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61e59cd01c4b421db9405971adc08511d6fd98fc
f542bc49c4d04b47d19c88e7c89d5db60922e34e
/PresentationFiles_Subjects/CONT/XC45NLQ/ATWM1_Working_Memory_MEG_XC45NLQ_Session1/ATWM1_Working_Memory_MEG_Nonsalient_Cued_Run1.sce
142e41dd4ab42b46478287aa1311adbfa41562dc
[]
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atwm1/Presentation
65c674180f731f050aad33beefffb9ba0caa6688
9732a004ca091b184b670c56c55f538ff6600c08
refs/heads/master
2020-04-15T14:04:41.900640
2020-02-14T16:10:11
2020-02-14T16:10:11
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ATWM1_Working_Memory_MEG_Nonsalient_Cued_Run1.sce
# ATWM1 MEG Experiment scenario = "ATWM1_Working_Memory_MEG_salient_cued_run1"; #scenario_type = fMRI; # Fuer Scanner #scenario_type = fMRI_emulation; # Zum Testen scenario_type = trials; # for MEG #scan_period = 2000; # TR #pulses_per_scan = 1; #pulse_code = 1; pulse_width=6; default_monitor_sounds = false; active_buttons = 2; response_matching = simple_matching; button_codes = 10, 20; default_font_size = 36; default_font = "Arial"; default_background_color = 0 ,0 ,0 ; write_codes=true; # for MEG only begin; #Picture definitions box { height = 382; width = 382; color = 0, 0, 0;} frame1; box { height = 369; width = 369; color = 255, 255, 255;} frame2; box { height = 30; width = 4; color = 0, 0, 0;} fix1; box { height = 4; width = 30; color = 0, 0, 0;} fix2; box { height = 30; width = 4; color = 255, 0, 0;} fix3; box { height = 4; width = 30; color = 255, 0, 0;} fix4; box { height = 369; width = 369; color = 42, 42, 42;} background; TEMPLATE "StimuliDeclaration.tem" {}; trial { sound sound_incorrect; time = 0; duration = 1; } wrong; trial { sound sound_correct; time = 0; duration = 1; } right; trial { sound sound_no_response; time = 0; duration = 1; } miss; # Start of experiment (MEG only) - sync with CTF software trial { picture { box frame1; x=0; y=0; box frame2; x=0; y=0; box background; x=0; y=0; bitmap fixation_cross_black; x=0; y=0; } expStart; time = 0; duration = 1000; code = "ExpStart"; port_code = 80; }; # baselinePre (at the beginning of the session) trial { picture { box frame1; x=0; y=0; box frame2; x=0; y=0; box background; x=0; y=0; bitmap fixation_cross_black; x=0; y=0; }default; time = 0; duration = 10000; #mri_pulse = 1; code = "BaselinePre"; port_code = 91; }; TEMPLATE "ATWM1_Working_Memory_MEG.tem" { trigger_encoding trigger_retrieval cue_time preparation_time encoding_time single_stimulus_presentation_time delay_time retrieval_time intertrial_interval alerting_cross stim_enc1 stim_enc2 stim_enc3 stim_enc4 stim_enc_alt1 stim_enc_alt2 stim_enc_alt3 stim_enc_alt4 trial_code stim_retr1 stim_retr2 stim_retr3 stim_retr4 stim_cue1 stim_cue2 stim_cue3 stim_cue4 fixationcross_cued retr_code the_target_button posX1 posY1 posX2 posY2 posX3 posY3 posX4 posY4; 43 61 292 292 399 125 2242 2992 2342 fixation_cross gabor_094 gabor_160 gabor_030 gabor_177 gabor_094_alt gabor_160 gabor_030 gabor_177_alt "1_1_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2250_3000_2350_gabor_patch_orientation_094_160_030_177_target_position_2_3_retrieval_position_2" gabor_circ gabor_113_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_1_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_113_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1892 2992 2492 fixation_cross gabor_027 gabor_088 gabor_141 gabor_104 gabor_027 gabor_088 gabor_141_alt gabor_104_alt "1_2_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1900_3000_2500_gabor_patch_orientation_027_088_141_104_target_position_1_2_retrieval_position_1" gabor_164_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_2_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_164_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1842 2992 2392 fixation_cross gabor_011 gabor_122 gabor_081 gabor_034 gabor_011 gabor_122 gabor_081_alt gabor_034_alt "1_3_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1850_3000_2400_gabor_patch_orientation_011_122_081_034_target_position_1_2_retrieval_position_1" gabor_011_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_3_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_011_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1992 2992 2492 fixation_cross gabor_058 gabor_081 gabor_124 gabor_102 gabor_058_alt gabor_081 gabor_124_alt gabor_102 "1_4_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2000_3000_2500_gabor_patch_orientation_058_081_124_102_target_position_2_4_retrieval_position_2" gabor_circ gabor_081_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_4_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_081_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 2242 2992 1892 fixation_cross gabor_056 gabor_139 gabor_092 gabor_122 gabor_056 gabor_139_alt gabor_092 gabor_122_alt "1_5_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2250_3000_1900_gabor_patch_orientation_056_139_092_122_target_position_1_3_retrieval_position_1" gabor_011_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_5_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_011_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 64 292 292 399 125 1892 2992 2142 fixation_cross gabor_038 gabor_145 gabor_127 gabor_093 gabor_038_alt gabor_145 gabor_127 gabor_093_alt "1_6_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_300_300_399_1900_3000_2150_gabor_patch_orientation_038_145_127_093_target_position_2_3_retrieval_position_1" gabor_038_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_6_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_retrieval_patch_orientation_038_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1792 2992 2092 fixation_cross gabor_157 gabor_032 gabor_047 gabor_095 gabor_157_alt gabor_032 gabor_047 gabor_095_alt "1_7_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1800_3000_2100_gabor_patch_orientation_157_032_047_095_target_position_2_3_retrieval_position_2" gabor_circ gabor_032_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_7_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_032_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 2242 2992 2192 fixation_cross gabor_080 gabor_148 gabor_095 gabor_125 gabor_080 gabor_148_alt gabor_095_alt gabor_125 "1_8_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2250_3000_2200_gabor_patch_orientation_080_148_095_125_target_position_1_4_retrieval_position_1" gabor_035_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_8_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_035_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1992 2992 2292 fixation_cross gabor_100 gabor_154 gabor_049 gabor_078 gabor_100_alt gabor_154 gabor_049_alt gabor_078 "1_9_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2000_3000_2300_gabor_patch_orientation_100_154_049_078_target_position_2_4_retrieval_position_2" gabor_circ gabor_154_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_9_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_154_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1742 2992 2542 fixation_cross gabor_082 gabor_043 gabor_158 gabor_098 gabor_082 gabor_043_alt gabor_158_alt gabor_098 "1_10_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1750_3000_2550_gabor_patch_orientation_082_043_158_098_target_position_1_4_retrieval_position_1" gabor_132_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_10_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_132_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 2042 2992 1942 fixation_cross gabor_062 gabor_030 gabor_092 gabor_149 gabor_062 gabor_030_alt gabor_092_alt gabor_149 "1_11_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2050_3000_1950_gabor_patch_orientation_062_030_092_149_target_position_1_4_retrieval_position_1" gabor_111_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_11_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_111_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2142 2992 2442 fixation_cross gabor_051 gabor_121 gabor_014 gabor_139 gabor_051 gabor_121 gabor_014_alt gabor_139_alt "1_12_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2150_3000_2450_gabor_patch_orientation_051_121_014_139_target_position_1_2_retrieval_position_1" gabor_051_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_12_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_051_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 63 292 292 399 125 1842 2992 2242 fixation_cross gabor_106 gabor_129 gabor_149 gabor_167 gabor_106 gabor_129_alt gabor_149 gabor_167_alt "1_13_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_300_300_399_1850_3000_2250_gabor_patch_orientation_106_129_149_167_target_position_1_3_retrieval_position_2" gabor_circ gabor_079_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_13_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_retrieval_patch_orientation_079_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 2142 2992 2442 fixation_cross gabor_029 gabor_176 gabor_150 gabor_095 gabor_029_alt gabor_176_alt gabor_150 gabor_095 "1_14_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2150_3000_2450_gabor_patch_orientation_029_176_150_095_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_012_framed gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_14_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_012_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 63 292 292 399 125 1892 2992 1892 fixation_cross gabor_093 gabor_171 gabor_016 gabor_037 gabor_093_alt gabor_171 gabor_016_alt gabor_037 "1_15_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_300_300_399_1900_3000_1900_gabor_patch_orientation_093_171_016_037_target_position_2_4_retrieval_position_1" gabor_143_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_15_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_retrieval_patch_orientation_143_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1842 2992 2592 fixation_cross gabor_068 gabor_148 gabor_103 gabor_126 gabor_068 gabor_148_alt gabor_103_alt gabor_126 "1_16_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1850_3000_2600_gabor_patch_orientation_068_148_103_126_target_position_1_4_retrieval_position_1" gabor_019_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_16_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_019_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1842 2992 2592 fixation_cross gabor_147 gabor_131 gabor_092 gabor_003 gabor_147_alt gabor_131 gabor_092_alt gabor_003 "1_17_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1850_3000_2600_gabor_patch_orientation_147_131_092_003_target_position_2_4_retrieval_position_2" gabor_circ gabor_131_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_17_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_131_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1742 2992 2542 fixation_cross gabor_169 gabor_049 gabor_119 gabor_013 gabor_169_alt gabor_049 gabor_119_alt gabor_013 "1_18_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1750_3000_2550_gabor_patch_orientation_169_049_119_013_target_position_2_4_retrieval_position_2" gabor_circ gabor_094_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_18_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_094_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 2242 2992 2442 fixation_cross gabor_124 gabor_016 gabor_106 gabor_087 gabor_124 gabor_016_alt gabor_106_alt gabor_087 "1_19_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2250_3000_2450_gabor_patch_orientation_124_016_106_087_target_position_1_4_retrieval_position_1" gabor_170_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_19_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_170_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 2192 2992 1892 fixation_cross gabor_065 gabor_143 gabor_170 gabor_004 gabor_065 gabor_143 gabor_170_alt gabor_004_alt "1_20_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2200_3000_1900_gabor_patch_orientation_065_143_170_004_target_position_1_2_retrieval_position_2" gabor_circ gabor_093_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_20_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_093_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1842 2992 2392 fixation_cross gabor_081 gabor_148 gabor_033 gabor_116 gabor_081_alt gabor_148_alt gabor_033 gabor_116 "1_21_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1850_3000_2400_gabor_patch_orientation_081_148_033_116_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_116_framed blank blank blank blank fixation_cross_target_position_3_4 "1_21_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_116_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1942 2992 2192 fixation_cross gabor_040 gabor_001 gabor_067 gabor_178 gabor_040_alt gabor_001_alt gabor_067 gabor_178 "1_22_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1950_3000_2200_gabor_patch_orientation_040_001_067_178_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_021_framed gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_22_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_021_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 64 292 292 399 125 1842 2992 1992 fixation_cross gabor_102 gabor_057 gabor_018 gabor_129 gabor_102_alt gabor_057 gabor_018_alt gabor_129 "1_23_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_300_300_399_1850_3000_2000_gabor_patch_orientation_102_057_018_129_target_position_2_4_retrieval_position_1" gabor_102_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_23_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_retrieval_patch_orientation_102_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2242 2992 2592 fixation_cross gabor_074 gabor_014 gabor_119 gabor_037 gabor_074 gabor_014_alt gabor_119 gabor_037_alt "1_24_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2250_3000_2600_gabor_patch_orientation_074_014_119_037_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_119_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_24_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_119_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2142 2992 2092 fixation_cross gabor_016 gabor_149 gabor_081 gabor_103 gabor_016_alt gabor_149_alt gabor_081 gabor_103 "1_25_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2150_3000_2100_gabor_patch_orientation_016_149_081_103_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_081_framed gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_25_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_081_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 64 292 292 399 125 1992 2992 1942 fixation_cross gabor_156 gabor_022 gabor_080 gabor_046 gabor_156 gabor_022 gabor_080_alt gabor_046_alt "1_26_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_300_300_399_2000_3000_1950_gabor_patch_orientation_156_022_080_046_target_position_1_2_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_046_framed blank blank blank blank fixation_cross_target_position_1_2 "1_26_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_retrieval_patch_orientation_046_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1792 2992 2492 fixation_cross gabor_083 gabor_098 gabor_124 gabor_157 gabor_083 gabor_098_alt gabor_124 gabor_157_alt "1_27_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1800_3000_2500_gabor_patch_orientation_083_098_124_157_target_position_1_3_retrieval_position_1" gabor_083_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_27_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_083_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2042 2992 2092 fixation_cross gabor_120 gabor_137 gabor_162 gabor_051 gabor_120_alt gabor_137 gabor_162_alt gabor_051 "1_28_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2050_3000_2100_gabor_patch_orientation_120_137_162_051_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_051_framed blank blank blank blank fixation_cross_target_position_2_4 "1_28_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_051_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 2192 2992 2142 fixation_cross gabor_099 gabor_176 gabor_070 gabor_009 gabor_099_alt gabor_176 gabor_070_alt gabor_009 "1_29_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2200_3000_2150_gabor_patch_orientation_099_176_070_009_target_position_2_4_retrieval_position_2" gabor_circ gabor_039_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_29_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_039_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 63 292 292 399 125 1842 2992 2292 fixation_cross gabor_040 gabor_163 gabor_005 gabor_090 gabor_040_alt gabor_163_alt gabor_005 gabor_090 "1_30_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_300_300_399_1850_3000_2300_gabor_patch_orientation_040_163_005_090_target_position_3_4_retrieval_position_2" gabor_circ gabor_117_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_30_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_retrieval_patch_orientation_117_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1742 2992 1892 fixation_cross gabor_069 gabor_024 gabor_051 gabor_129 gabor_069_alt gabor_024 gabor_051_alt gabor_129 "1_31_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1750_3000_1900_gabor_patch_orientation_069_024_051_129_target_position_2_4_retrieval_position_2" gabor_circ gabor_024_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_31_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_024_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1742 2992 1942 fixation_cross gabor_177 gabor_059 gabor_098 gabor_125 gabor_177 gabor_059_alt gabor_098 gabor_125_alt "1_32_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1750_3000_1950_gabor_patch_orientation_177_059_098_125_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_148_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_32_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_148_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 2142 2992 2192 fixation_cross gabor_059 gabor_165 gabor_041 gabor_026 gabor_059_alt gabor_165 gabor_041_alt gabor_026 "1_33_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2150_3000_2200_gabor_patch_orientation_059_165_041_026_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_076_framed blank blank blank blank fixation_cross_target_position_2_4 "1_33_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_076_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 64 292 292 399 125 2192 2992 2042 fixation_cross gabor_176 gabor_041 gabor_005 gabor_124 gabor_176_alt gabor_041_alt gabor_005 gabor_124 "1_34_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_300_300_399_2200_3000_2050_gabor_patch_orientation_176_041_005_124_target_position_3_4_retrieval_position_2" gabor_circ gabor_041_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_34_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_retrieval_patch_orientation_041_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2092 2992 2292 fixation_cross gabor_051 gabor_180 gabor_074 gabor_126 gabor_051 gabor_180_alt gabor_074 gabor_126_alt "1_35_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2100_3000_2300_gabor_patch_orientation_051_180_074_126_target_position_1_3_retrieval_position_1" gabor_051_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_35_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_051_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2092 2992 2542 fixation_cross gabor_094 gabor_054 gabor_035 gabor_116 gabor_094 gabor_054_alt gabor_035 gabor_116_alt "1_36_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2100_3000_2550_gabor_patch_orientation_094_054_035_116_target_position_1_3_retrieval_position_1" gabor_094_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_36_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_094_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1792 2992 2192 fixation_cross gabor_083 gabor_017 gabor_166 gabor_054 gabor_083_alt gabor_017 gabor_166_alt gabor_054 "1_37_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1800_3000_2200_gabor_patch_orientation_083_017_166_054_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_054_framed blank blank blank blank fixation_cross_target_position_2_4 "1_37_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_054_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1742 2992 2492 fixation_cross gabor_034 gabor_169 gabor_063 gabor_144 gabor_034_alt gabor_169_alt gabor_063 gabor_144 "1_38_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1750_3000_2500_gabor_patch_orientation_034_169_063_144_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_063_framed gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_38_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_063_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1892 2992 2042 fixation_cross gabor_070 gabor_128 gabor_022 gabor_039 gabor_070 gabor_128_alt gabor_022 gabor_039_alt "1_39_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1900_3000_2050_gabor_patch_orientation_070_128_022_039_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_159_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_39_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_159_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1942 2992 1992 fixation_cross gabor_018 gabor_095 gabor_055 gabor_080 gabor_018 gabor_095 gabor_055_alt gabor_080_alt "1_40_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1950_3000_2000_gabor_patch_orientation_018_095_055_080_target_position_1_2_retrieval_position_2" gabor_circ gabor_095_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_40_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_095_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 63 292 292 399 125 2192 2992 1942 fixation_cross gabor_121 gabor_094 gabor_138 gabor_032 gabor_121_alt gabor_094_alt gabor_138 gabor_032 "1_41_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_300_300_399_2200_3000_1950_gabor_patch_orientation_121_094_138_032_target_position_3_4_retrieval_position_1" gabor_166_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_41_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_retrieval_patch_orientation_166_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 2092 2992 2242 fixation_cross gabor_143 gabor_168 gabor_097 gabor_059 gabor_143_alt gabor_168 gabor_097_alt gabor_059 "1_42_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2100_3000_2250_gabor_patch_orientation_143_168_097_059_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_011_framed blank blank blank blank fixation_cross_target_position_2_4 "1_42_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_011_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2242 2992 2442 fixation_cross gabor_094 gabor_078 gabor_008 gabor_142 gabor_094_alt gabor_078_alt gabor_008 gabor_142 "1_43_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2250_3000_2450_gabor_patch_orientation_094_078_008_142_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_008_framed gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_43_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_008_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2192 2992 2342 fixation_cross gabor_007 gabor_096 gabor_158 gabor_072 gabor_007 gabor_096_alt gabor_158_alt gabor_072 "1_44_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2200_3000_2350_gabor_patch_orientation_007_096_158_072_target_position_1_4_retrieval_position_1" gabor_007_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_44_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_007_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1792 2992 2142 fixation_cross gabor_009 gabor_174 gabor_093 gabor_060 gabor_009_alt gabor_174_alt gabor_093 gabor_060 "1_45_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1800_3000_2150_gabor_patch_orientation_009_174_093_060_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_142_framed gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_45_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_142_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1942 2992 2392 fixation_cross gabor_018 gabor_087 gabor_123 gabor_176 gabor_018_alt gabor_087_alt gabor_123 gabor_176 "1_46_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1950_3000_2400_gabor_patch_orientation_018_087_123_176_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_037_framed blank blank blank blank fixation_cross_target_position_3_4 "1_46_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_037_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1792 2992 2292 fixation_cross gabor_110 gabor_020 gabor_176 gabor_130 gabor_110 gabor_020_alt gabor_176_alt gabor_130 "1_47_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1800_3000_2300_gabor_patch_orientation_110_020_176_130_target_position_1_4_retrieval_position_1" gabor_110_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_47_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_110_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 63 292 292 399 125 1892 2992 2242 fixation_cross gabor_115 gabor_135 gabor_049 gabor_167 gabor_115_alt gabor_135 gabor_049_alt gabor_167 "1_48_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_300_300_399_1900_3000_2250_gabor_patch_orientation_115_135_049_167_target_position_2_4_retrieval_position_3" gabor_circ gabor_circ gabor_095_framed gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_48_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_retrieval_patch_orientation_095_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1992 2992 2242 fixation_cross gabor_138 gabor_109 gabor_023 gabor_157 gabor_138 gabor_109_alt gabor_023 gabor_157_alt "1_49_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2000_3000_2250_gabor_patch_orientation_138_109_023_157_target_position_1_3_retrieval_position_1" gabor_138_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_49_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_138_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1892 2992 2342 fixation_cross gabor_178 gabor_089 gabor_052 gabor_140 gabor_178_alt gabor_089_alt gabor_052 gabor_140 "1_50_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1900_3000_2350_gabor_patch_orientation_178_089_052_140_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_140_framed blank blank blank blank fixation_cross_target_position_3_4 "1_50_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_140_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1742 2992 2142 fixation_cross gabor_039 gabor_111 gabor_054 gabor_160 gabor_039 gabor_111_alt gabor_054_alt gabor_160 "1_51_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1750_3000_2150_gabor_patch_orientation_039_111_054_160_target_position_1_4_retrieval_position_1" gabor_085_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_51_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_085_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 63 292 292 399 125 2092 2992 2042 fixation_cross gabor_023 gabor_134 gabor_109 gabor_050 gabor_023_alt gabor_134_alt gabor_109 gabor_050 "1_52_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_300_300_399_2100_3000_2050_gabor_patch_orientation_023_134_109_050_target_position_3_4_retrieval_position_1" gabor_161_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_52_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_retrieval_patch_orientation_161_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2042 2992 1992 fixation_cross gabor_170 gabor_132 gabor_013 gabor_153 gabor_170_alt gabor_132 gabor_013 gabor_153_alt "1_53_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2050_3000_2000_gabor_patch_orientation_170_132_013_153_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_013_framed gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_53_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_013_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1892 2992 1942 fixation_cross gabor_040 gabor_090 gabor_066 gabor_009 gabor_040 gabor_090_alt gabor_066_alt gabor_009 "1_54_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1900_3000_1950_gabor_patch_orientation_040_090_066_009_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_149_framed blank blank blank blank fixation_cross_target_position_1_4 "1_54_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_149_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1992 2992 2592 fixation_cross gabor_135 gabor_046 gabor_179 gabor_028 gabor_135 gabor_046_alt gabor_179 gabor_028_alt "1_55_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2000_3000_2600_gabor_patch_orientation_135_046_179_028_target_position_1_3_retrieval_position_1" gabor_090_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_55_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_090_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2192 2992 2292 fixation_cross gabor_108 gabor_143 gabor_080 gabor_022 gabor_108 gabor_143_alt gabor_080 gabor_022_alt "1_56_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2200_3000_2300_gabor_patch_orientation_108_143_080_022_target_position_1_3_retrieval_position_1" gabor_108_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_56_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_108_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 63 292 292 399 125 1942 2992 2542 fixation_cross gabor_019 gabor_100 gabor_079 gabor_159 gabor_019_alt gabor_100_alt gabor_079 gabor_159 "1_57_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_300_300_399_1950_3000_2550_gabor_patch_orientation_019_100_079_159_target_position_3_4_retrieval_position_2" gabor_circ gabor_050_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_3_4 "1_57_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_UncuedRetriev_retrieval_patch_orientation_050_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2142 2992 1892 fixation_cross gabor_051 gabor_019 gabor_078 gabor_130 gabor_051_alt gabor_019 gabor_078 gabor_130_alt "1_58_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2150_3000_1900_gabor_patch_orientation_051_019_078_130_target_position_2_3_retrieval_position_2" gabor_circ gabor_019_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_58_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_019_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1792 2992 2242 fixation_cross gabor_063 gabor_043 gabor_016 gabor_180 gabor_063_alt gabor_043 gabor_016_alt gabor_180 "1_59_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1800_3000_2250_gabor_patch_orientation_063_043_016_180_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_133_framed blank blank blank blank fixation_cross_target_position_2_4 "1_59_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_133_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 64 292 292 399 125 1942 2992 2092 fixation_cross gabor_013 gabor_094 gabor_073 gabor_032 gabor_013 gabor_094 gabor_073_alt gabor_032_alt "1_60_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_300_300_399_1950_3000_2100_gabor_patch_orientation_013_094_073_032_target_position_1_2_retrieval_position_3" gabor_circ gabor_circ gabor_073_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_2 "1_60_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_retrieval_patch_orientation_073_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 2042 2992 2042 fixation_cross gabor_084 gabor_036 gabor_015 gabor_157 gabor_084_alt gabor_036 gabor_015_alt gabor_157 "1_61_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2050_3000_2050_gabor_patch_orientation_084_036_015_157_target_position_2_4_retrieval_position_2" gabor_circ gabor_173_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_61_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_173_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1992 2992 1992 fixation_cross gabor_040 gabor_128 gabor_006 gabor_090 gabor_040 gabor_128_alt gabor_006 gabor_090_alt "1_62_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2000_3000_2000_gabor_patch_orientation_040_128_006_090_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_056_framed gabor_circ blank blank blank blank fixation_cross_target_position_1_3 "1_62_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_056_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 2092 2992 2092 fixation_cross gabor_132 gabor_176 gabor_022 gabor_003 gabor_132_alt gabor_176 gabor_022_alt gabor_003 "1_63_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_2100_3000_2100_gabor_patch_orientation_132_176_022_003_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_048_framed blank blank blank blank fixation_cross_target_position_2_4 "1_63_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_048_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 1792 2992 2192 fixation_cross gabor_108 gabor_002 gabor_019 gabor_088 gabor_108_alt gabor_002 gabor_019_alt gabor_088 "1_64_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_1800_3000_2200_gabor_patch_orientation_108_002_019_088_target_position_2_4_retrieval_position_2" gabor_circ gabor_002_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_64_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_002_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1742 2992 2342 fixation_cross gabor_042 gabor_010 gabor_121 gabor_066 gabor_042 gabor_010_alt gabor_121_alt gabor_066 "1_65_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1750_3000_2350_gabor_patch_orientation_042_010_121_066_target_position_1_4_retrieval_position_1" gabor_092_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_65_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_092_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 61 292 292 399 125 1942 2992 2342 fixation_cross gabor_073 gabor_055 gabor_029 gabor_144 gabor_073_alt gabor_055 gabor_029_alt gabor_144 "1_66_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_300_300_399_1950_3000_2350_gabor_patch_orientation_073_055_029_144_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_008_framed blank blank blank blank fixation_cross_target_position_2_4 "1_66_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_DoChange_CuedRetrieval_retrieval_patch_orientation_008_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2042 2992 2392 fixation_cross gabor_072 gabor_138 gabor_008 gabor_114 gabor_072_alt gabor_138 gabor_008 gabor_114_alt "1_67_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2050_3000_2400_gabor_patch_orientation_072_138_008_114_target_position_2_3_retrieval_position_2" gabor_circ gabor_138_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_67_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_138_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 64 292 292 399 125 2142 2992 2142 fixation_cross gabor_022 gabor_007 gabor_127 gabor_166 gabor_022 gabor_007_alt gabor_127_alt gabor_166 "1_68_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_300_300_399_2150_3000_2150_gabor_patch_orientation_022_007_127_166_target_position_1_4_retrieval_position_2" gabor_circ gabor_007_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_1_4 "1_68_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_retrieval_patch_orientation_007_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 62 292 292 399 125 2042 2992 1992 fixation_cross gabor_087 gabor_143 gabor_021 gabor_111 gabor_087_alt gabor_143 gabor_021 gabor_111_alt "1_69_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_300_300_399_2050_3000_2000_gabor_patch_orientation_087_143_021_111_target_position_2_3_retrieval_position_2" gabor_circ gabor_143_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_target_position_2_3 "1_69_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_CuedRetrieval_retrieval_patch_orientation_143_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 43 64 292 292 399 125 2092 2992 2042 fixation_cross gabor_122 gabor_066 gabor_032 gabor_008 gabor_122_alt gabor_066 gabor_032_alt gabor_008 "1_70_Encoding_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_300_300_399_2100_3000_2050_gabor_patch_orientation_122_066_032_008_target_position_2_4_retrieval_position_3" gabor_circ gabor_circ gabor_032_framed gabor_circ blank blank blank blank fixation_cross_target_position_2_4 "1_70_Retrieval_Working_Memory_MEG_P2_RL_Nonsalient_NoChange_UncuedRetriev_retrieval_patch_orientation_032_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; }; # baselinePost (at the end of the session) trial { picture { box frame1; x=0; y=0; box frame2; x=0; y=0; box background; x=0; y=0; bitmap fixation_cross_black; x=0; y=0; }; time = 0; duration = 5000; code = "BaselinePost"; port_code = 92; };
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err_getValue2.tst
; get-value without check-sat (set-option :produce-models true) (set-logic QF_UF) (declare-fun x () Bool) (get-value (x))
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Ex12_3.sce
sigma_cbc=5//in MPa sigma_st=230//in MPa phi=30//angle of repose, in degrees H=5//height of wall, in m B=0.6*H//assume, in m T=B/4//assume toe to base ratio as 1:4 t=450//thickness of wall, in mm W=16//density of retained earth, in kN/cu m P=W*H^2/2*(1-sind(phi))/(1+sind(phi))//in kN P=67//assume, in kN y=1.8//in m P=67//in kN Wt=223//in kN D=0.5//thickness of base, in m x=1.8-P*(H/3+D/10^3)/Wt//in m x=1.15//in m e=B/2-x//in m q1=Wt/B+Wt*e/(1*B^2/6)//maximum pressure, in kN/sq m q2=Wt/B-Wt*e/(1*B^2/6)//minimum pressure, in kN/sq m Pa=q1-(q1-q2)/B*T//pressure at A, in kN/sq m Pa=100//assume, in kN/sq m Pb=q1-(q1-q2)/B*(T+t/10^3)//pressure at B, in kN/sq m Pb=85//assume, in kN/sq m Ma=Pa*T^2/2+1/2*(q1-Pa)*T*2/3*T-T*D*25*T/2//bending moment at A, in kN-m Ma=30//round-off, in kN-m Mb=(B-T-t/10^3)^2*H*W/2+(B-T-t/10^3)^2*D*25/2-q2*(B-T-t/10^3)^2/2-(Pb-q2)*1/3*(B-T-t/10^3)^2/2//bending moment at B, in kN-m Mb=80//in kN-m //design of toe d=sqrt(Ma*10^6/0.65/10^3)//in mm D=d+10/2+70//<500 mm (provided), hence OK D=500//in mm d=D-70//in mm Ast=Ma*10^6/sigma_st/0.9/d//in sq mm Astmin=0.12/100*10^3*D//in sq mm Ast=max(Ast,Astmin)//in sq mm s1=1000*0.785*10^2/Ast//in mm s1=130//assume, in mm //distribution steel is same as above //check for shear V=(q1+Pa)/2*T//in kN Tv=V*10^3/10^3/d//in MPa //for M15 grade concrete and pt=0.32 Tc=0.2368//in MPa //as Tc > Tv, no shear reinforcement required //development length dia=10//in mm Tbd=0.84//in MPa Ld=dia*sigma_st/4/Tbd//in mm Ld=685//assume, in mm //design of heel d=sqrt(Mb*10^6/0.65/10^3)//< 430 mm (provided), hence OK d=430//in mm Ast=Mb*10^6/sigma_st/0.9/d//in sq mm s2=1000*0.785*10^2/Ast//in mm s2=85//assume, in mm //distribution steel: 0.12% of Ag, hence provide 10 mm dia bars @ 130 mm c/c V=(B-T-t/10^3)*H*W-(Pb+q2)/2*(B-T-t/10^3)//in kN Tv=V*10^3/10^3/d//in MPa //for M15 grade concrete and pt=0.32 Tc=0.2368//in MPa //as Tc > Tv, no shear reinforcement required //development length dia=10//in mm Tbd=0.84//in MPa Ld=dia*sigma_st/4/Tbd//in mm Ld=685//assume, in mm mprintf("Summary of design:\nThickness of base slab=%d mm. Refer to Fig. 12.11 of textbook for reinforcement details.",D) //answer in textbook for spacing of 10 mm dia bars for main steel in toe and distribution steel is incorrect
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EX_6_30.sce
// Example 6.30;//bandwidth clc; clear; close; BW=10;//bandwidth without feedback in killo hertz A= 100;// open loop voltage gain Beta=0.1;// feedback ratio Afb= (A/(1+(Beta*A)));//GAIN WITH FEEDBACk Bwf=round(BW*(1+Beta*A));//bandwidth with feedback in killo hertz disp(Afb,"feedback gain") disp(Bwf,"bandwidth with feedback in killo hertz")
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Example_10_13.sce
clc; clear; printf("\n Example 10.13\n"); D_e=1e-5;//Effective diffusivity for the reactants in the catalyst particle k=14.4;//first order rate constant L=2.5e-3; lambda=(k/D_e)^0.5; phi=(k/D_e)^0.5*(L);//Thiele modulus //From equation 10.202, the effectiveness factor, eta=(1/phi)*tanh(phi); printf("\n (i) The effectiveness factor = %.3f",eta); //The concentration profile is given by equation 10.198 y=1.25e-3; C_Ai=0.15; C_A=C_Ai*(cosh(lambda*y)/cosh(lambda*L)); printf("\n (ii) The concentration of reactant at a position half-way between the centre and the outside of the\n\t pellet = %.3f kmol/m^3",C_A);
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function f1=%rms(f1,n2) // %rms(f1,n2) //f1 = f1*n2 //! [n1,d1]=f1(2:3), [l1,m1]=size(n1);[l2,m2]=size(n2), if l1*m1==0|l2*m2==0 then,f1=[];return;end indef=%f if l1==-1 then n1=n1+0;d1=d1+0;l1=1;m1=1; if l2*m2==1 then indef=%t,end end if l2==-1 then n2=n2+0;l2=1;m2=1; if l1*m1==1 then indef=%t,end end // if mini([l1*m1,l2*m2])=1 then, num=n1*n2, den=d1*ones(l2,m2), else, if m1<>l2 then error(10),end, for i=1:l1, n=n1(i,:); [y,fact]=lcm(d1(i,:)), den(i,1:m2)=ones(1,m2)*y, for j=1:m2, num(i,j)=n*(n2(:,j).*matrix(fact,l2,1)), end, end, end, [num,den]=simp(num,den), if indef then num=num*eye den=den*eye end f1(2)=num;f1(3)=den;
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@relation yeast-4 @attribute Mcg real [0.11, 1.0] @attribute Gvh real [0.13, 1.0] @attribute Alm real [0.21, 1.0] @attribute Mit real [0.0, 1.0] @attribute Erl real [0.5, 1.0] @attribute Pox real [0.0, 0.83] @attribute Vac real [0.0, 0.73] @attribute Nuc real [0.0, 1.0] @attribute Class {MIT, NUC, CYT, ME1, ME2, ME3, EXC, VAC, POX, ERL} @inputs Mcg, Gvh, Alm, Mit, Erl, Pox, Vac, Nuc @outputs Class MIT MIT CYT MIT MIT ME3 MIT MIT MIT MIT NUC NUC MIT CYT EXC ME1 MIT ME1 ME3 ME3 CYT CYT CYT NUC NUC NUC ME3 ME3 ME3 ME3 CYT MIT CYT CYT MIT NUC MIT MIT MIT MIT ERL ME1 CYT CYT MIT MIT NUC CYT NUC NUC NUC CYT ME2 ME3 ME3 ME3 ME2 CYT ME3 ME3 POX CYT NUC NUC CYT CYT ME3 ME3 NUC NUC ME3 ME3 NUC NUC CYT CYT NUC NUC NUC NUC MIT MIT NUC NUC NUC MIT MIT CYT NUC CYT MIT NUC NUC NUC MIT CYT ME3 ME3 NUC MIT ME3 ME3 NUC NUC CYT CYT MIT MIT ME2 NUC MIT CYT MIT CYT EXC CYT NUC CYT NUC CYT MIT ME3 CYT NUC CYT CYT NUC CYT MIT MIT ME1 ME1 NUC CYT NUC CYT NUC CYT NUC CYT POX MIT NUC MIT NUC NUC NUC CYT CYT CYT CYT MIT CYT CYT MIT NUC NUC NUC NUC NUC NUC NUC CYT CYT CYT MIT CYT MIT CYT CYT MIT MIT CYT NUC CYT MIT CYT CYT CYT NUC CYT CYT CYT NUC CYT CYT ME3 ME3 ME3 ME3 NUC CYT NUC CYT NUC MIT CYT CYT CYT CYT NUC ME3 CYT CYT ME1 ME1 NUC NUC NUC CYT NUC NUC CYT MIT CYT NUC CYT NUC CYT CYT ME1 ME1 ME1 ME1 CYT CYT CYT CYT CYT CYT NUC CYT CYT CYT CYT CYT VAC CYT VAC NUC CYT CYT VAC CYT ME3 ME3 ME3 ME3 ME3 ME3 EXC ME1 ME3 MIT ME2 MIT MIT CYT MIT MIT CYT CYT NUC ME3 CYT CYT ME3 ME3 CYT NUC NUC NUC NUC CYT NUC CYT ME2 NUC CYT NUC MIT MIT CYT CYT MIT MIT NUC CYT CYT NUC CYT NUC CYT NUC ME3 ME3 NUC CYT
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//clc(); clear; stacksize('max'); path = "/media/data/evo/manipulator_dynamics/data_for_identification_Youbot/"; N = 51; p = 5; //path = "/media/data/evo/manipulator_dynamics/data_for_identification_2dof/"; //N = 13; //p = 2; Chi = zeros(N,1); for l = 1:1 data_type = 'raw'; xi = path + "bigs/'+data_type+'/big_xi" + string(l) + ".txt"; tau = path + "bigs/'+data_type+'/big_tau" + string(l) + ".txt"; tau = read(tau, -1, 1); xi = read(xi, -1, N); i = 30; xi = [xi(:,1:i), xi(:,(i+2):N)]; N = N-1; Chi = zeros(N,1); sz = size(xi); for i = 1:p taus(:,i) = tau(i:p:sz(1),:); end m = sz(1) / p; for i = 1:p norma(i) = norm(taus(:, i)) end winH=waitbar('Нормировка данных...'); for i = 1:sz(1) waitbar(i/sz(1),winH); tau(i) = tau(i) / norma(pmodulo(i-1, p)+1); xi(i, :) = xi(i, :) / norma(pmodulo(i-1, p)+1); end close(winH); Chi(:,l) = inv(xi' * xi) * xi' * tau; // scf() // ChiReal = [4.5, 0, -2.5833333333333335, 0, 0, 0, 1.0, 0, -0.5333333333333334, 0.0, 0, 0, 0]' tau_calc = xi * Chi; // tau_calc_real = xi * ChiReal; for i = 1:p // subplot(2, p, i+p); subplot(2, 3, i); plot2d(1:m, tau(i:p:sz(1)), 3); plot2d(1:m, tau_calc(i:p:sz(1)), 1); // plot2d(1:m, tau_calc_real(i:p:sz(1)), 5); // legend("raw data", "ident data", 'calc data') a = gca() a.title.text = 'Calculations for normalized data. Link ' + string(i); end end disp("Normalized calcs") disp('cond(xi) = ' + string(cond(xi))) disp('rank([xi]) = ' + string(rank([xi]))) disp('rank([xi, tau_calc]) = ' + string(rank([xi, tau_calc])))
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//Programming Example 9.13 //Reorder a 1 dimentional, integer array from smallest to largest function[] = main() //read in a value for n printf("\n How many numbers will be entered? "); n = scanf("%d"); printf("\n"); //read in the list of numbers for i =1:n printf("i = %d x = ", i+1); x(i) = scanf("%d"); end //reorder all array elements x=reorder(n,x); //display the reordered list of numbers printf("\n\nReordered List of numbers:\n\n"); for i=1:n printf("i = %d x=%d\n", i, x(i)); end endfunction function[x] = reorder(n, x) //rearrange the list of numbers for item=1:n-1 //find the smallest of all remaining elements for i= item+1:n if(x(i) < x(item)) //interchange two element temp=x(item); x(item)=x(i); x(i)= temp; end end end return x; endfunction //calling main() funcprot(0); main();
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//El apóstrofe indica un arreglo en columna o simplemente usar el ; en cada fina de fila F1 = [1 2 3] F2 = [4 5 6] F3 = [7 8 9] MF = [F1; F2; F3] C1 = [1 2 3]' C2 = [4 5 6]' C3 = [7 8 9]' MC = [C1 C2 C3] disp(MF) disp(MC) A = [9 8 7; 6 5 4; 3 2 1] i = 2 j = 1 disp(A) //Elemento i j disp(A(i, j)) //Fila i disp(A(i,:)) //Columna j disp(A(:,j)) //Scilab tiene la función inv(A) //Hacer código para sacar inversa de una matriz //D:\Documentos\Workspaces\DevC++ workspace\Matrices\matrices.cpp:214
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// Scilab Code Ex5.2 Term values for L-S coupling: Pg:145 (2008) // For 2D(3/2) state // Set-I values of L and S L = 1; // Orbital quantum number S = 1/2; // Spin quantum number printf("\nThe term values for L = %d and S = %2.1f (P-state) are:\n",L, S); J1 = 3/2; // Total quantum number printf("%dP(%2.1f)\t", 2*S+1,J1); J2 = 1/2; // Total quantum number printf("%dP(%2.1f)", 2*S+1,J2); // Set-II values of L and S L = 2; // Orbital quantum number S = 1/2; // Spin quantum number printf("\nThe term values for L = %d and S = %2.1f (P-state) are:\n",L, S); J1 = 5/2; // Total quantum number printf("%dD(%2.1f)\t", 2*S+1,J1); J2 = 3/2; // Total quantum number printf("%dD(%2.1f)", 2*S+1,J2); // Result // The term values for L = 1 and S = 0.5 (P-state) are: // 2P(1.5) 2P(0.5) // The term values for L = 2 and S = 0.5 (P-state) are: // 2D(2.5) 2D(1.5)
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//Chapter 02:Basic Structures: Sets, Functions, Sequences, Sums and Matrices clc; clear; s=0 res=[] mprintf("Sum of values of s for all the members of the set { ") for s=0:2:4 mprintf("%d ",s) res=res+s end mprintf("} is %d",res)
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clc; //Example 33.5 page no 527 printf("Example 33.5 page no 527\n\n"); //an artery branches into two smaller equal area arteries so that velocity is same //because q1=q2,volumetric flow rate //q1=q2=q/2 //because s1=s2,cross sectional area //s1=s2=s/2 //let the values q=1//flow rate at inlet artery q1=q/2//flow rate at outlet artery s=1//area of inlet artery s1=s/2//area of outlet artery //v=q/s D_r=sqrt(q/q1)//ratio of diameters printf("\n ratio of diameters D_r=%f ",D_r);
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//Problem 17.08: A coil of inductance 0.04 H and resistance 10 ohm is connected to a 120 V, d.c. supply. Determine (a) the final value of current, (b) the time constant of the circuit, (c) the value of current after a time equal to the time constant from the instant the supply voltage is connected, (d) the expected time for the current to rise to within 1% of its final value. //initializing the variables: L = 0.04; // in Henry R = 10; // in ohms V = 120; // in Volts //calculation: tou = L/R t1 = tou I = V/R i1 = I*(1 - %e^(-1*t1/tou)) i2 = 0.01*I t2 = -1*tou*log(i2/I) printf("\ = \n\n Result \n\n") printf("\n (a) the final value of current is %.0f A",I) printf("\n (b)time constant of the circuit is %.3f sec",tou) printf("\n (c) value of current after a time equal to the time constant is %.2f A",i1) printf("\n (d)the expected time for the current to rise to within 0.01 times of its final value is %.2f sec",t2)
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errcatch(-1,"stop");mode(2);//Chapter 1, Example 1.6 n=2 //no of recievers Zo=75 //input impedance of each receiver //calculating the value of resistor R=((n-1)/(n+1))*Zo printf("Value of the matching resistor = %d ohm",R) exit();
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clear; clc; //Example 6.13 Vtn=0.8; Vtp=-0.8; Kn=80*10^-3; Kp=40*10^-3; //x=W/L xn=15; xp=10; //lambda=y yn=0.01; yp=0.01; Ibias=0.2; gm=2*sqrt(Kn*xn*Ibias/2); printf('\ntransconductance of the NMOS driver=%.3f mA/V^2\n',gm) ron=1/(yn*Ibias); printf('\noutput resistances=%.2f Kohm\n',ron) Av=-gm*ron/2; printf('\nsmall signal voltage gain=%.2f \n',Av)
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TITLE easyarmies MAP_NAME easyarmies SHRUB_LIST_NAME easyarmies_shrubs.txt BUILDING_LIST_NAME easyarmies_buildings.txt UNIT_LIST_NAME easyarmies_units.txt TIME_LIMIT_MINS 0 NUMBER_OF_FORCES 2 FORCE_NAME 0 352nd Infantry Div. FORCE_SHIELD 0 mkiv/EyeOfRa CAM_POS_FORCE 0 {0.00,100.00,0.00} CAM_AIM_FORCE 0 {0.00,0.00,0.00} FORCE_NAME 1 29th Infantry Div. FORCE_SHIELD 1 mkiv/EyeOfRa CAM_POS_FORCE 1 {0.00,100.00,0.00} CAM_AIM_FORCE 1 {0.00,0.00,0.00} WATER_TYPE NONE WATER_LEVEL -10.00
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clc //to calculate uncertainity in frequency //delE*delt=h/2*%pi----eq(1) //delE=h*delv-----------eq(2) delt=10^-8 //uncertainity in time in s //from eq(1) and eq(2),we get delnu=1/(2*%pi*delt) disp("minimum uncertainity in the frequency of the photon is delv="+string(delnu)+"sec^-1")
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//Example 9.5 //Vector Computation //Page no. 299 clc;clear;close; X=[2,3,0,1]; n=X(1); for i=2:4 if(n<X(i)) n=X(i); end end printf('\nMaximum Value (n)=%i\n',n) for i=1:4 X(i)=X(i)/n; end disp(X,'Normalized X=') k=0; for i=1:4 k=k+X(i)^2; end sigma=X(1)*abs(1/X(1))*sqrt(k); printf('\nsigma=%f\n',sigma); X(1)=X(1)+sigma; printf('\nModified x1 = %g\n',X(1)) for i=1:4 U(1,i)=X(i); end disp(U,'U=') p=sigma*X(1);sigma=n*sigma; printf('\n p = %f\n\n sigma = %f',p,sigma); printf('\n\n\nNote : There is a computation error in calculation of U1')
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clc //initialisation of variables g1=1.41 g=32.2//ft/sec^2 T=273//c R=96 p=14.7//lb/in^2 //CALCULATIONS w=p*144/(R*T) po=w/g v=sqrt(g1*p*144*g/w) //RESULTS printf (' velocity of sound in air= %.f ft/sec',v)
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//Functioning of XOR logic printf("\tInput 1\tInput 2\tOutput\n\n") for i=0:1 for j=0:1 printf("\t %d\t %d\t %d\n",i,j,bitxor(i,j)) end end
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function [x]=d2(orbit,NbrIti,Dim,Delai, NbrEps, TheWin, MaxLenSca, MinLenSca) // Initialisation Commandline=''; NbrComp=size(orbit,2); if ~isdef('DoEstim','local')... then DoEstim=%F, end; if isdef('NbrIti','local')... then Commandline=Commandline+' -l'+string(NbrIti), end; if isdef('Dim','local')... then Commandline=Commandline+' -M'+string(NbrComp)+','+string(Dim), end; if isdef('NbrPair','local')... then Commandline=Commandline+' -N'+string(NbrPair), end; if isdef('NbrEps','local')... then Commandline=Commandline+' -#'+string(NbrEps), end; if isdef('MaxLenSca','local')... then Commandline=Commandline+' -R'+string(MaxLenSca), end; if isdef('MinLenSca','local')... then Commandline=Commandline+' -r'+string(MinLenSca), end; if isdef('TheWin','local')... then Commandline=Commandline+' -t'+string(TheWin), end; if isdef('Delai','local')... then Commandline=Commandline+' -d'+string(Delai), end; // Utilisation de Lyap_K from TiSeAn if isdef('orbit','local')... then mdelete('tmpin') ; mdelete('tmp.c2') ; mdelete('tmp.d2') ; mdelete('tmp.h2') ; mdelete('tmp.stat') ; write('tmpin',string(orbit)), Commandline=' tmpin'+Commandline+' -c'+string(NbrComp)+' -otmp', end; Commandline='d2'+Commandline, // Reading the output x=host(Commandline); if x~=0... then disp('Erreur!!! Fichier ou Tisean manquant'); return; end; x=read('tmp.d2',-1,1,'(a)'); y=[]; for i=1:size(x,1) do if length(x(i))>3... then y=[x(i);y]; end; end; x=y; carct=[]; for i=1:size(x,1) do carct=[carct '#']; end; ix=grep(x',carct); indexelem=ix; x=strsubst(x,'#center= ','0 '); x=strsubst(x,'#dim= ','0 '); x=evstr(x); y=[]; col=2; for i=1:size(x,1); if x(i,1)~=0 then y=[x(i,1) x(i,2); y], end; end; x=y; endfunction
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function r=%i_j_i(a,n) if or(n<0) then r=double(a).^double(n) else if size(a,'*')==1 then r=iconvert(double(a).^double(n),inttype(a)) else if size(n,'*')<>1 then error(43) else n=double(n) r=a for i=2:n,r=r.*a,end end end end
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CA0 = 10; CB0 = 2; X = 0.2; X1=0.9
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clear all; clc; disp("Scilab Code Ex 13.2 : ") //Given: E = 200; //GPa I = 15.3*10^6; //mm^4 l= 4*1000; //mm A = 5890; //mm^2 sigma_y = 250; //MPa //Calculations: Pcr = ((%pi^2)*E*10^6*I*1000^-2)/(l^2); //Pcr = (%pi^2*EI)/(l^2) sigma_cr = (Pcr*1000)/A; if(sigma_cr>sigma_y) Pcr = (sigma_y*A); Pcr = Pcr/1000; //in kN end //Display: printf("\n\nThe maximum allowable axial load that the column can support = %1.1f kN',Pcr); //----------------------------------------------------------------------END--------------------------------------------------------------------------------
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clear // // // //Variable declaration n=5000 //number of lines/cm lamda=6000*10**-8 //wavelength(cm) //Calculation e=1/n k=e/lamda //highest order of spectrum //Result printf("\n highest order of spectrum is %0.3f ",k)
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fo=200*10^6; Vce=3; Ic=3*10^-3; Cbc=0.1*10^-15; rBE=2*10^3; rCE=10*10^3; Cbe=100*10^-15; L3=50*10^-9; L=50*10^-9; gm=0.11666; disp("DC values of Hparameters are"); h11=rBE; h12=0; h21=rBE*gm; h22=1/rCE; disp("Mho",h22,"h22",h21,"h21",h12,"h12","Ohms",h11,"h11"); k=h21/(h11*h22-h21*h12); A=(1+k)/L; B=A^2; C=16*k*(%pi)^2*fo^2*(h22/h11); D=8*k*(%pi)^2*fo^2; C2=(A+sqrt(B+C))/D; C1=k*C2; disp("H parameters at resonance frequency"); w=2*%pi*fo; E=1+%i*w*(Cbe+Cbc)*rBE; hie=rBE/E; hre=(%i*w*Cbc*rBE)/E; hfe=(rBE*(gm-%i*w*Cbc))/E; hoe=h22+(%i*w*Cbc*(1+gm*rBE+%i*w*Cbe*rBE))/E; disp("Mho",hoe,"hoe",hfe,"hfe",hre,"hre","Ohms",hie,"hie");
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clear// //Variables VCC = 8.0 //Source voltage (in volts) VRC = 0.5 //Voltage across collector resistance (in volts) RC = 800.0 //Collector resistance (in ohm) alpha = 0.96 //common base current gain //Calculation VCE = VCC - VRC //Collector-to-emitter voltage (in volts) IC = VRC / RC //Collector current (in milli-Ampere) IE = IC / alpha //Emitter current (in milli-Ampere) IB = IE - IC //Base current (in milli-Ampere) //Result printf("\n Collector-to-Emitter VCE is %0.3f V.\nBase current is %0.3f mA.",VCE,IB*10**3)
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clc; syms t A=[0 -2 1;0 0 3;0 0 0]; z=A*A*A; if z==0 then disp("A is a nilpotent of index 3"); else disp("A is not nilpotent") end //we know %e^(at)=b0*I+b1*A+b2*A^2; e=spec(A);//eigen values b2=t^2*%e^(e(3)*t); b1=t*%e^(e(2)*t)-b2*2*e(2); b0=%e^(e(1)*t)-b1*e(1)-b2*e(1)^2; eAt=b0*eye(A)+b1*A+b2*A^2; disp(eAt,"e^(At)")
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clear; clc; close; Beta = -0.1; dA_A = 20; A = -1000; dAf_Af = abs(1/(Beta*A))*abs((dA_A)); disp(dAf_Af,'Percentage Change in gain of feedback amplifier = ');
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clc disp("Example 3.68") printf("\n") disp("Calculate required base resistance for Collector to base bias circuit") printf("Given\n") //given Vcc=30 Vce=7 Vbe=0.7 Rc=8.2*10^3 hFE=100 //base current Ib=(Vcc-Vce)/(Rc*(1+hFE)) //base resistance Rb=(Vce-Vbe)/Ib printf("base resistance is \n%f ohm\n",Rb)
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clear; clc; printf("Example 2.3") //Given r1=44 // [mm] r1=r1/1000 //[m] r2=0.094 // [m] r3=0.124 // [m] T1=623 //Temperature at outer surface of wall in[K] T3=313 //Temperature at outer surface of outer insulation [K] k1=0.087 //Thermal conductivity of insulation layer 1..in [W/m.K] k2=0.064 //Thermal conductivity of insulation layer 2 [W/m.K] l=1 // Length of pipe [m] rm1=(r2-r1)/log(r2/r1) //log mean radius of insulation layer 1 [m] rm2=(r3-r2)/log(r3/r2) //log mean radius of insulation layer 2[m] //Putting values in following eqn: Q= (T1-T3)/((r2-r1)/(k1*2*%pi*rm1*l)+(r3-r2)/(k2*2*%pi*rm2*l)); printf("Heat loss per meter pipe is %f W/m",Q)
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function f=%r_t(f1) // f=f1' //! // Copyright INRIA f=rlist(f1('num')',f1('den')',f1('dt'))
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clear; clc; // Stoichiometry // Chapter 7 // Combustion // Example 7.4 // Page 444 printf("Example 7.4, Page 444 \n \n"); // solution // basis 1 mol of natural gas // using table 7.7 H2O = [2*.894+3*.05+.019+5*(.004+.006)]*18 // g Hv = H2O*2442.5/1000 NCV1 = 945.16-Hv GCV = 945.16*1000/18.132 NCV = NCV1*1000/18.132 printf(" GCV = "+string(GCV)+" kJ/kg. \n NCV = "+string(NCV)+" kJ/kg.")
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// Chapter9 // Maximum and minimum Frequency of oscillation // Page.No-307 // Example9_2 //Figure 9.9 // Given clear;clc; // for minimium frequency R=11100; //in Ohm C=0.1*10^-6; //in F f=1/(2*%pi*R*C); printf("\n The mimimum frequency of oscillation = %.1f Hz\n",f); // Result // for maximum frequency R=1100; //in Ohm C=0.1*10^-6; //in F fm=1/(2*%pi*R*C); printf("\n The maximum frequency of oscillation = %.0f Hz\n",fm); // Result printf("\n For C=0.001microF, the range is from %.1f Hz to %.0f Hz\n ", f*10,fm*10);//Result printf("\n For C=0.0001microF, the range is from %.1f Hz to %.0f Hz\n ", f*100,fm*100);//Result Rf=10000+2700; //in ohm Ri=5600; //in Ohm Av=1+Rf/Ri; printf("\n Gain ,Av is %.2f \n ", Av);//Result
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clc; tp=10*10**-6; c=1000*10**-12; R1=tp/(1.1*c); disp('Kohm',R1*10**-3,"R1="); t=(0:0.1:5*%pi)'; plot2d1('onn',t,[squarewave(t,60)]);
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// Chapter 11 example 3 //------------------------------------------------------------------------------ clc; clear; // Given data a1 = 18000; // semi major axis of the elliptical orbits of satellite 1 a2 = 24000; // semi major axis of the elliptical orbits of satellite 2 // Calculations // T = 2*%pi*sqrt(a^3/u); //let K = T2/T1; K = (a2/a1)^(3/2); // Ratio of orbital periods // Output mprintf('The orbital period of satellite-2 is %3.2f times the orbital period of satellite-1',K); //------------------------------------------------------------------------------
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//data in question //power transmission(W) Pt=25000 //operating frequency(Hz) f=12*10^9 //gain of transmitter antenna(25dB) Gt=10^(25/10) //gain of receiver antenna(25dB) Gr=10^(25/10) //distance between two radars(m) R=10000 //surface area of target radar(m^2) A=8 c=3*10^8 //data print printf("\nPt=25 kW\tf=12 GHz\tGt=Gr=25 dB\tR=10 km\tA=8 m^2\n") //equation and result printf("\nresult:-") //wavelength L L=c/f printf("\nwavelength of signal L=c/f=%.3f m",L) Pr=Gr*Gt*Pt*A*L^2/(4*%pi*(4*%pi*R^2)^2) printf("\nreceived power \nPr=Gr*Gt*Pt*A*L^2/(4*pi*(4*pi*R^2)^2)= %.2eW",Pr) printf(" = %.2f pW",Pr*10^12)
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x=[0.5 1.0 1.5 2.0 2.5 3.0] y=[0 1 2 3 4 5] z=[0 2 4 6 8 10] plot(x,y,'r*-') xtitle('subplot 1') plot(y,z,'p+-') xlabel('x-axis') ylabel('y-axis') xgrid()
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//========================================================================= //chapter 7 example 10 clc; clear; //input data IDSS = 10; //current in mA IDS =2.; // current in mA Vp = -4.0; //pinch off voltage in V //formula //IDS = IDSS*((1-(VGS/Vp))^2) //calculation VGS = Vp*(1-(sqrt(IDS/IDSS))); gm = ((-2*IDSS)/Vp)*(1-(VGS/Vp)); //result mprintf('transconductance =%3.2f.m*A/V\n',gm); //==========================================================================
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clc //initialisation of variables W1= 7000 //lb W2= 1000 //lb W3= 3000 //lb x1= 6 //in x2= 9 //in x3= 10 //in x4= 5 //in //CALCULATIONS Rb= (W1*x1+W2*(x1+x2)+W3*(x1+x2+x3))/(x1+x2+x3+x4) Ra= W1+W2+W3-Rb //RESULTS printf ('Rb= %.1f lb',Rb) printf (' \n Ra=%.1f lb',Ra)
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// ::::::::::::::::::::::::::::::::::::::::: // :: :: // :: Question 14. Gauss-Newton :: // :: :: // ::::::::::::::::::::::::::::::::::::::::: funcprot(0); exec("Q11_Flux.sce"); flux_cible = [-0.1, -0.18]; // Calcule le minimum de la fonction J, c'est un point de la barre. function [xk] = minJ(x0) xk = x0 k = 0 arret_xk = 1; while abs(arret_xk) > 10^-5 flux_xk = (flux_vecteur(xk)'); flux_deriv = numderivative(flux_vecteur, xk)'; delta_k = (-flux_deriv) * ((flux_xk - flux_cible)') / (flux_deriv * flux_deriv'); xk = xk + delta_k; // Condition d'arrêt, epsilon est fixé à 10^-5 arret_xk = (2 * flux_deriv * (flux_xk - flux_cible)') / (flux_cible(1)^2 + flux_cible(2)^2); k = k + 1; disp("- x_k vaut " + string(xk)); end endfunction // EXEMPLES D'APPEL A ESSAYER // minJ(0); // minJ(-5); // minJ(3);
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//Chapter 9, Problem 6 clc; B=1.4; //flux density l=12*10^-2; //length N=80; //no of turns n=1200/60; //rotation in sec E1=90; //emf r=(8*10^-2)/2; Q90=%pi/2; //calculating velocity v=2*%pi*n*r; //calculating maximum emf E=2*N*B*v*l*sin(Q90); //calculating velocity with emf 90V v=E1/(2*N*B*l*sin(Q90)); //calculating speed of coil w=v/r; w1=(w*60)/(2*%pi); disp("(a)"); printf("Maximum emf induced = %f V",E); disp("(b)"); printf("Speed of coil in rev/min = %d rev/min",w1);
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/* Questionaire created by optica toolkit Date: Fri Nov 5 15:51:40 1999 */ question(1, '1', 'Wde ejfejpofew', [ '1', '1.5' ], state(state, '', [ m1 = lens(label(''), radius(5), thickness(0.1), focal_distance(5), sfere_left(*), sfere_right(*), breaking_index(1.51), pos_x(9.8), show_gauge(true), instrument_name(lens)), l1 = lamp1(switch(true), angle(0), pos_y(3.7), pos_x(3.55), instrument_name(lamp1)) ])).
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//Optoelectronics - An Introduction, 2nd Edition by J. Wilson and J.F.B. Hawkes //Example 5.3 //OS=Windows XP sp3 //Scilab version 5.5.2 clc; clear; //given h=6.6e-34;//Planck's constant in SI Units T21=230e-6;//Spontaneous lifetime in s lambda=1.06e-6;//Wavelength in m n=1.82;//Refractive index of medium DeltaNu=3e12;//Linewidth in Hz k=1;//Given value of gain coefficient in m^(-1) B21=(lambda^3)/(8*%pi*h*T21); mprintf("\n B21 = %.1e m^3 W^-1 s^-3",B21); //Let the inversion density (N2-g2/g1*N1) be Di Di=k*lambda*DeltaNu/(B21*h*n); mprintf("\n N2-g2/g1*N1 = %.1e m^(-3)",Di);//The answer provided in the textbook is wrong
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clc clear //input data f=120 //lowest frequency //calculation x=3*f // the next higher frequency is thrice the lowest frequency //output printf("the next higher frequency where the antinode is formed is at %3.3f Hz",x)
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//Calculate Hole concentration //Ex:15.9 clc; clear; close; nd=10^17;//in per cu cm ni=1.5*10^10;//in cu cm ne=nd;//nd>>ni nh=ni^2/ne; disp(nh,"Hole concentration (in per cubic cm) = "); t=300;//in K e=0.0259*log(ne/ni);//in eV disp(e,"Location of Fermi Level (in eV) = ");
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// Example 3.7.6:average output voltage,supply rms current ,supply fundamental current current,displacement factor,supply factor and supply harmonic factor clc; clear; close; format('v',6) Vsrms=220;//in volts alpha=%pi/3;// vm=sqrt(2)*Vsrms;// vldc=((2*vm)/(%pi))*(cos(alpha));//in volts vldcm=(2*vm)/(%pi);//in volts vn=vldc/vldcm;//normalised average output voltage in volts x=((1/%pi)*((%pi-alpha)+(sin((2*alpha)))/2))^(1/2);// vlrms=((vm/sqrt(2))*x);//RMS load voltage in volts Io=1;//assume Isrms=Io*(1-(alpha/%pi))^(1/2);//in amperes Is1rms=((2*sqrt(2))*Io*cos(alpha/2))/(%pi);//in amperes HF=((Isrms/Is1rms)^2-1)^(1/2);//Harmonic Fator is DF=cos(alpha/2);//Displacement factor PF=(Is1rms/Isrms)*(DF);//power factor disp("part (a)") disp(round(vldc),"average output voltage (Vldc)in volts is") disp("part (b)") disp("due to exact 50% duty cycle the rms value of supply current Isrms=Io") Io=1;//assume Isrms=Io;//in amperes Is1rms=((2*sqrt(2))*Io)/(%pi);//in amperes disp("part (c)") disp("supply fundamental current is "+string(Is1rms)+" Io ") disp("part (d)") DF=cos(alpha);// disp(DF,"displacement factor is") disp("part (a)") SPF=Is1rms*DF;// disp(SPF,"supply power factor is (lagging)") disp("part (f)") HF=(((Isrms/Is1rms)^2)-1)^(1/2);// disp(HF*100,"supply harmonic factor in percentage is")
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// Question 7 page 8.44 clc; clear; w=25d-6; //width v=3d4; //velocity t=w/v; //computing drift time BW=(2*%pi*t)^-1; //computing bandwidth rt=1/BW; //response time rt=rt*10^9; printf("\nMaximum response time is %.2f ns.",rt); //Answer in the book is given as 5.24ns deviation of 0.01ns
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clear; clc; //1. create and Display Lab Topology NameOfNetwork='Lab Topology';// Name of your network NumberOfNodes=input("Enter number of nodes");//Number of Nodes in the network ConnectionEndingNode=[1 2]; //Ending Nodes of the connection lines ConnectionStartingNode=[1 2];//Starting Nodes of the connection lines x=(NumberOfNodes/2)*100;//inital position of starting node k=300;//a variable used later for incrementing so that we can get the next x position of the node pp=900;//a variable used later for incrementing so that we can get the next y position of the node XCoordinatedOfNodes=[100 200];// X-Coordinates of the nodes YCoordinatedOfNodes=[pp pp];// Y-Coordinates of the nodes for i=1:NumberOfNodes//adding Starting and connection nodes ConnectionEndingNode($+1)=i;//adding connection starting node ConnectionStartingNode($+1)=i;//adding connection ending node end nn=0;//variable to use as a counter for the while loop bb=modulo((NumberOfNodes-2),6);//excess ndes when divided by 6 cc=(NumberOfNodes-bb-2)/6;//quotient when divided by 6 //3. insert new nodes in the specified edge while(nn<cc)//This gives us the number of rows which are exactly divisible by the number of nodes in each row ie 6 for i=1:3//adding 3 nodes in a row on the left XCoordinatedOfNodes($+1)=k;//adding the x position of node YCoordinatedOfNodes($+1)=pp;//adding the y position of node k=k+100;//incrementing variable for new position of next node end l=k+100;//incrementing variable for new position of next node for i=1:3//adding 3 nodes in a row on the right XCoordinatedOfNodes($+1)=l;//adding the x position of node YCoordinatedOfNodes($+1)=pp;//adding the y position of node l=l+100;//incrementing variable for new position of next node end nn=nn+1;//incremneting the varibles for the while loop pp=pp-100;//decrementing the y position for the new row k=300;//restioring the inital x position end //4.inserting new edge if(bb>0 & bb<=3), for i=1:bb//adding nodes to left if the excess nodes are less than 3 and greater than 0 XCoordinatedOfNodes($+1)=k;//adding the x position of node YCoordinatedOfNodes($+1)=pp;//adding the y position of node k=k+100;//incrementing variable for new position of next node end elseif(bb>3 & bb<6), for i=1:3//adding nodes to left if the excess nodes are less than 6 and greater than 3 XCoordinatedOfNodes($+1)=k;//adding the x position of node YCoordinatedOfNodes($+1)=pp;//adding the y position of node k=k+100;//incrementing variable for new position of next node end l=k+100;//incrementing variable for new position of next node for i=1:(bb-3)//adding nodes to right if the excess nodes are less than 6 and greater than 3 XCoordinatedOfNodes($+1)=l;//adding the x position of node YCoordinatedOfNodes($+1)=pp;//adding the y position of node l=l+100;//incrementing variable for new position of next node end end [TopologyGraph]=NL_G_MakeGraph(NameOfNetwork,NumberOfNodes,ConnectionEndingNode,ConnectionEndingNode,XCoordinatedOfNodes,YCoordinatedOfNodes)//Creates the lab topoplogy WindowIndex=1;//window index [VisualizeGraph1] = NL_G_ShowGraph(TopologyGraph,WindowIndex);//display graph [ExtractNode,ExtractEdge]=NL_G_GraphSize(TopologyGraph);//extract nodes and edges disp(ExtractNode,ExtractEdge); //displays the number of nodes and edges //5. insert new nodes in the specified edge EdgeIndex=7;//edge index NewNodeQuantity=2;//quantity of new nodes [go]=NL_G_SplitEdge(TopologyGraph,EdgeIndex,NewNodeQuantity);//application of NL_G_SplitEdge WindowIndex=3;//window index VisualizeGraph1=NL_G_ShowGraphNE(go,WindowIndex)//visualise graph NewEdgeHeadVector=[1 2];//head vector of new edges NewEdgeTailVector=[2 3];//tail vector of new edges start=3;//starting node ends=4;//ending node for i=1:cc//adding nodes for i=start:(start+4)//adding 4 nodes to headVector NewEdgeHeadVector($+1)=i;//adding nodes to headVector end for i=ends:(ends+4)//adding 4 nodes to tailVector NewEdgeTailVector($+1)=i;//adding nodes to tailVector end start=start+6;//incrementind the starting position for spacing ends=ends+6;///incrementind the starting position for spacing end for i=1:1 for i=start:(bb+start-2)//adding 4 nodes to headVector NewEdgeHeadVector($+1)=i;//adding nodes to headVector end for i=ends:(ends+bb -2)//adding 4 nodes to tailVector NewEdgeTailVector($+1)=i;//adding nodes to tailVector end start=start+6;//incrementind the starting position for spacing ends=ends+6;////incrementind the starting position for spacing end busStart=3;//variable for storing the initial position of the remaning nodes to headVector busEnd=9;//variable for storing the initial position of the remaning nodes to tailVector for i=1:cc NewEdgeHeadVector($+1)=busStart;//adding remaning nodes to headVector NewEdgeTailVector($+1)=busEnd;//adding remaning nodes to tailVector busStart=busStart+6;//incrementind the starting position for spacing busEnd=busEnd+6;//incrementind the starting position for spacing end NewEdgeNameVector=['e5' 'e6' 'e7' 'e8'];//name vector of new edges [TopologyGraph] = NL_G_AddEdges(go,NewEdgeHeadVector,NewEdgeTailVector,NewEdgeNameVector);//Create graph with head & tail nodes WindowIndex=4;//window index VisualizeGraph1=NL_G_ShowGraphNE(TopologyGraph,WindowIndex);//display graph WindowIndex=5;//window index NeworkSquareArea=1000;//Nework Square Area LocalityRadius=1000000;//LocalityRadius [TopologyGraph4]=NL_T_LocalityConnex(NumberOfNodes , NeworkSquareArea ,LocalityRadius);//Display Graph with number of nodes and area
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// This file is released under the 3-clause BSD license. See COPYING-BSD. // Generated by builder.sce : Please, do not edit this file // ---------------------------------------------------------------------------- // libnetwork_path = get_absolute_file_path('loader.sce'); // // ulink previous function with same name [bOK, ilib] = c_link('libnetwork'); if bOK then ulink(ilib); end // list_functions = [ 'network_Init'; 'SWIG_this'; 'SWIG_ptr'; 'TcpOpen'; 'client'; 'close'; ]; addinter(libnetwork_path + filesep() + 'libnetwork' + getdynlibext(), 'libnetwork', list_functions); // remove temp. variables on stack clear libnetwork_path; clear bOK; clear ilib; clear list_functions; // ----------------------------------------------------------------------------
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gridcoords boardsize 4 #playgame d1 a1 g1 e2 g4 f3 a4 d7 c4 f4 f5 e5 e6 d6 c2 e1 c3 c1 e3 f2 d2 b4 c5 b5 c6 b1 a2 a3 d4 g3 b2 d3 b3 f1 d5 e4 g2 playgame d1 a1 g1 e2 g4 f3 a4 d7 c4 f4 f5 e5 e6 d6 c2 e1 c3
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function [res] = clip(data, a) N = length(data); for k = 1 : N new = 0; x = data(k) if abs(x) <= a then new = x; else new = a * sign(x); end res(k) = new; end endfunction function [res] = distort(data, a, b) N = length(data); for k = 1 : N res(k) = a * atan(b * data(k)) end endfunction raw_signal = loadwave('guitar.wav'); first_ch = raw_signal(1,:); // plot original signal // in time and frequecny domains figure(1); subplot(221); plot(first_ch); title("Original signal in time domain"); xlabel("Time t"); ylabel("signal(t)"); subplot(223); plot(fft(first_ch)); title("Original signal in frequency domain"); xlabel("Frequency x"); ylabel("signal(x)") // pass the signal throught clipping filter // and plot the result // in time and frequency domains clipped_signal = clip(first_ch, 0.025)'; //figure(2) // //subplot(221); //plot(clipped_signal); //title("Clipped signal in time domain"); //xlabel("Time t"); //ylabel("clipped(t)"); // //subplot(223); //plot(fft(clipped_signal)); //title("Clipped signal in frequency domain"); //xlabel("Freq x"); //ylabel("clipped(x)"); // pass the signal throught clipping filter // and plot the result // in time and frequency domains distorted_signal = distort(first_ch, 2, 200)'; figure(3) subplot(221); plot(distorted_signal); title("Distorted signal in time domain"); xlabel("Time t"); ylabel("distorted(t)"); subplot(223); plot(fft(distorted_signal)); title("Distorted signal in frequency domain"); xlabel("Freq x"); ylabel("distorted(x)"); savewave("clipped_0025.wav", clipped_signal, 44100); savewave("distorted_2-200.wav", distorted_signal, 44100);
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//Tests the Signed 8 Bit Mutliplication using csa (SMuL8) load SMuL8.hdl, output-file SMuL8.out, output-list a%B1.8.1 b%B1.8.1 out%B1.8.1 OF%B1.1.1; //Non overflow cases.(-128 to 127 range) set a %B00000101,set b %B00011001,eval,output; //5 * 25 = 125 set a %B00000101,set b %B11100111,eval,output; //5 * (-25) = -125 set a %B11111011,set b %B00011001,eval,output; //(-5) * 25 = -125 set a %B11111011,set b %B11100111, eval, output; //(-5) * (-25) = 125 //Overflowing cases set a %B00001010,set b %B00000111,eval,output; //15 * 10 = 150 > 127 set a %B00001111,set b %B11111001,eval,output; //15 * -7 = -135 < -128
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function [y] = log2(x) // Copyright INRIA // function [y] = log2(x) // Log bas 2 of x // // Inputs: // x real matrix // Outputs: // y real matrix y = log_2(x) y = log(x)./log(2) ;
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//Find thickness of insulation //Ex:15.10 clc; clear; close; d=40000;//dielectric strength in V/mm v=33*10^3;//in volts t=v/d;//in mm disp(t,"thickness of insulation (in mm) = ");
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//Example 7.2.a: total armature current clc; clear; close; // given data: Vt=200;// terminal voltage in volts Rsh=100; //shunt fieldresistance in ohm Ra=0.1; // armature resistance in ohm l=60; // number of lamps w=40;// in watt total_l=l*w;// in watt Il=total_l/Vt;// load current Ish=Vt/Rsh;// shunt field current Ia=Il+Ish; disp(Ia,"armature current,Ia(A) = ")
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// chapter 6 // example 6.5 // fig. 6.14 // Determine design details // page-287-288 clear; clc; // given E_supply=230; // in V (voltage supply) Im=12; // in A Edc=150; // in V alpha=30; // in degree V_drop=1.5; // in V (voltage drop across SCR) // calculate // Since Edc=(2*Em/%pi)*cos(alpha)-V_drop, evaluating it for Em we get Em=(%pi*(Edc+V_drop))/(2*cosd(alpha)); // calculation of peak voltage Erms=Em/sqrt(2); // calculation of rms voltage Irms=Im/sqrt(2); // calculation of rms current TSR=2*Erms*Irms; // calculation of Transformer secondory rating K=E_supply/Erms; // calculation of Transformer voltage ratio I_P=Im*(1/K); // calculation of Transformer primary current PIV=2*Em;// calculation of PIV for each SCR printf("\nFor M-2 connection\n") printf("\n\tThe peak voltage is \t\t\tEm=%.1f V",Em); printf("\n\tThe rms volatge is \t\t\tErms=%.2f V",Erms); printf("\n\tThe rms current is \t\t\tIrms=%.2f A",Irms); printf("\n\tThe Transformer secondory rating is \t %.1f kVA",TSR*1E-3); printf("\n\tThe Transformer voltage ratio is \tK=%.2f",K); printf("\n\tThe Transformer primary current is \tI_P=%.2f A",I_P); printf("\n\tThe PIV for each SCR is \t\tPIV=%.f V",PIV); Em=(%pi*(Edc+2*V_drop))/(2*cosd(alpha)); // calculation of peak voltage Erms=Em/sqrt(2); // calculation of rms voltage Irms=Im; // calculation of rms current TSR=Erms*Irms; // calculation of Transformer secondory rating K=E_supply/Erms; // calculation of Transformer voltage ratio I_P=Im*(1/K); // calculation of Transformer primary current PIV=Em;// calculation of PIV for each SCR I_rms_SCR=Im/sqrt(2); // calculation of rms current for each SCR printf("\nFor B-2 connection\n") printf("\n\tThe peak voltage is \t\t\tEm=%.2f V",Em); printf("\n\tThe rms volatge is \t\t\tErms=%.2f V",Erms); printf("\n\tThe rms current is \t\t\tIrms=%.f A",Irms); printf("\n\tThe Transformer secondory rating is \t %.2f kVA",TSR*1E-3); printf("\n\tThe Transformer voltage ratio is \tK=%.2f",K); printf("\n\tThe Transformer primary current is \tI_P=%.2f A",I_P); printf("\n\tThe PIV for each SCR is \t\tPIV=%.2f V",PIV); printf("\n\tThe rms current for each SCR is \t%.1f A",I_rms_SCR); SCR_loss_M2=(V_drop/Edc)*100; // SCR loss in M2 connection SCR_loss_B2=(2*V_drop/Edc)*100; // SCR loss in B2 connection printf("\n\nThe SCR loss in M2 connection is \t%.f percent of the load power",SCR_loss_M2); printf("\nThe SCR loss in B2 connection is \t%.f percent of the load power",SCR_loss_B2);
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//clear// //Caption: Calculation of Stimulated Brillouin Scattering(SBS) threshold power //Example12.2 //page 433 clear; clc; close; delta_VB = 20e06; //Brillouin linewidth in Hz Aeff = 55e-12; //effective cross-sectional area of the propagating wave in square meter Leff = 20e03; //effective length b = 2;//polarization factor gB = 4e-11;//Brillous gain coefficient m/W delta_Vsource = 40e06; //optical source linewidth in Hz Pth = 21*(Aeff*b/(gB*Leff))*(1+(delta_Vsource/delta_VB)); disp(Pth*1e03,'SBS threshold power in milli watts Pth=') //Result //SBS threshold power in milli watts Pth= 8.6625
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errcatch(-1,"stop");mode(2);// Exa 1.2 ; ; // Given data T1 = 25;// in degree C T2 = 100;// in degree C del_T = T2-T1;// in degree C I_S = (2)^7 *5;// in nA I_S = (1.07)^5*I_S;// in nA disp(round(I_S),"The saturation current at 100 degree C in nA is"); exit();
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//Example 2_17 //find convolution of two sequences clc; n=-8:1/1000:8; for i=1:length(n) if n(i)<-5 then x(i)=0; else x(i)=(1/2)^n(i); end if n(i)<3 then h(i)=0; else h(i)=(1/3)^n(i); end end y=convol(x,h); figure plot2d3(n,h); title('Impulse responce'); figure plot2d3(n,x); title('Input signal'); figure n1=-16:1/1000:16 plot2d3(n1,y); title('Output signal');
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//Chapter-1, Example 1.31, Page 44 //============================================================================= clc; clear; //INPUT DATA E=12;//emf of battery in volts R1=3;//resistance1 in parallel combination in ohms R2=4;//resistance2 in parallel combination in ohms R3=6;//resistance3 in parallel combination in ohms R4=4;//resistance4 in series with parallel combination in ohms r=6;//internal resistance in ohm //CALCULATIONS RP=((R2*R3)+(R3*R1)+(R1*R2))/(R1*R2*R3); RP=1/RP;//equivalent resistance of parallel combination in ohms RT=RP+R4+r;//total circuit resistance in ohms I=E/RT;//total circuit current in A V=E-(I*r);//terminal voltage of battery in volts //OUTPUT mprintf("Thus the terminal voltage of battery is %1.3f volts ",V); //=================================END OF PROGRAM==============================
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@relation vowel @attribute TT integer[0,1] @attribute SpeakerNumber integer[0,14] @attribute Sex integer[0,1] @attribute F0 real[-5.211,-0.941] @attribute F1 real[-1.274,5.074] @attribute F2 real[-2.487,1.431] @attribute F3 real[-1.409,2.377] @attribute F4 real[-2.127,1.831] @attribute F5 real[-0.836,2.327] @attribute F6 real[-1.537,1.403] @attribute F7 real[-1.293,2.039] @attribute F8 real[-1.613,1.309] @attribute F9 real[-1.68,1.396] @attribute Class{0,1,2,3,4,5,6,7,8,9,10} @inputs TT,SpeakerNumber,Sex,F0,F1,F2,F3,F4,F5,F6,F7,F8,F9 @outputs Class @data 0 1 5 5 4 4 8 8 10 10 3 3 5 5 2 2 2 2 3 3 1 1 10 5 7 7 10 8 2 2 5 5 8 8 3 3 8 10 6 5 4 4 6 6 0 0 10 5 0 0 1 1 9 9 4 4 3 3 6 6 7 7 6 7 7 7 0 0 6 6 10 10 10 10 6 6 0 0 3 3 4 4 0 0 8 8 7 7 9 9 1 0 0 0 1 1 1 1 4 4 8 8 3 3 3 3 3 3 5 5 8 8 10 10 7 7 6 6 9 9 3 3 2 2 10 10 0 0 8 7 1 1 7 7 5 4 4 4 6 4 8 7 9 8 2 2 4 4 2 2 9 9 1 1 0 0 1 1 4 4 5 5 5 5 9 8 1 2 7 7 5 5 10 10 6 6 9 9 2 2 5 5 2 2 4 4 9 9 2 2 7 7 8 8 7 7 9 9
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clear// //Variables R = 10.0*10**3 //Resistance (in ohm) //Calculation G = 1/R //Conductance (in siemens) //Result printf("\n The conductance of gold conductor is %0.3f siemens.",G)
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Ex6_15.sce
clear; clc; printf("\t\t\tProblem Number 6.15\n\n\n"); // Chapter 6: The Ideal Gas // Problem 6.15 (page no. 256) // Solution //When solving this type of problem,it is necessary to note carefully the information given and to write the correct energy equation for this process.Because the process is carried out at constant volume,the heat added equals the change in inernal energy.Because the change in internal energy per pound for the ideal gas is cv*(T2-T1),the total change in internal energy for m pounds must equals the heat added.Thus, //data given Q=0.33; //heat //Initial conditions V=60; //in^3 //volume m=0.0116; //lbs //mass p1=90; //psia //pressure T1=460+40; //Fahrenheit temperature converted to absolute temperature //Final condition=Initial condition + heat V=60; //in^3 //volume m=0.0116; //lbs //mass p2=108; //psia //pressure T2=460+140; //Fahrenheit temperature converted to absolute temperature //unit:R //Q=m*(u2-u1)=m*cv*(T2-T1) cv=Q/(m*(T2-T1)); //specific heat at constant volume //Btu/lbm*R printf("Specific heat at constant volume is %f Btu/lbm*R\n",cv); //To obtain cp,it is first necessary to obtain R.Enough information was given in the initial conditions of the problem to apply eqn. p*V=m*R*T R=(144*p1*(V/1728))/(m*T1); //1 ft^2=144 in^2 //1 ft^3=1728 in^3 //Unit:ft*lbf/lbm*R //constant of proportionality printf("Constant of proportionality R is %f ft*lbf/lbm*R\n",R); //cp-cv=(R/J) J=778; //conversion factor cp=cv+(R/J); //Specific heat at constant pressure //Btu/lbm*R printf("Specific heat at constant pressure is %f Btu/lbm*R\n",cp);
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Ex6_4.sce
clc; clear; Ip0=0.5*10^-3 //in A tau_p0=5*10^-7 //in s Const=0.026 //constant for kT/e in V //Calculation Cd0=(1/(2*Const))*tau_p0*Ip0 mprintf("Diffusion Capacitance= %.1e F",Cd0) //The answers vary due to round off error
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11_1.sce
clc //initialization of varaibles P1=15 //psia T1=80+460 //R dm=3 //lb T2=75+460 //R P2=25 //psia //calculations mratio=P1*T2/(P2*T1) m2=dm/(1-mratio) V2=m2*55.16*T2/(P2*144) //results printf("Volume of the apparatus = %.1f cu ft",V2)
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ex6_10.sce
//Determine the collector current at two different B clear; clc; //soltion //given //At B=50 B=50; //dc beta Rc=2;//ohm //resistor connected to collector Re=1000;//ohm //resistor connected to emitter Rb=300*10^3;//ohm //resistor connected to base Vcc=9;//V //Voltage supply across the collector resistor Ib=Vcc/(Rb+B*Re); //Base current Ic=B*Ib; //Colletor current printf("the collector current at (B=50)= %.3f mA\n",Ic*1000); //At B=150 B1=150; //dc beta Ib1=Vcc/(Rb+B1*Re); //Base current Ic1=B1*Ib1; //Colletor current printf("the collector current at (B=150)= %.0f mA\n",Ic1*1000); printf("The factor at which collector current increases %.2f",Ic1/Ic); //IN BOOK Ic(AT B=50)= 1.25 mA and Ic1/Ic=2.4 DUE TO APPROAXIMATION
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Ex1_7.sce
//Electric Drives:concepts and applications by V.subrahmanyam //Publisher:Tata McGraw-Hill //Edition:Second //Ex1_7 clc; clear; V=250;// voltage in V I=40;//Current in A Ro=0.4;// Resistance in ohm R1=2.725;// Resistance in ohm R2=3.5;// Resistance in ohm Eb=125;// voltage in V Na=480;//Speed in rpm Na1=50.24;//Speed in rad/sec R=((1/R1)+(1/R2)); Vm=(V-(I*R1))/(R*R1); Em=Vm-(I*Ro); N=(Em/Eb)*Na; disp(N,'The speed of the motor in rpm is:') N1=(2*%pi*N)/60; Il=(V-Vm)/R1; Po=Em*I; T=Po/N1; disp(T,'The torque in Nm is:')
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EX6.sce
// Example 11.6: (b) R2/R1 // (c) Amount of feedback in decibels // (d) Vo, Vf, Vi // (e) Decrease in Af clc, clear disp("Part (b)"); A=1e4; Af=10; bta=(A/Af-1)/A; // Feedback factor R2_R1=1/bta-1; // R2/R1 disp(R2_R1,"R2/R1 ="); disp("Part (c)"); dB=20*log10(1+A*bta); // Amount of feedback in decibels disp(dB,"Amount of feedback (dB) ="); disp("Part (d)"); Vs=1; // in volts Vo=Af*Vs; // in volts Vf=bta*Vo; // in volts Vi=Vs-Vf; // in volts disp(Vo,"Vo (V) ="); disp(Vf,"Vf (V) ="); disp(Vi,"Vi (V) ="); disp("Part (e)"); A=80*A/100; // Decreased A Af_dash=A/(1+A*bta); // Decreased Af C=(Af-Af_dash)*100/Af; // Percentage decrease in Af disp(C,"Percentage decrease in Af (%) =");
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//find power of periodic signal x(t)=10sin(10*pi*t) clc; t=-0.5:0.01:0.5; x=10*sin(10*%pi*t);//given signal plot(t,x); n=length(t); //To calculate Power xsq=abs(x).^2;//adds squares of all the 'x' values(integrates 'x^2' terms) P=1/n*sum(xsq);//divide by n,to take the average rate of energy(gives power) disp('watts',P,'Power=');
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Example14_3.sce
//clear// //Caption:Program to determine the group delay and difference in propagation times //Example14.3 //page 502 clc; C = 3e08; //free space velocity in m/sec er = 2.1; //dielectric constant of teflon material fc1 = 10.3e09;//cutoff frequency for mode m =1 fc2 = 2*fc1; //cutoff frequency for mode m =2 f = 25e09; //operating frequency in Hz Vg1 = group_delay(C,er,fc1,f);//group delay for mode m = 1 Vg2 = group_delay(C,er,fc2,f);//group delay for mode m = 2 del_t = group_delay_difference(Vg1,Vg2); disp(ceil(del_t*1e10),'group delay difference in ps/cm del_t=') //Result //group delay difference in ps/cm del_t= // 33.
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ex5_17.sce
clc;clear; //Example 5.17 //given values W=2000;//wavelength in Angstrom Vs=4.2;//Work Function in eV e=1.6*10^-19;//the charge on electron in C //calculations E=12400/W; Emax=(E-Vs)*e; disp(Emax,'KE of fastest photoelectron in J'); Emin=0; disp(Emin,'KE of slowest moving electron in J'); Vo=Emax/e; disp(Vo,'Stopping potential in V'); Wo=12400/Vs; disp(Wo,'The cutoff wavelength in Angstrom')
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Example7_15.sce
//Chapter-7,Example7_15,pg 7-41 Rm=50 Im=20*10^-3 I=10 Rsh=(Im*Rm)/(I-Im) printf("shunt resistance for I=10A\n") printf("Rsh=%.2f ohm\n",Rsh) I=20 Rsh=(Im*Rm)/(I-Im) printf("shunt resistance for I=20A\n") printf("Rsh=%.2f ohm\n",Rsh) V=150 Rs=(V/Im)-Rm printf("series resistance for V=150V\n") printf("Rs=%.2f ohm\n",Rs) V=300 Rs=(V/Im)-Rm printf("series resistance for V=300V\n") printf("Rs=%.2f ohm",Rs)
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Ex9_3.sce
l=7//span, in m sigma_cbc=5//in MPa sigma_st=140//in MPa fy=250//in MPa m=18.66//modular ratio b=300//assume, in mm W1=35//imposed load on beam, in kN/m M=W1*l^2/8//in kN-m d=(M*10^6/0.87/b)^0.5//in mm d=910//approximately, in mm D=1.1*d+50//increase d by 10% for self-weight and cover is 50 mm D=1050//approximately, in mm W2=25*(b/10^3)*(D/10^3)//self-weight, in kN/m W=W1+W2//in kN/m M=W*l^2/8//in kN-m d=(M*10^6/0.87/b)^0.5//in mm d=1000//approximately, in mm dia=20//in mm D=d+dia/2+35//in mm Ast=round(M*10^6/sigma_st/0.87/d)//in sq mm n=Ast/0.785/20^2//no. of 20 mm dia bars n=7//assume Ast=n*0.785*20^2//in sq mm pt=Ast/b/D*100//pt=0.7, approximately As=round(0.85/fy*b*d)//minimum steel, As<Ast, hence OK Asf=0.1/100*b*d/2//side faced steel on each face, in sq mm //provide 6 mm dia bars s=1000*0.785*6^2/Asf//in mm s=188//assume, in mm V=W*l/2//in kN Tv=V*10^3/b/d//<Tcmax=1.6 MPa, hence OK //for M15 grade concrete and pt=0.7 Tc=0.33//in MPa //as Tv>Tc, shear reinforcement required Vs=V-Tc*b*d/10^3//in kN //provide 6 mm dia bars Asv=2*0.785*6^2//in sq mm sigma_sv=140//in MPa Sv=Asv*sigma_sv*d/Vs/10^3//in mm Sv=155//approximately, in mm Svmin=Asv*fy/0.4/b//in mm Svmin=117//approximately, in mm Sv=min(Sv,Svmin)//in mm mprintf("Summary of design\nSize of beam = %d x %d mm\nCover = 35 mm\nSteel= %d-20 mm dia bars\nStirrups = 6 mm dia @ %d mm c/c throughout\nSide faced steel-6 mm dia @ %d mm c/c on both vertical faces of beam",b,D,n,Sv,s)
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ex1_56.sce
//Exa:1.56 clc; clear; close; theta_1=20;//in degree celcius theta_2=35;//in degree celcius t_1=1/2;//in hours t_2=1;//in hours t=-(t_2-t_1)/log((theta_2/theta_1)-1);//in minutes theta_F=theta_1/(1-exp(-t_1/t)); theta=theta_F*(1-exp(-2/t)); disp(theta,'Temperature Rise After 2 hrs (in Degree Celcius)='); theta_F1=theta_F*0.8;//in Degree Celcius t_o=0.8*t;//in hours theta_o=theta_F1*(1-exp(-1/t_o)); disp(theta_o,'Temperature Rise from cold After 1 hr at full load (in Degree Celcius)=');
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Ex11_4.sce
//Tested on Windows 7 Ultimate 32-bit //Chapter 11 Oscillators and Multivibrators Pg no. 361 clear; clc; //Given R=4.7D3;//R1,R2,R3 resistances in RC filter circuit in ohms C=2.2D-9;//C1,C2,C3 resistances in RC filter circuit in farads //Solution f0=1/(2*%pi*R*C*sqrt(6));//frequency of oscillation in hertz printf("Frequency of oscillation f0 = %.3f kHz",f0/10^3);
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//chapter17 //example17.1 //page375 L1=58.6d-6 // H C1=300d-12 // F f=1/(2*%pi*(L1*C1)^0.5) printf("frequency of oscillations = %.3f Hz or %.3f kHz",f,f/1000) // in book the answer is 1199 kHz but the accurate answer is 1200.358 kHz
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//find... clc //solution //given P=50000//W N=150//rpm n=75 ft=4*10^6//N/m^2 rho=7200 Tmean=(P*60)/(2*%pi*N)//N-m printf("mean torque acig is,%f N-m\n",Tmean) //ref fig 22.14 q=4*%pi Wdpc=Tmean*q Wp=1.4*Wdpc//work done in power stroke....eq1 //from dia //Wp1=(0.5*%pi)*Tmax...eq2 Tmax=Wp/1.571//N-m printf("max torque is,%f N-m\n",Tmax) //BG=BF-FG BG=Tmax-Tmean//N-m BF=Tmax dE=Wp*(BG/BF)^2//N-m printf("dE is,%f N-m\n",dE) //let D be mean dia //let v be peripheral velo v=sqrt(ft/rho)//m/s D=(v*60)/(N*%pi)//m printf("the dia of wheel is,%f m\n",D) //let t be thickness and b be width of rim //b=4t //A=b*t=4*t^2 //N1-N2=0.01*N Cs=0.01 //dE=E*2*Cs E=dE/(2*Cs)//N-m Erim=(15/16)*E//N-m printf("Erim is,%f N-m\n",Erim) m=Erim*2/v^2//kg t=sqrt(m/271468) printf("the thickness and width si,%f m\n,%f m\n",t,4*t)
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Cparametros.sci
function [B,C,D,E,F,G] = Cparacmetros(VC,V,RL,RD,RP,C) R1=RL*RD; R2=R1*C; R3=RD+RL R4=RD*C; R5=RP*RL; R6=R2*RP; R7=R4*RP; R8=R7+R2; R9=RP+R3; A=R5+R1; B=VC*R6; C=VC*A; D=V*R1; E=VC*R9 F=VC*R8+V*R2; G=V*R3; endfunction
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Ex9_3.sce
//Ex 9.3 clc; clear; close; format('v',5); f0=800;//Hz //For Butterworth filter : f0=fH=f_3dB fH=f0;//Hz f_3dB=f0;//Hz BW=fH;//Hz disp(BW,"Bandwidth(Hz)");
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Ex6_4.txt
//Caption:Calculate R1,R2 and Actual UTP and LTP //Ex6.4 clc; clear; close; u=3//Upper trigger voltage(in volts) Ib=500//Max base current(in nA) Vcc=15//Collector voltage(in volts) i=Ib*0.1 R2=u*1000/i I=u/R2 Vo=Vcc-1 Vr1=Vo-u R1=Vr1/I utp=Vo*R2/(R1+R2) ltp=-utp disp(ltp,utp,R2,R1,'Circuit components R1,R2(in kilo ohm) and actual UTP and LTP(in volts)=')
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clear; clc; V_s=400; V_ph=V_s/2; a=160; r=cosd(180-a); m=3; V_or=r*(V_ph*(m/%pi)*sin(%pi/m)); printf("rms o/p voltage=%.3f V",V_or); R=2; X_L=1.5; th=atand(X_L/R); Z=sqrt(R^2+X_L^2); I_or=V_or/Z; printf("\nrms o/p current=%.2f A",I_or); printf("\nphase angle of o/p current=%.2f deg",-th) P=I_or^2*R; printf("\no/p power=%.2f W",P);
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//pathname=get_absolute_file_path('8.16.sce') //filename=pathname+filesep()+'8.16-data.sci' //exec(filename) //Steam flow rate(in kg/s): m=35 //From steam tables: h1=3530.9 //kJ/kg s1=6.9486 //kJ/kg.K s2=s1 x2=0.864 h2=2288.97 //kJ/kg v3=0.001017 //m^3/kg h3=251.40 //kJ/kg //Pump work(in kJ/kg): Wp=v3*(70-0.20)*10^2 //Turbine work(in kJ/kg): Wt=h1-h2 //Net work(in kJ/kg): Wnet=Wt-Wp //Power produced(in MW): P=m*Wnet/10^3 //Enthalpy at state 4(in kJ/kg): h4=h3+Wp //Total heat supplied to the boiler(in kJ/s): Q=m*(h1-h4) //Thermal efficiency: n=Wnet*m/Q*100 printf("\n RESULT \n") printf("\nNet power = %f MW",P) printf("\nThermal efficiency = %f percent",n)
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Ex1_2_u2.sce
//Example 1_2_u2 clc(); clear; //To calculate the wavelength of the radiation emitted h=6.63*10^-34 //units in m^2 kg s^-1 m=9.1*10^-31 //units in Kgs l=1 //units in nm l=l*10^-9 //units in meters c=3*10^8 //units in meters/sec lamda=(8*m*c*l^2)/(27*h) //units in meters lamda=lamda*10^9 //units in nm printf("The wavelength of the radiation is lamda=%.1fnm",lamda)
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Ex5_4.sce
//Ex5_4 clc RL=5*10^(3) disp("RL= "+string(RL)+ " ohm") //Load resistance RF=2.5*10^(3) disp("RF= "+string(RF)+ " ohm") // resistance Rs=50 disp("Rs= "+string(Rs)+ " ohm") // resistance ro=50*10^(3) disp("ro= "+string(ro)+ " ohm") // output resistance rd=ro // drain resistance rc=ro// Collector resistance disp("rc= "+string(rc)+ " ohm") // Collector resistance rbe=1*10^(3) disp("rbe= "+string(rbe)+ " ohm") //base -emitter resistance disp("For CG Amplifier") gm=5*10^(-3) disp("gm = "+string(gm)+" A/V")// transconductance for FET Ri=1/gm // formulae disp("Ri= 1/gm="+string(Ri)+ " ohm") // value of CGA (common gate amplifier)input resistance for FET Avs=gm*RL/(1+gm*Rs) disp("Avs=gm*RL/(1+gm*Rs)= "+string(Avs)) // Overall voltage gain for FET (CGA) Ro=rd*(1+gm*Rs) disp("Ro=rd*(1+gm*Rs)="+string(Ro)+ " ohm") //output resistance for FET (CGA) disp("For CB Amplifier") gm=50*10^(-3) disp("gm = "+string(gm)+" A/V")// transconductance for BJT Ri=1/gm // formulae disp("Ri= 1/gm="+string(Ri)+ " ohm") // value of CBA (common base amplifier)input resistance for BJT Avs=gm*RL/(1+gm*Rs) disp("Avs=gm*RL/(1+gm*Rs)= "+string(Avs)) // Overall voltage gain for BJT (CBA) Ro=gm*(rbe*rc) disp("Ro=gm*(rbe*rc)="+string(Ro)+ " ohm") //output resistance for BJT (CBA) //NOTE: I have calculated first all the parameters for CG amplifier and then for CB amplifier but in book parameters have been calculated alternatingly for CG and CB amplifiers.
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//page 96 clear; close; clc; disp('These four columns span the column space U,but they are not independent.') U=[1 3 3 2;0 0 3 1;0 0 0 0]; disp(U,'U='); disp('The columns that contains pivots (here 1st & 3rd) are a basis for the column space. These columns are independent, and it is easy to see that they span the space.In fact,the column space of U is just the x-y plane withinn R3. C(U) is not the same as the column space C(A) before elimination-but the number of independent columns did not change.')
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clc; //ex2.4 Vs=6; //volt Vd=0.7;//volt R1=10000;//ohm It=(Vs-Vd)/R1; //Total circuit current using kirchoff's volatage law disp('Ampere',It,"It=")
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//// //Variable Declaration n = 12 //Total Number of players j = 5 //Number player those can play match //Calculation P = factorial(n)/factorial(n-j) //Results printf("\n Maximum Possible permutations for 5 player to play are %8d",P)
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//Example 1.12 //Program to Compute convolution of given sequences //x(n)=[3 2 1 2], h(n)=[1 2 1 2]; clear; clc ; close ; x=[3 2 1 2]; h=[1 2 1 2]; y=convol(x,h); disp(y);
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00_recycleIdeal.tst
# A simple recycle test # set up thermo - the name can be anything, I just use # 'thermo' for convenience. Essentially the rhs causes # a thermo package to be created and assigned to the unit op # owning the name thermo - in the case the base flowsheet # Also note that for now spaces are needed around the operators (= + etc) # A further also is that case is always significant $thermo = VirtualMaterials.IdealLiquid/Ideal/HC / -> $thermo thermo + METHANOL ETHANOL units SI # Add a stream # for now creating a unit op requires module.class(), but this # will be stream lined in the future stream = Stream.Stream_Material() # Make the stream In port current to save typing # You can use cd (named because it is similar to change directory in # Unix and DOS) to sub objects in this case first to the unit op stream # and then to its port In. This is just a typing convenience as everything # could be done from the top level with full names i.e. stream.In.T = 360.15 cd stream.In # Mole fractions can be enter indivually (Fraction.METHANOL = .25) or all # together as below. Fraction = .5 .5 VapFrac = 0.4 T = 300 K MoleFlow = 3000 # Now create a recycle stream cd / # return to top level - only place a slash is used recycle = Stream.Stream_Material() cd recycle.In # Estimate the values in the stream # Estimates use the ~= operator in place of the normal = which # fixes values T ~= 460.15 K P ~= 715 MoleFlow ~= 300 Fraction # any object without an operator displays itself - here to get order Fraction ~= 0 .5 . # a dot represents the current obj for display purposes # add a mixer to combine the first stream with the recycle cd / mixer = Mixer.Mixer() # ports are connected with the -> operator. They would be disconnected # by having an empty rhs. Similarly "stream.In.T =" would remove any value # for the stream In port Temperature stream.Out -> mixer.In0 recycle.Out -> mixer.In1 mixer.Out # add a separator flash = Flash.SimpleFlash() mixer.Out -> flash.In # split the liquid from the flash splitter = Split.Splitter() flash.Liq0 -> splitter.In # set the flow in one of the splitter outlets splitter.Out1.MoleFlow = 200 # close the recycle splitter.Out1 -> recycle.In # All done - check some streams recycle.Out splitter.Liq0 #splitter.Liq0.Out splitter.Out0 flash.In
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//Exa 2.25 format('v',6) clc; clear; close; // Given data E= 5.95;// in eV EF= 6.25;// in eV delE= 0.01; // delE= 1-1/(1+exp((E-EF)/KT)) K=1.38*10^-23;// Boltzmann Constant in J/K // The temperature at which there is a 1 % probability that a state 0.30 eV below the Fermi energy level T = ((E-EF)/log(1/(1-delE) -1)*1.6*10^-19)/K;// in K disp(T,"The temperature in K is : ")
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clc Ps = 2.339 // Satutation pressure in kPa P = 100 // Atmospheric pressure in kPa W2 = (0.622*Ps)/(P-Ps) // Specific humidity hfg2 = 2454.1 // Latent heat of vaporization in kJ/kg hf2 = 83.96 // Enthalpy of fluid in kJ/kg cpa = 1.005 // COnstant pressure heat capacity of air hw1 = 2556.3// ENthalpy of water T2 = 20 // Exit tempeature of mixture in degree Celsius T1 = 30 // Inlet tempeature of mixture in degree Celsius W1 = (cpa*(T2-T1)+(W2*hfg2))/(hw1-hf2) // Specific humidity at inlet Pw1 = ((W1/0.622)*P)/(1+(W1/0.622)) // pressure due to moisture Ps1 = 4.246 // Saturation pressure in kPa fi = (Pw1/Ps1) // Humidity ratio printf("\n Example 15.2\n") printf("\n Humidity ratio of inlet mixture is %f kg vap./kg dry air",W1) printf("\n Relative humidity is %f percent",fi*100) //The answers vary due to round off error
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clc; VCC=8; VRC=0.5; RC=800; a=0.96; VCE=VCC-VRC;//VRC=IC*RC IC=VRC/RC; disp('mA',IC*10**3,"IC="); IE=IC/a; disp('mA',IE*10**3,"IE="); IB=IE-IC; disp('microA',IB*10**6,"IB=");
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// Dados do Boeing 747 para altitude de 40.000 pés e Mach = 0.90 ref. Nelson // Coeficientes laterais cyb = -0.564 cyp = 0 cyr = 0 clb = -0.074 cnb = 0.071 clp = -0.41 cnp = -0.0575 clr = 0.107 cnr = -0.125 clda = -0.134 cnda = 0.0035 cydr = 0.157 cldr = 0.107 cndr = -0.072 // Dimensões S = 17.10 // Área alar b = 10.18 // Envergadura c = 1.74 // Corda média //Massa m = 1247.38 // Momentos de inércia Ix = 1420.90 Iy = 4967.45 Iz = 4786.04 u0 = 53.7 // Velocidade de cruzeiro do Boeing 747 // Dados do ambiente rho = 1.225 // Densidade atmosférica g = 9.81 // Gravidade // Pré-cálculo das constantes do espaço de estados Q = 1/2*rho*u0^2 Fyv = Q*S*cyb/u0 Fyp = Q*S*b*cyp/(2*u0) Fyr = Q*S*b*cyr/(2*u0) Mxv = Q*S*b*clb/u0 Mxp = Q*S*b^2*clp/(2*u0) Mxr = Q*S*b^2*clr/(2*u0) Mzv = Q*S*b*cnb/(u0) Mzp = Q*S*b^2*cnp/(2*u0) Mzr = Q*S*b^2*cnr/(2*u0) Fydr = Q*S*cydr Mxda = Q*S*b*clda Mxdr = Q*S*b*cldr Mzda = Q*S*b*cnda Mzdr = Q*S*b*cndr // Constantes da linearização theta0 = 0 // Definição das matrizes do espaço de estados // Espaço de Estados do tipo: dx/dt = Ax + Bu e y = Cx + Du A = [[Fyv/m,Fyp/m,(Fyr/m-u0/u0),g*cos(theta0)/u0];[Mxv/Ix,Mxp/Ix,Mxr/Ix,0];[Mzv/Iz,Mzp/Iz,Mzr/Iz,0];[0,1,0,0]] B = [[0,Fydr/m];[Mxda/Ix,Mxdr/Ix];[Mzda/Iz,Mzdr/Iz];[0,0]] C = [[1,0,0,0];[0,0,1,0]] D = [[0,0];[0,0]] E = [[-Fyv/m,0,0];[Mxv/Ix,Mxp/Ix,Mxr/Ix];[-Mzv/Iz,-Mzp/Iz,-Mzr/Iz];[0,0,0]]
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clc //initialisation of variables H= 8 //in x= 32.5 //in y= 33.7 //in //CALCULATIONS Cv= sqrt(x^2/(4*y*H)) //RESULTS printf (' Coefficient of velocity = %.3f ',Cv)
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//Example 3.7 //what is the heat imput to the boiling. //Given id=2.5*10^-2 //m, internal diameter of glass tube t=0.3*10^-2 //m, thickness of wall l=2.5 //m, length of nichrome wire L=0.12 //m, length of steel covered with heating coil Re=16.7 //ohm, electrical resistance ti=2.5*10^-2 //m, thickness of layer of insulation kg=1.4 //W/m C, thermal conductivity of glass ki=0.041 //W/m C, thermal conductivity of insulation T1=91 //C, boiling temp. of liquid T2=27 //C, ambient temp. ho=5.8 //W/m ^2 C outside air film coefficient V=90 //V, voltage //Calculation Rc=Re*l //ohm, resistance of heating coil Q=V^2/Rc //W, rate of heat generation ri=id/2 //m, inner radius of glass tube r_=ri+t //m, outer radius of glass tube ro=r_+ti //m,outer radius of insulation //heat transfer resistance of glass wall Rg=log(r_/ri)/(2*%pi*L*kg) //combined resistance of insulation and outer air film Rt=log(ro/r_)/(2*%pi*L*ki)+1/(2*%pi*ro*L*ho) //Rate of heat input to the boiling liquid in steel=Q1=(Ts-T1)/Rg //Rate of heat loss through insulation ,Q2=(Ts-To)/(Rt) //Q1+Q2=Q Ts=(Q+ T1/Rg +T2/Rt)/(1/Rg +1/Rt) Q1=(Ts-T1)/Rg Q2=Q-Q1 printf("the heat imput to the boiling.is %f W",Q1)
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//Exa:3.4.1 clc; clear; close; B=1;//in tesla B1=1.1;//in Tesla B2=1.45;//in Tesla H1=1000;//in Ampere/meter H2=2500;//in Ampere/meter b=((H1*B2)-(H2*B2))/((H1*H2*B1)-(H1*H2*B2)); disp(b,'b='); a=(B1/H1)+(b*B1); disp(a,'a='); H=B/(a-(b*B)); u_r=B/(4*%pi*H*10^-7); disp(u_r,'Relative Permeablity=')