 30 # degree\n", + "Vm=Vs*sqrt(2) # V\n", + "Vo=2*Vm/pi*cos(alpha*pi/180) # V\n", + "print ' Average load voltage = %.2f V'%( Vo)\n", + "Io=(Vo)/R # A\n", + "print '\\n Average load current = %.2f A'%( Io)\n", + "Is=Io # A\n", + "Is1=4*Io/pi/sqrt(2) # A\n", + "PF=Vo*Io/Vs/Is # power factor\n", + "print '\\n Power factor = %.4f'%(PF)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.8 page 123" + ] + }, + { + "cell_type": "code", + "execution_count": 8, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + " Average load voltage = 176.75 V\n", + "\n", + " Average load current = 33.35 A\n", + "\n", + " Power factor = 0.7685\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "R=5 # ohm\n", + "L=1 # H\n", + "E=10 # V\n", + "Vs=230 # V\n", + "f=50 # Hz\n", + "alpha = 45 # degree\n", + "Vm=Vs*sqrt(2) # V\n", + "Vo=Vm/pi*(1+cos(alpha*pi/180)) # V\n", + "print ' Average load voltage = %.2f V'%( Vo)\n", + "Io=(Vo-E)/R # A\n", + "print '\\n Average load current = %.2f A'%( Io)\n", + "PF=(Io**2*R+E*Io)/Vs/Io # power factor\n", + "print '\\n Power factor = %.4f'%(PF)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.9 page 124" + ] + }, + { + "cell_type": "code", + "execution_count": 9, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + " (i) Average voltage across 50 ohm resistor = 179.33 V\n", + "\n", + " (ii) rms current = 2.5361 A\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "R=50 # ohm\n", + "Vs=230 # V\n", + "f=50 # Hz\n", + "alpha = 30 # degree\n", + "Vm=Vs*sqrt(2) # V\n", + "Vo=2*Vm/pi*cos(alpha*pi/180) # V\n", + "print ' (i) Average voltage across 50 ohm resistor = %.2f V'%( Vo)\n", + "Io=(Vo)/R # A\n", + "Ior=Io/sqrt(2) # A\n", + "print '\\n (ii) rms current = %.4f A'%( Ior)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.10 page 124" + ] + }, + { + "cell_type": "code", + "execution_count": 10, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "emf on load side = 123.54 V\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "R=2 # ohm\n", + "Vs=230 # V\n", + "f=50 # Hz\n", + "alpha = 120 # degree\n", + "Ia=10 # A\n", + "\n", + "Vo=2*sqrt(2)*Vs*cos(alpha*pi/180)/pi\n", + "V=Ia*R-Vo # V\n", + "print 'emf on load side = %.2f V'%( V)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.11 page 125" + ] + }, + { + "cell_type": "code", + "execution_count": 11, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "part(i)\n", + "\n", + " dc output voltage = 146.4 V\n", + "\n", + " Active power = 732.1 W\n", + "\n", + " Reactive power = 732.1 VAR\n", + "\n", + "\n", + " part(ii)\n", + "\n", + " dc output voltage = 176.7 V\n", + "\n", + " Active power = 1066.8 W\n", + "\n", + " Reactive power = -441.9 VAR\n", + "\n", + "\n", + " part(iii)\n", + "\n", + " Average load voltage = 88 V\n", + "\n", + " Average load current = 3.02 A\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "Vs=230 # V\n", + "Io=5 # A\n", + "alpha = 45 # degree\n", + "print 'part(i)'\n", + "Vo=2*sqrt(2)*Vs/pi*cos(alpha*pi/180) # V\n", + "print '\\n dc output voltage = %.1f V'%(Vo)\n", + "Pi=Vo*Io # W\n", + "print '\\n Active power = %.1f W'%(Pi)\n", + "Qi=2*sqrt(2)*Vs/pi*sin(alpha*pi/180)*Io # VAR\n", + "print '\\n Reactive power = %.1f VAR'%(Qi)\n", + "print '\\n\\n part(ii)'\n", + "R=Vo/Io # ohm\n", + "Vo=sqrt(2)*Vs/pi*(1+cos(alpha*pi/180)) # V\n", + "print '\\n dc output voltage = %.1f V'%(Vo)\n", + "Io=Vo/R # A\n", + "Pi=Vo*Io # W\n", + "print '\\n Active power = %.1f W'%(Pi)\n", + "Qi=sqrt(2)*Vs/pi*sin(alpha*pi/4)*Io # VAR\n", + "print '\\n Reactive power = %.1f VAR'%(Qi)\n", + "print '\\n\\n part(iii)'\n", + "Vo=sqrt(2)*Vs/pi/2*(1+cos(alpha*pi/180)) # \n", + "print '\\n Average load voltage = %.0f V'%(Vo)\n", + "Io=Vo/R # A\n", + "print '\\n Average load current = %.2f A'%(Io)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.12 page 126" + ] + }, + { + "cell_type": "code", + "execution_count": 12, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "\n", + " Average load voltage = 467.818 V\n", + "\n", + " Average load current = 23.391 A\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "R=20 # ohm\n", + "Vs=400 # V\n", + "f=50 # Hz\n", + "alpha = 30 # degree\n", + "\n", + "Vm=Vs*sqrt(2) # V\n", + "Vo=3*Vm/pi*cos(alpha*pi/180) # V\n", + "Io=Vo/R # A\n", + "print '\\n Average load voltage = %.3f V'%(Vo)\n", + "print '\\n Average load current = %.3f A'%(Io)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.13 page 126" + ] + }, + { + "cell_type": "code", + "execution_count": 13, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + " (i)\n", + "\n", + " Output voltage = 270 V\n", + "\n", + " Output power = 27009 W\n", + "\n", + "\n", + " (ii)\n", + "\n", + " average current through thyristor = 33.33 A\n", + "\n", + " rms current through thyristor = 57.74 A\n", + "\n", + " peak current through thyristor = 100.00 A\n", + "\n", + "\n", + " (iii)\n", + "\n", + " PIV of thyristor = 565.7 V\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "n=3 # no. of phase\n", + "Vs=400 # V\n", + "f=50 # Hz\n", + "Io=100 # A\n", + "alpha = 60 # degree\n", + "\n", + "Vm=Vs*sqrt(2) # V\n", + "Vo=n*Vm/pi*cos(alpha*pi/180) # V\n", + "Po=Vo*Io # W\n", + "print ' (i)'\n", + "print '\\n Output voltage = %.0f V'%(Vo)\n", + "print '\\n Output power = %.0f W'%(Po)\n", + "print '\\n\\n (ii)'\n", + "Iav=Io*2*pi/3/2/pi # A\n", + "print '\\n average current through thyristor = %.2f A'%( Iav)\n", + "Ior=sqrt(Io**2*2*pi/3/2/pi) # A\n", + "print '\\n rms current through thyristor = %.2f A'%( Ior)\n", + "Ip=Io # A\n", + "print '\\n peak current through thyristor = %.2f A'%( Ip)\n", + "print '\\n\\n (iii)'\n", + "PIV=sqrt(2)*Vs # V\n", + "print '\\n PIV of thyristor = %.1f V'%(PIV)\n", + "# Ans in the book is not accurate." + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.14 page 127" + ] + }, + { + "cell_type": "code", + "execution_count": 14, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "\n", + " Average load voltage = 467.818 V\n", + "\n", + " Average load current = 7.8 A\n", + "\n", + " input power factor = 0.6752\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "n=3 # no. of phase\n", + "R=60 # ohm\n", + "Vs=400 # V\n", + "alpha = 30 # degree\n", + "\n", + "Vm=Vs*sqrt(2) # V\n", + "Vo=3*Vm/pi*cos(alpha*pi/180) # V\n", + "Io=Vo/R # A\n", + "P=Io**2*R # W\n", + "pf=P/sqrt(3)/Vs/Io # power factor\n", + "\n", + "print '\\n Average load voltage = %.3f V'%(Vo)\n", + "print '\\n Average load current = %.1f A'%(Io)\n", + "print '\\n input power factor = %.4f'%(pf)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.15 page 127" + ] + }, + { + "cell_type": "code", + "execution_count": 15, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "\n", + " Average load voltage = 461.08 V\n", + "\n", + " Average load current = 9.22 A\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin\n", + "\n", + "n=3 # no. of phase\n", + "R=50 # ohm\n", + "Vs=400 # V\n", + "f=50 # Hz\n", + "alpha = 45 # degree\n", + "\n", + "Vm=Vs*sqrt(2) # V\n", + "Vo=3*Vm/2/pi*(1+cos(alpha*pi/180)) # V\n", + "Io=Vo/R # A\n", + "print '\\n Average load voltage = %.2f V'%(Vo)\n", + "print '\\n Average load current = %.2f A'%(Io)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.16 page 128" + ] + }, + { + "cell_type": "code", + "execution_count": 16, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "\n", + " Firing angle = 33.59 degree\n", + "\n", + " Overlap angle = 10.20 degree\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin,acos\n", + "\n", + "n=3 # no. of phase\n", + "Vs=400 # V\n", + "f=50 # Hz\n", + "Ls=5/1000 # H\n", + "Io=20 # A\n", + "Ri=1 # ohm\n", + "Vdc=400 # V\n", + "\n", + "Vo=Vdc+Io*Ri # V\n", + "# Vo=3*Vm/pi*cos(alpha*pi/180)-3*2*pi*f*Ls/pi*Io\n", + "Vm=sqrt(2)*Vs # V\n", + "alpha=acos((Vo+3*2*pi*f*Ls/pi*Io)/(3*Vm/pi))*180/pi # degree\n", + "\n", + "# Vo=3*Vm/pi*cos((alpha+mu)*pi/180)-3*2*pi*f*Ls/pi*Io\n", + "mu=acos((Vo-3*2*pi*f*Ls/pi*Io)/(3*Vm/pi))*180/pi-alpha # degree\n", + "print '\\n Firing angle = %.2f degree'%(alpha)\n", + "print '\\n Overlap angle = %.2f degree'%(mu)\n", + "# ans in the textbook is not accurate." + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Ex 3.17 page 128" + ] + }, + { + "cell_type": "code", + "execution_count": 17, + "metadata": { + "collapsed": false + }, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + " Load resistance = 36 ohm\n", + "\n", + " Source inductance = 7.3 mH\n", + "\n", + " Overlap angle = 6 degree\n" + ] + } + ], + "source": [ + "from __future__ import division\n", + "from math import sqrt,pi,cos,sin,acos\n", + "\n", + "n=3 # no. of phase\n", + "Vs=400 # V\n", + "f=50 # Hz\n", + "alpha = pi/4 # radian\n", + "Io=10 # A\n", + "Vo=360 # V\n", + "\n", + "# Vo=n*Vs*sqrt(2)/pi/sqrt(2)-3*2*pi*f*Ls*Io/pi\n", + "Ls=(n*Vs*sqrt(2)/pi/sqrt(2)-Vo)/(3*2*pi*f)/(Io/pi)*1000 # mH\n", + "R=Vo/Io # ohm\n", + "print ' Load resistance = %.f ohm'%(R)\n", + "print '\\n Source inductance = %.1f mH'%(Ls)\n", + "# Vo = n*Vs*sqrt(2)/pi*cos(alpha+mu)+3*2*pi*f*Ls*Io/pi\n", + "mu=acos((Vo-3*2*pi*f*Ls/1000*Io/pi)/(n*Vs*sqrt(2)/pi))-alpha # radian\n", + "mu=mu*180/pi # degree\n", + "print '\\n Overlap angle = %.d degree'%(mu)" + ] + } + ], + "metadata": { + "kernelspec": { + "display_name": "Python 2", + "language": "python", + "name": "python2" + }, + "language_info": { + "codemirror_mode": { + "name": "ipython", + "version": 2 + }, + "file_extension": ".py", + "mimetype": "text/x-python", + "name": "python", + "nbconvert_exporter": "python", + "pygments_lexer": "ipython2", + "version": "2.7.9" + } + }, + "nbformat": 4, + "nbformat_minor": 0 +} |