Datasets:
pierreqi
/
scilab_code

Dataset card Data Studio Files
xet
Community
blob_id
stringlengths
40
40
directory_id
stringlengths
40
40
path
stringlengths
4
214
content_id
stringlengths
40
40
detected_licenses
listlengths
0
50
license_type
stringclasses
2 values
repo_name
stringlengths
6
115
snapshot_id
stringlengths
40
40
revision_id
stringlengths
40
40
branch_name
stringclasses
21 values
visit_date
timestamp[us]
revision_date
timestamp[us]
committer_date
timestamp[us]
github_id
int64
141k
586M
star_events_count
int64
0
30.4k
fork_events_count
int64
0
9.67k
gha_license_id
stringclasses
8 values
gha_event_created_at
timestamp[us]
gha_created_at
timestamp[us]
gha_language
stringclasses
50 values
src_encoding
stringclasses
23 values
language
stringclasses
1 value
is_vendor
bool
1 class
is_generated
bool
1 class
length_bytes
int64
5
10.4M
extension
stringclasses
29 values
filename
stringlengths
2
96
content
stringlengths
5
10.4M
1f1c4643e970ef2090e43a0979952866585891e1
449d555969bfd7befe906877abab098c6e63a0e8
/24/CH22/EX22.3/Example22_3.sce
5168600ca1bf0bcd27dd8356c6e0f534659499dd
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
433
sce
Example22_3.sce
exec('electrostatics.sci', -1) //Given that Q = 1 //(say) q1 = Q q2 = 0 a = 1 //(say) //Sample Problem 22-3a printf("**Sample Problem 22-3a**\n") q1 = (q1 + q2)/2 q2 = q1 F = coulomb(q1, q2, a) printf("The net force between the two sphere is %eQ^2/a^2\n", F) //Sample Problem 22-3b printf("\n**Sample Problem 22-3b**\n") q1 = 0 F = coulomb(q1, q2, a) printf("The net force between the two sphere is %fN", F)
df9c96366b7d7af05e8b7ff3b4cd649f6c3edcff
8217f7986187902617ad1bf89cb789618a90dd0a
/browsable_source/2.3/Unix-Windows/scilab-2.3/macros/percent/%lsst.sci
ba14eda0f5911d8364b23a8d0549f2c13fbcb4ee
[ "LicenseRef-scancode-warranty-disclaimer", "LicenseRef-scancode-public-domain", "MIT" ]
permissive
clg55/Scilab-Workbench
4ebc01d2daea5026ad07fbfc53e16d4b29179502
9f8fd29c7f2a98100fa9aed8b58f6768d24a1875
refs/heads/master
2023-05-31T04:06:22.931111
2022-09-13T14:41:51
2022-09-13T14:41:51
258,270,193
0
1
null
null
null
null
UTF-8
Scilab
false
false
150
sci
%lsst.sci
function s=%lsst(s) //s=%lsst(s) <=> s=s' in state-space //! [a,b,c,d,x,dom]=s(2:7) s=tlist(['lss','A','B','C','D','X0','dt'],a',c',b',d',x,dom)
67356e5bb1320fa84aabcd2df8a5c4eb212b3c26
449d555969bfd7befe906877abab098c6e63a0e8
/2489/CH4/EX4.2/4_2.sce
ce6544498c4576c1e848de48926e58b4f9d52abc
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
188
sce
4_2.sce
clc //Intitalisation of variables clear v1= 360 //ml T1= 15 //C v2= 480 //ml //CALCULATIONS T2= v2*(273+T1)/v1 Tc= T2-273 //RESULTS printf ('Centigrade temperature = %.f C',Tc)
4f78ae9366f4a2a9db87fc5372a8866a590c1eb9
449d555969bfd7befe906877abab098c6e63a0e8
/1385/CH16/EX16.3/16_3.sce
1656db37f77bcdb7701611f4d1a5c9bf487784be
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
193
sce
16_3.sce
clc //initialisation of variables p= 60 //percent x= 0.030 //v E= -0.039 //v //CALCULATIONS V= E-x*log10((1-(p/100))/(p/100)) //RESULTS printf (' Redox potential of sample= %.3f v',V)
5f195287121efac749a155586fada9763501e4cd
c9720259ca558b771c949ca78e71ccf181b7bcca
/Scilab/loader_linux64.sce
a6451fd001bae3f4121d48ee983296de085588bb
[ "BSD-3-Clause" ]
permissive
Strifus/x2c-audio
1e2cf30c76876ef8a4c152f7002df1608db9d4e0
2837a09842f62d0d66d291ecb72eae02741d2661
refs/heads/master
2020-06-06T23:43:24.283232
2020-01-06T17:34:25
2020-01-06T17:34:25
192,877,737
0
0
BSD-3-Clause
2020-01-06T17:21:18
2019-06-20T08:09:01
null
UTF-8
Scilab
false
false
2,207
sce
loader_linux64.sce
// This file is released under the 3-clause BSD license. See COPYING-BSD. // Generated by builder.sce : Please, do not edit this file // ---------------------------------------------------------------------------- // Audio_linux64_path = get_absolute_file_path('loader_linux64.sce'); // // ulink previous function with same name [bOK, ilib] = c_link('x2c_RectangleWav_FiP8_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_RectangleWav_FiP16_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_RectangleWav_FiP32_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_RectangleWav_Float32_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_RectangleWav_Float64_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_SineWave_FiP8_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_SineWave_FiP16_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_SineWave_FiP32_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_SineWave_Float32_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_SineWave_Float64_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_TriangleWave_FiP8_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_TriangleWave_FiP16_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_TriangleWave_FiP32_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_TriangleWave_Float32_C'); if bOK then ulink(ilib); end // [bOK, ilib] = c_link('x2c_TriangleWave_Float64_C'); if bOK then ulink(ilib); end // link(Audio_linux64_path + 'libAudio_linux64' + getdynlibext(), ['x2c_RectangleWav_FiP8_C','x2c_RectangleWav_FiP16_C','x2c_RectangleWav_FiP32_C','x2c_RectangleWav_Float32_C','x2c_RectangleWav_Float64_C','x2c_SineWave_FiP8_C','x2c_SineWave_FiP16_C','x2c_SineWave_FiP32_C','x2c_SineWave_Float32_C','x2c_SineWave_Float64_C','x2c_TriangleWave_FiP8_C','x2c_TriangleWave_FiP16_C','x2c_TriangleWave_FiP32_C','x2c_TriangleWave_Float32_C','x2c_TriangleWave_Float64_C'],'c'); // remove temp. variables on stack clear Audio_linux64_path; clear bOK; clear ilib; // ----------------------------------------------------------------------------
56ba17c1ec2bcf70a85eb9eda7e24a3f5f82f2a1
449d555969bfd7befe906877abab098c6e63a0e8
/1628/CH3/EX3.20/Ex3_20.sce
c4f28749275217f7130ad8790b88f001d871d3c5
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
867
sce
Ex3_20.sce
// Examle 3.20 // From the diagram (3.38) Apply KVL to all the 3 loop. // Loop-1 19I1-12I2+0I3-= 60................(i // Loop-2 -12I1+18I2-6I3= 0...............(ii // Loop-3 0I1-6I2+18I3= 0.................(iii // By using matrix form will get A*X = B formate delta=[19 -12 0 ; -12 18 -6 ; 0 -6 18 ]; // value of A d=det(delta); // Determinant of A delta1=[60 -12 0 ; 0 18 -6 ; 0 -6 18 ]; // value of A1 (when 1st colomn is replace by B) d1=det(delta1); // Determinant of A1 Is=d1/d; // Current drawn from source (Is=I1) disp(' Current drawn from source (Is) = '+string(Is)+' Amp'); // p 79 3.20
6fc7b2dbc747115206aac621a47f36db7b3f0620
449d555969bfd7befe906877abab098c6e63a0e8
/1652/CH13/EX13.1/13_1.sce
d588e21ab1423601f3e0d1df222ddee8923f3da6
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
131
sce
13_1.sce
clc //Initialization of variables n1=10 //mol n2=12 //mol //calculations dn=n1-n2 //results printf("dHp = dEv- %d *RT",dn)
b2c7b6bc457c33635ff0a59570cda9a9791439f9
f542bc49c4d04b47d19c88e7c89d5db60922e34e
/PresentationFiles_Subjects/CONT/PU17QHW/ATWM1_Working_Memory_MEG_PU17QHW_Session1/ATWM1_Working_Memory_MEG_Salient_Uncued_Run1.sce
d00f757f83cfae76814efe1b942627e4300edc51
[]
no_license
atwm1/Presentation
65c674180f731f050aad33beefffb9ba0caa6688
9732a004ca091b184b670c56c55f538ff6600c08
refs/heads/master
2020-04-15T14:04:41.900640
2020-02-14T16:10:11
2020-02-14T16:10:11
56,771,016
0
1
null
null
null
null
UTF-8
Scilab
false
false
48,405
sce
ATWM1_Working_Memory_MEG_Salient_Uncued_Run1.sce
# ATWM1 MEG Experiment scenario = "ATWM1_Working_Memory_MEG_salient_uncued_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; 42 61 292 292 399 125 2092 2992 2292 fixation_cross gabor_144 gabor_058 gabor_085 gabor_020 gabor_144_alt gabor_058_alt gabor_085 gabor_020 "1_1_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2100_3000_2300_gabor_patch_orientation_144_058_085_020_target_position_1_2_retrieval_position_1" gabor_004_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_1_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_004_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2242 2992 2292 fixation_cross gabor_136 gabor_076 gabor_118 gabor_057 gabor_136 gabor_076 gabor_118_alt gabor_057_alt "1_2_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2250_3000_2300_gabor_patch_orientation_136_076_118_057_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_164_framed gabor_circ blank blank blank blank fixation_cross_white "1_2_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_164_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2042 2992 2292 fixation_cross gabor_153 gabor_021 gabor_069 gabor_042 gabor_153_alt gabor_021_alt gabor_069 gabor_042 "1_3_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_2300_gabor_patch_orientation_153_021_069_042_target_position_1_2_retrieval_position_1" gabor_103_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_3_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_103_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 1842 2992 2542 fixation_cross gabor_116 gabor_179 gabor_070 gabor_147 gabor_116 gabor_179_alt gabor_070_alt gabor_147 "1_4_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_300_300_399_1850_3000_2550_gabor_patch_orientation_116_179_070_147_target_position_2_3_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_147_framed blank blank blank blank fixation_cross_white "1_4_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_147_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1842 2992 2592 fixation_cross gabor_021 gabor_166 gabor_130 gabor_057 gabor_021_alt gabor_166 gabor_130_alt gabor_057 "1_5_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1850_3000_2600_gabor_patch_orientation_021_166_130_057_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_085_framed gabor_circ blank blank blank blank fixation_cross_white "1_5_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_085_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2042 2992 2342 fixation_cross gabor_073 gabor_145 gabor_090 gabor_116 gabor_073_alt gabor_145 gabor_090 gabor_116_alt "1_6_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_2350_gabor_patch_orientation_073_145_090_116_target_position_1_4_retrieval_position_1" gabor_026_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_6_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_026_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1992 2992 2192 fixation_cross gabor_046 gabor_079 gabor_135 gabor_117 gabor_046_alt gabor_079 gabor_135 gabor_117_alt "1_7_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_2200_gabor_patch_orientation_046_079_135_117_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_117_framed blank blank blank blank fixation_cross_white "1_7_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_117_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1992 2992 2542 fixation_cross gabor_126 gabor_021 gabor_063 gabor_037 gabor_126_alt gabor_021_alt gabor_063 gabor_037 "1_8_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2000_3000_2550_gabor_patch_orientation_126_021_063_037_target_position_1_2_retrieval_position_1" gabor_173_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_8_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_173_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1942 2992 1992 fixation_cross gabor_086 gabor_129 gabor_005 gabor_156 gabor_086_alt gabor_129 gabor_005_alt gabor_156 "1_9_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1950_3000_2000_gabor_patch_orientation_086_129_005_156_target_position_1_3_retrieval_position_1" gabor_086_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_9_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_086_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2192 2992 2042 fixation_cross gabor_081 gabor_149 gabor_059 gabor_115 gabor_081 gabor_149_alt gabor_059_alt gabor_115 "1_10_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2050_gabor_patch_orientation_081_149_059_115_target_position_2_3_retrieval_position_2" gabor_circ gabor_099_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_10_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_099_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 1942 2992 2442 fixation_cross gabor_099 gabor_040 gabor_017 gabor_123 gabor_099 gabor_040_alt gabor_017_alt gabor_123 "1_11_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_300_300_399_1950_3000_2450_gabor_patch_orientation_099_040_017_123_target_position_2_3_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_123_framed blank blank blank blank fixation_cross_white "1_11_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_123_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1742 2992 1992 fixation_cross gabor_025 gabor_091 gabor_002 gabor_161 gabor_025_alt gabor_091_alt gabor_002 gabor_161 "1_12_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2000_gabor_patch_orientation_025_091_002_161_target_position_1_2_retrieval_position_1" gabor_025_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_12_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_025_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2192 2992 2492 fixation_cross gabor_052 gabor_113 gabor_087 gabor_175 gabor_052_alt gabor_113_alt gabor_087 gabor_175 "1_13_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2500_gabor_patch_orientation_052_113_087_175_target_position_1_2_retrieval_position_2" gabor_circ gabor_159_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_13_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_159_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 2092 2992 2042 fixation_cross gabor_084 gabor_023 gabor_007 gabor_055 gabor_084 gabor_023_alt gabor_007_alt gabor_055 "1_14_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_300_300_399_2100_3000_2050_gabor_patch_orientation_084_023_007_055_target_position_2_3_retrieval_position_1" gabor_084_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_14_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_084_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1892 2992 2092 fixation_cross gabor_045 gabor_103 gabor_169 gabor_024 gabor_045 gabor_103_alt gabor_169_alt gabor_024 "1_15_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_2100_gabor_patch_orientation_045_103_169_024_target_position_2_3_retrieval_position_2" gabor_circ gabor_152_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_15_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_152_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1792 2992 2392 fixation_cross gabor_142 gabor_086 gabor_164 gabor_111 gabor_142_alt gabor_086 gabor_164_alt gabor_111 "1_16_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_2400_gabor_patch_orientation_142_086_164_111_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_164_framed gabor_circ blank blank blank blank fixation_cross_white "1_16_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_164_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2092 2992 2042 fixation_cross gabor_008 gabor_074 gabor_030 gabor_144 gabor_008 gabor_074_alt gabor_030_alt gabor_144 "1_17_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2100_3000_2050_gabor_patch_orientation_008_074_030_144_target_position_2_3_retrieval_position_2" gabor_circ gabor_120_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_17_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_120_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1792 2992 2492 fixation_cross gabor_004 gabor_039 gabor_174 gabor_156 gabor_004_alt gabor_039_alt gabor_174 gabor_156 "1_18_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_2500_gabor_patch_orientation_004_039_174_156_target_position_1_2_retrieval_position_2" gabor_circ gabor_039_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_18_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_039_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2242 2992 2342 fixation_cross gabor_057 gabor_081 gabor_138 gabor_028 gabor_057 gabor_081_alt gabor_138_alt gabor_028 "1_19_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_2350_gabor_patch_orientation_057_081_138_028_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_138_framed gabor_circ blank blank blank blank fixation_cross_white "1_19_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_138_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1842 2992 2242 fixation_cross gabor_052 gabor_096 gabor_021 gabor_068 gabor_052_alt gabor_096_alt gabor_021 gabor_068 "1_20_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2250_gabor_patch_orientation_052_096_021_068_target_position_1_2_retrieval_position_2" gabor_circ gabor_096_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_20_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_096_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2092 2992 2092 fixation_cross gabor_011 gabor_116 gabor_131 gabor_074 gabor_011 gabor_116_alt gabor_131_alt gabor_074 "1_21_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2100_3000_2100_gabor_patch_orientation_011_116_131_074_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_180_framed gabor_circ blank blank blank blank fixation_cross_white "1_21_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_180_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 1892 2992 1942 fixation_cross gabor_094 gabor_059 gabor_165 gabor_014 gabor_094_alt gabor_059_alt gabor_165 gabor_014 "1_22_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_300_300_399_1900_3000_1950_gabor_patch_orientation_094_059_165_014_target_position_1_2_retrieval_position_3" gabor_circ gabor_circ gabor_165_framed gabor_circ blank blank blank blank fixation_cross_white "1_22_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_165_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1942 2992 2592 fixation_cross gabor_114 gabor_052 gabor_073 gabor_008 gabor_114 gabor_052_alt gabor_073_alt gabor_008 "1_23_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1950_3000_2600_gabor_patch_orientation_114_052_073_008_target_position_2_3_retrieval_position_2" gabor_circ gabor_052_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_23_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_052_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2192 2992 2192 fixation_cross gabor_043 gabor_126 gabor_061 gabor_166 gabor_043_alt gabor_126 gabor_061_alt gabor_166 "1_24_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2200_gabor_patch_orientation_043_126_061_166_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_106_framed gabor_circ blank blank blank blank fixation_cross_white "1_24_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_106_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1942 2992 2192 fixation_cross gabor_076 gabor_140 gabor_098 gabor_029 gabor_076 gabor_140 gabor_098_alt gabor_029_alt "1_25_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1950_3000_2200_gabor_patch_orientation_076_140_098_029_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_029_framed blank blank blank blank fixation_cross_white "1_25_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_029_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 2142 2992 2242 fixation_cross gabor_086 gabor_023 gabor_105 gabor_132 gabor_086_alt gabor_023_alt gabor_105 gabor_132 "1_26_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_300_300_399_2150_3000_2250_gabor_patch_orientation_086_023_105_132_target_position_1_2_retrieval_position_3" gabor_circ gabor_circ gabor_105_framed gabor_circ blank blank blank blank fixation_cross_white "1_26_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_105_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1842 2992 2342 fixation_cross gabor_098 gabor_139 gabor_083 gabor_122 gabor_098_alt gabor_139 gabor_083 gabor_122_alt "1_27_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1850_3000_2350_gabor_patch_orientation_098_139_083_122_target_position_1_4_retrieval_position_1" gabor_098_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_27_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_098_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2042 2992 1942 fixation_cross gabor_115 gabor_088 gabor_155 gabor_030 gabor_115_alt gabor_088 gabor_155_alt gabor_030 "1_28_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2050_3000_1950_gabor_patch_orientation_115_088_155_030_target_position_1_3_retrieval_position_1" gabor_115_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_28_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_115_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2042 2992 2292 fixation_cross gabor_019 gabor_127 gabor_180 gabor_040 gabor_019_alt gabor_127 gabor_180_alt gabor_040 "1_29_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_2300_gabor_patch_orientation_019_127_180_040_target_position_1_3_retrieval_position_1" gabor_068_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_29_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_068_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1992 2992 2442 fixation_cross gabor_113 gabor_092 gabor_147 gabor_171 gabor_113_alt gabor_092 gabor_147_alt gabor_171 "1_30_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2000_3000_2450_gabor_patch_orientation_113_092_147_171_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_007_framed gabor_circ blank blank blank blank fixation_cross_white "1_30_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_007_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2242 2992 1992 fixation_cross gabor_120 gabor_154 gabor_098 gabor_031 gabor_120_alt gabor_154 gabor_098_alt gabor_031 "1_31_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_2000_gabor_patch_orientation_120_154_098_031_target_position_1_3_retrieval_position_1" gabor_120_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_31_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_120_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1892 2992 2542 fixation_cross gabor_178 gabor_091 gabor_119 gabor_010 gabor_178_alt gabor_091_alt gabor_119 gabor_010 "1_32_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1900_3000_2550_gabor_patch_orientation_178_091_119_010_target_position_1_2_retrieval_position_1" gabor_178_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_32_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_178_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 2092 2992 2242 fixation_cross gabor_089 gabor_032 gabor_007 gabor_062 gabor_089_alt gabor_032 gabor_007_alt gabor_062 "1_33_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_300_300_399_2100_3000_2250_gabor_patch_orientation_089_032_007_062_target_position_1_3_retrieval_position_2" gabor_circ gabor_170_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_33_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_170_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2042 2992 2142 fixation_cross gabor_160 gabor_091 gabor_046 gabor_130 gabor_160_alt gabor_091 gabor_046_alt gabor_130 "1_34_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2050_3000_2150_gabor_patch_orientation_160_091_046_130_target_position_1_3_retrieval_position_1" gabor_021_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_34_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_021_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1792 2992 2242 fixation_cross gabor_151 gabor_077 gabor_043 gabor_014 gabor_151_alt gabor_077 gabor_043_alt gabor_014 "1_35_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_2250_gabor_patch_orientation_151_077_043_014_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_093_framed gabor_circ blank blank blank blank fixation_cross_white "1_35_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_093_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2142 2992 1892 fixation_cross gabor_082 gabor_105 gabor_155 gabor_043 gabor_082 gabor_105 gabor_155_alt gabor_043_alt "1_36_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2150_3000_1900_gabor_patch_orientation_082_105_155_043_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_155_framed gabor_circ blank blank blank blank fixation_cross_white "1_36_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_155_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 1892 2992 2142 fixation_cross gabor_160 gabor_095 gabor_021 gabor_137 gabor_160_alt gabor_095 gabor_021_alt gabor_137 "1_37_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_300_300_399_1900_3000_2150_gabor_patch_orientation_160_095_021_137_target_position_1_3_retrieval_position_2" gabor_circ gabor_047_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_37_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_047_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1892 2992 2192 fixation_cross gabor_032 gabor_119 gabor_137 gabor_001 gabor_032_alt gabor_119_alt gabor_137 gabor_001 "1_38_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1900_3000_2200_gabor_patch_orientation_032_119_137_001_target_position_1_2_retrieval_position_2" gabor_circ gabor_119_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_38_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_119_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1792 2992 1942 fixation_cross gabor_157 gabor_078 gabor_139 gabor_025 gabor_157 gabor_078_alt gabor_139_alt gabor_025 "1_39_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_1950_gabor_patch_orientation_157_078_139_025_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_139_framed gabor_circ blank blank blank blank fixation_cross_white "1_39_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_139_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1742 2992 1992 fixation_cross gabor_102 gabor_138 gabor_078 gabor_022 gabor_102_alt gabor_138_alt gabor_078 gabor_022 "1_40_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1750_3000_2000_gabor_patch_orientation_102_138_078_022_target_position_1_2_retrieval_position_1" gabor_054_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_40_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_054_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1792 2992 2042 fixation_cross gabor_110 gabor_157 gabor_177 gabor_005 gabor_110 gabor_157_alt gabor_177_alt gabor_005 "1_41_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_2050_gabor_patch_orientation_110_157_177_005_target_position_2_3_retrieval_position_2" gabor_circ gabor_021_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_41_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_021_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 1742 2992 1892 fixation_cross gabor_074 gabor_035 gabor_104 gabor_144 gabor_074_alt gabor_035_alt gabor_104 gabor_144 "1_42_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_300_300_399_1750_3000_1900_gabor_patch_orientation_074_035_104_144_target_position_1_2_retrieval_position_3" gabor_circ gabor_circ gabor_057_framed gabor_circ blank blank blank blank fixation_cross_white "1_42_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_057_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1742 2992 2392 fixation_cross gabor_036 gabor_175 gabor_089 gabor_108 gabor_036 gabor_175_alt gabor_089 gabor_108_alt "1_43_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2400_gabor_patch_orientation_036_175_089_108_target_position_2_4_retrieval_position_2" gabor_circ gabor_175_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_43_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_175_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1792 2992 2342 fixation_cross gabor_166 gabor_006 gabor_077 gabor_033 gabor_166_alt gabor_006_alt gabor_077 gabor_033 "1_44_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1800_3000_2350_gabor_patch_orientation_166_006_077_033_target_position_1_2_retrieval_position_1" gabor_166_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_44_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_166_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2142 2992 1892 fixation_cross gabor_005 gabor_076 gabor_022 gabor_136 gabor_005 gabor_076_alt gabor_022_alt gabor_136 "1_45_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2150_3000_1900_gabor_patch_orientation_005_076_022_136_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_022_framed gabor_circ blank blank blank blank fixation_cross_white "1_45_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_022_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 1892 2992 2392 fixation_cross gabor_161 gabor_051 gabor_110 gabor_128 gabor_161_alt gabor_051 gabor_110_alt gabor_128 "1_46_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_300_300_399_1900_3000_2400_gabor_patch_orientation_161_051_110_128_target_position_1_3_retrieval_position_2" gabor_circ gabor_004_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_46_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_004_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2242 2992 2592 fixation_cross gabor_074 gabor_010 gabor_116 gabor_029 gabor_074_alt gabor_010_alt gabor_116 gabor_029 "1_47_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2250_3000_2600_gabor_patch_orientation_074_010_116_029_target_position_1_2_retrieval_position_2" gabor_circ gabor_010_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_47_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_010_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1992 2992 2542 fixation_cross gabor_048 gabor_099 gabor_132 gabor_009 gabor_048 gabor_099 gabor_132_alt gabor_009_alt "1_48_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_2550_gabor_patch_orientation_048_099_132_009_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_132_framed gabor_circ blank blank blank blank fixation_cross_white "1_48_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_132_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1842 2992 2192 fixation_cross gabor_102 gabor_127 gabor_143 gabor_086 gabor_102 gabor_127 gabor_143_alt gabor_086_alt "1_49_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1850_3000_2200_gabor_patch_orientation_102_127_143_086_target_position_3_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_037_framed blank blank blank blank fixation_cross_white "1_49_Retrieval_Working_Memory_MEG_P3_RL_Salient_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; 42 62 292 292 399 125 2142 2992 2142 fixation_cross gabor_092 gabor_005 gabor_072 gabor_151 gabor_092 gabor_005_alt gabor_072_alt gabor_151 "1_50_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2150_3000_2150_gabor_patch_orientation_092_005_072_151_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_072_framed gabor_circ blank blank blank blank fixation_cross_white "1_50_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_072_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1892 2992 2092 fixation_cross gabor_153 gabor_176 gabor_047 gabor_016 gabor_153_alt gabor_176_alt gabor_047 gabor_016 "1_51_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1900_3000_2100_gabor_patch_orientation_153_176_047_016_target_position_1_2_retrieval_position_1" gabor_104_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_51_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_104_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 2192 2992 2092 fixation_cross gabor_158 gabor_023 gabor_177 gabor_137 gabor_158_alt gabor_023 gabor_177 gabor_137_alt "1_52_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_300_300_399_2200_3000_2100_gabor_patch_orientation_158_023_177_137_target_position_1_4_retrieval_position_2" gabor_circ gabor_071_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_52_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_071_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2192 2992 2342 fixation_cross gabor_146 gabor_121 gabor_039 gabor_087 gabor_146_alt gabor_121_alt gabor_039 gabor_087 "1_53_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2350_gabor_patch_orientation_146_121_039_087_target_position_1_2_retrieval_position_2" gabor_circ gabor_169_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_53_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_169_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1942 2992 1892 fixation_cross gabor_144 gabor_025 gabor_059 gabor_090 gabor_144_alt gabor_025 gabor_059_alt gabor_090 "1_54_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1950_3000_1900_gabor_patch_orientation_144_025_059_090_target_position_1_3_retrieval_position_1" gabor_004_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_54_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_004_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2192 2992 2392 fixation_cross gabor_159 gabor_126 gabor_069 gabor_090 gabor_159_alt gabor_126_alt gabor_069 gabor_090 "1_55_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2200_3000_2400_gabor_patch_orientation_159_126_069_090_target_position_1_2_retrieval_position_1" gabor_109_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_55_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_109_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1842 2992 2592 fixation_cross gabor_150 gabor_081 gabor_012 gabor_117 gabor_150_alt gabor_081 gabor_012 gabor_117_alt "1_56_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1850_3000_2600_gabor_patch_orientation_150_081_012_117_target_position_1_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_166_framed blank blank blank blank fixation_cross_white "1_56_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_166_retrieval_position_4" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 2042 2992 2142 fixation_cross gabor_054 gabor_140 gabor_174 gabor_007 gabor_054_alt gabor_140_alt gabor_174 gabor_007 "1_57_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_300_300_399_2050_3000_2150_gabor_patch_orientation_054_140_174_007_target_position_1_2_retrieval_position_3" gabor_circ gabor_circ gabor_124_framed gabor_circ blank blank blank blank fixation_cross_white "1_57_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_124_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1842 2992 2242 fixation_cross gabor_119 gabor_140 gabor_031 gabor_094 gabor_119_alt gabor_140_alt gabor_031 gabor_094 "1_58_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1850_3000_2250_gabor_patch_orientation_119_140_031_094_target_position_1_2_retrieval_position_2" gabor_circ gabor_004_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_58_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_004_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 2242 2992 1992 fixation_cross gabor_055 gabor_033 gabor_010 gabor_082 gabor_055 gabor_033 gabor_010_alt gabor_082_alt "1_59_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_300_300_399_2250_3000_2000_gabor_patch_orientation_055_033_010_082_target_position_3_4_retrieval_position_2" gabor_circ gabor_033_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_59_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_033_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 2242 2992 2492 fixation_cross gabor_103 gabor_129 gabor_019 gabor_080 gabor_103_alt gabor_129 gabor_019_alt gabor_080 "1_60_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_2250_3000_2500_gabor_patch_orientation_103_129_019_080_target_position_1_3_retrieval_position_1" gabor_055_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_60_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_055_retrieval_position_1" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1742 2992 2492 fixation_cross gabor_152 gabor_090 gabor_003 gabor_026 gabor_152 gabor_090_alt gabor_003_alt gabor_026 "1_61_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1750_3000_2500_gabor_patch_orientation_152_090_003_026_target_position_2_3_retrieval_position_2" gabor_circ gabor_136_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_61_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_136_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1992 2992 1942 fixation_cross gabor_089 gabor_010 gabor_059 gabor_128 gabor_089 gabor_010_alt gabor_059 gabor_128_alt "1_62_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_1950_gabor_patch_orientation_089_010_059_128_target_position_2_4_retrieval_position_4" gabor_circ gabor_circ gabor_circ gabor_128_framed blank blank blank blank fixation_cross_white "1_62_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_128_retrieval_position_4" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1942 2992 2092 fixation_cross gabor_172 gabor_038 gabor_083 gabor_102 gabor_172 gabor_038_alt gabor_083_alt gabor_102 "1_63_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1950_3000_2100_gabor_patch_orientation_172_038_083_102_target_position_2_3_retrieval_position_3" gabor_circ gabor_circ gabor_083_framed gabor_circ blank blank blank blank fixation_cross_white "1_63_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_083_retrieval_position_3" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 64 292 292 399 125 2092 2992 2292 fixation_cross gabor_165 gabor_037 gabor_108 gabor_147 gabor_165_alt gabor_037 gabor_108_alt gabor_147 "1_64_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_300_300_399_2100_3000_2300_gabor_patch_orientation_165_037_108_147_target_position_1_3_retrieval_position_2" gabor_circ gabor_037_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_64_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_UncuedRetriev_retrieval_patch_orientation_037_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 61 292 292 399 125 1792 2992 2042 fixation_cross gabor_122 gabor_060 gabor_036 gabor_165 gabor_122_alt gabor_060 gabor_036_alt gabor_165 "1_65_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_300_300_399_1800_3000_2050_gabor_patch_orientation_122_060_036_165_target_position_1_3_retrieval_position_3" gabor_circ gabor_circ gabor_086_framed gabor_circ blank blank blank blank fixation_cross_white "1_65_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_CuedRetrieval_retrieval_patch_orientation_086_retrieval_position_3" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1992 2992 1942 fixation_cross gabor_089 gabor_133 gabor_074 gabor_157 gabor_089_alt gabor_133_alt gabor_074 gabor_157 "1_66_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2000_3000_1950_gabor_patch_orientation_089_133_074_157_target_position_1_2_retrieval_position_1" gabor_089_framed gabor_circ gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_66_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_089_retrieval_position_1" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1742 2992 2142 fixation_cross gabor_003 gabor_129 gabor_149 gabor_112 gabor_003 gabor_129_alt gabor_149 gabor_112_alt "1_67_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_2150_gabor_patch_orientation_003_129_149_112_target_position_2_4_retrieval_position_2" gabor_circ gabor_129_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_67_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_129_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 1742 2992 1892 fixation_cross gabor_123 gabor_043 gabor_012 gabor_176 gabor_123 gabor_043_alt gabor_012_alt gabor_176 "1_68_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_1750_3000_1900_gabor_patch_orientation_123_043_012_176_target_position_2_3_retrieval_position_2" gabor_circ gabor_043_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_68_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_043_retrieval_position_2" 2 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 63 292 292 399 125 2142 2992 2442 fixation_cross gabor_019 gabor_107 gabor_070 gabor_047 gabor_019_alt gabor_107 gabor_070_alt gabor_047 "1_69_Encoding_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_300_300_399_2150_3000_2450_gabor_patch_orientation_019_107_070_047_target_position_1_3_retrieval_position_2" gabor_circ gabor_153_framed gabor_circ gabor_circ blank blank blank blank fixation_cross_white "1_69_Retrieval_Working_Memory_MEG_P3_RL_Salient_DoChange_UncuedRetriev_retrieval_patch_orientation_153_retrieval_position_2" 1 58.69 58.69 -58.69 58.69 -58.69 -58.69 58.69 -58.69; 42 62 292 292 399 125 2142 2992 2442 fixation_cross gabor_048 gabor_074 gabor_180 gabor_001 gabor_048 gabor_074 gabor_180_alt gabor_001_alt "1_70_Encoding_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_300_300_399_2150_3000_2450_gabor_patch_orientation_048_074_180_001_target_position_3_4_retrieval_position_3" gabor_circ gabor_circ gabor_180_framed gabor_circ blank blank blank blank fixation_cross_white "1_70_Retrieval_Working_Memory_MEG_P3_RL_Salient_NoChange_CuedRetrieval_retrieval_patch_orientation_180_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; };
94b841a0f9d0885a7472f5aa9812edbfc34aec9a
449d555969bfd7befe906877abab098c6e63a0e8
/24/CH26/EX26.2/Example26_2.sce
a6e443d7a262f2443df2fd6f747c4129eff3d83d
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
525
sce
Example26_2.sce
exec('electrostatics.sci', -1) //Given that C1 = 12 //in uF C2 = 5.30 //in uF C3 = 4.50 //in uF V = 12.5 //in Volts //Sample Problem 26-2a printf("**Sample Problem 26-2a**\n") C12 = C1 + C2 //in series C123 = C12*C3/(C12 + C3) //in parallel printf("The equivalent capacitance for the given circuit is %fuF\n", C123) //Sample Problem 26-2b printf("\n**Sample Problem 26-2b**\n") Q123 = C123*V Q12 = Q123 //in series Q1 = Q12*C1/(C1+C2) printf("The charge on the capacitor C1 is equal to %fuC", Q1)
88b18b0799ea8366cbd77f81ac08d6c920542043
af7cd799acb90ee773382c3b1b8630e092971cd8
/TP3_exo6_exo7/methode_iterative.sce
e8383e32504f31095001b60ef7cbe5909f400e64
[]
no_license
Souad742/my-repo
1e080b1a593aa1f8f24edd2ed4a766680344510f
3c0df0e0cf230cbd6160d8e9a08ca7b51bdbf324
refs/heads/main
2023-02-03T05:06:47.269245
2020-12-18T23:32:27
2020-12-18T23:32:27
305,127,993
0
0
null
null
null
null
UTF-8
Scilab
false
false
1,882
sce
methode_iterative.sce
function[sol,relres,resvecJ,niter]= myjacobi(A,b,tol,nmaxit) x0=zeros(n,1); normb=norm(b); resvecJ=zeros(nmaxit,1); res=b-A*x0; relres=norm(res)/normb; D=(1.)./diag(A); niter=0; while(relres>tol) &(niter<nmaxit) niter=niter+1; sol =x0 + D.*res; x0=sol; res=b-A*x0; relres=norm(res)/normb; resvecJ(niter)=relres; end endfunction function[sol,relres,resvecG,niter]= gauss_s(A,b,tol,nmaxit) x0=zeros(n,1); normb=norm(b); resvecG=zeros(nmaxit,1); res=b-A*x0; relres=norm(res)/normb; DmE=tril(A); niter=0; while(relres>tol) & (niter<nmaxit) niter=niter+1; sol =DmE\res; sol=sol+x0; x0=sol; res=b-A*x0; relres=norm(res)/normb; resvecG(niter)=relres; end endfunction function[sol,relres,resvecR,niter]= richard(A,b,alpha,tol,nmaxit) x0=zeros(n,1); normb=norm(b); resvecR=zeros(nmaxit,1); res=b-A*x0; relres=norm(res)/normb; D= alpha; niter=0; while(relres>tol) &(niter<nmaxit) niter=niter+1; sol =x0 + D.*res; x0=sol; res=b-A*x0; relres=norm(res)/normb; resvecR(niter)=relres; end endfunction n=3 A=[2 -1 0;-1 2 -1;0 -1 2] b=[1; 2; 3] [sol,relres,resvecJ,niter]= myjacobi(A,b,0.01,50) [sol,relres,resvecG,niter]= gauss_s(A,b,0.01,50) [sol,relres,resvecR,niter]= richard(A,b,1 /2,0.01,50) figure; plot(1:niter,log10(resvecJ),'r'); plot(1:niter,log10(resvecG)); plot(1:niter,log10(resvecR,'g'));
364b739df22684e0686428555339019f609766a3
449d555969bfd7befe906877abab098c6e63a0e8
/1382/CH4/EX4.11/exe_4_11.sce
173ddcda504c110ba0c87a2dcc50ba5736f585c6
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
353
sce
exe_4_11.sce
// Example 4.11: drain to source resisitance clc, clear //Given DATA Vdd=10;//in volt knwl=1;//in mA/V^2 Vd=0.1;//drain voltage Vt=-1;//in Volt Id=1*((-Vt)*Vd- (1/2)*0.01);//drain current in milli ampere Rd=(Vdd-Vd)/Id;// resistance in killo ohms Rds= Vd/Id;//resistance in killo ohms disp(Rds,"drain to source resistance in killo ohms is")
b2577a549fd0e1ebf1a7035a54bca00a63b01ef8
449d555969bfd7befe906877abab098c6e63a0e8
/764/CH4/EX4.12.a/data4_12.sci
630a480e43627fa1930817f76dbb5409fe2b81c8
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
520
sci
data4_12.sci
//(Design against Static Load) Example 4.12 //Refer Fig.4.39 //Force acting on the bracket P (kN) P = 5 //Ultimate tensile strength of FG200 material Sut (N/mm2) Sut = 200 //Factor of safety fs fs = 3.5 //Angle made by the line of force with the vertical theta (radian) theta = (60 * (%pi/180)) //Distance between the point load and the horizontal axis h (mm) h = 150 //Distance between the point load and the rigid support r (mm) r = 300 //Ratio of depth to width of the cross-section ratio ratio = 2
9cb5755b19b194e5f6d2936060b23fa9340e1a5f
449d555969bfd7befe906877abab098c6e63a0e8
/1523/CH6/EX6.17/ex6_17.sce
bdaa7e26f32bb8b5d18cad9a09a4f779f7171796
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
638
sce
ex6_17.sce
// Three-Phase Circuits :example 6.17 :(pg 6.20) Po=200*10^3; f=50; VL=440; N=0.91; pf=0.86; phi=acosd(pf); Pi=(Po/N); IL=(Pi/(sqrt(3)*VL*pf)); Iph=(IL/sqrt(3)); AC=(Iph*pf); RC=(Iph*sind(phi)); printf("\nPo=200 kW \nf=50Hz \nVL= 440 V \nN=0.91 \npf=0.86"); //For a delta connected load (induction motor) printf("\nVph =VL =%.f V",VL); printf("\nN=(Po/Pi)");//efficiency printf("\nPi=%.f W",Pi);//Input power printf("\nPi=sqrt(3)*VL*IL*cos(phi) \nIL=%.1f A",IL); printf("\nAC = (Iph*cos(phi))=%.1f A",AC);//Active component of phase current printf("\nRC=(Iph*sin(phi)) =%.1f A",RC);//Reactive component of phase current
abdb93a527d671686712fdefbf6d6bb7857c8aba
449d555969bfd7befe906877abab098c6e63a0e8
/534/CH5/EX5.1/5_1_Thermocouple_junction.sce
f41c10e048fb72a86469c9563cfa309ac0af2004
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
917
sce
5_1_Thermocouple_junction.sce
clear; clc; printf('FUNDAMENTALS OF HEAT AND MASS TRANSFER \n Incropera / Dewitt / Bergman / Lavine \n EXAMPLE 5.1 Page 261 \n'); //Example 5.1 // Junction Diameter and Time Calculation to attain certain temp //Operating Conditions h = 400; //[W/m^2.K] Heat Convection coefficient k = 20; //[W/m.K] Thermal Conductivity of Blade c = 400; //[J/kg.K] Specific Heat rho = 8500; //[kg/m^3] Density Ti = 25+273; //[K] Temp of Air Tsurr = 200+273; //[K] Temp of Gas Stream TimeConstt = 1; //[sec] //From Eqn 5.7 D = 6*h*TimeConstt/(rho*c); Lc = D/6; Bi = h*Lc/k; //From eqn 5.5 for time to reach T = 199+273; //[K] Required temperature t = rho*D*c*2.30*log10((Ti-Tsurr)/(T-Tsurr))/(h*6); printf("\n\n Junction Diameter needed for a time constant of 1 s = %.2e m \n\n Time Required to reach 199degC in a gas stream = %.1f sec ", D, t); //END
f9be056a424245b1e13018a4d2c96ecd699d9986
449d555969bfd7befe906877abab098c6e63a0e8
/1379/CH11/EX11.1.7/example11_7.sce
356377e6ed6e86593a79f02681478aac5e5ed152
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
396
sce
example11_7.sce
//exapple 11.7 clc; funcprot(0); // Initialization of Variable e=0.4;//incipent to fluidisation //calculation //part 1 disp("for Re<500"); disp("the ratio of terminal velocity & minimmum fluidising velocity is"); a=3.1*1.75/e^3; disp(sqrt(a)); //part 2 disp("for Re>500"); disp("the ratio of terminal velocity & minimmum fluidising velocity is"); a=150*(1-e)/18/e^3; disp(a);
84b8d775b28e9527e0aef2b222842d25175bff3b
18bf68cdf766092ccdcba8d231e8140063833a5a
/NonLinearDistortionCT.sce
81b7ef2a7b0be09611bcf46b8889fdce3462b23e
[]
no_license
goodengineer/Scilab-Exercises
b51cc9a4c938f0289a32875d2d21eb9061d0e68e
3c268211fe48e7e4d0002e44757ea8b50cda10f9
refs/heads/master
2022-12-24T23:30:12.875423
2020-10-05T06:27:20
2020-10-05T06:27:20
null
0
0
null
null
null
null
UTF-8
Scilab
false
false
398
sce
NonLinearDistortionCT.sce
// CT Non - linear distortion // Exercise 10 clear; clf; dt = 1/10000; t = 0 : dt : 1; x = sin(2*%pi*1*t); subplot(311); plot(t,x,'r'); title("X(t) : any sine function","fontsize",3) a = 2; b = 3; y = a.*x + b.*x.*x; subplot(312); plot(t,y,'m'); title("y(t) : a*x + b*x*x","fontsize",3) a = 4; b = 5; y = a.*x + b.*x.*x; subplot(313); plot(t,y,'g'); title("y(t) : a*x + b*x*x","fontsize",3)
a5d6555f1418d2a11f212cf93a6f4a531a902f29
449d555969bfd7befe906877abab098c6e63a0e8
/3878/CH22/EX22.3/Ex22_3.sce
cfde6d548569392c649c2a14fb82040917b33758
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
653
sce
Ex22_3.sce
clear // Variable declaration T_d=26// The dry bulb temperature of air in °C T_w=20// The wet bulb temperature of water in °C T_win=29// The temperature of water at inlet in °C T_wout=24// The temperature of water at outlet in °C C_pw=4.187// The specific heat capacity of water in kJ/kg.K // Calculation Q=C_pw*(T_win-T_wout)// Heat from water in kJ/kg h_ain=57.1// Enthalpy of entering air in kJ/kg h_aout=78.1// Enthalpy of leaving air in kJ/kg printf("\n \nHeat from water=%2.0f kJ/kg \nEnthalpy of entering air=57.1 kJ/kg \nEnthalpy of leaving air=78.1 kJ/kg",Q) printf("\n From the chart, the air leaves at approximately 25.7°C dry bulb")
4416e14f572a862f2a3435b69335d8edbee22d54
449d555969bfd7befe906877abab098c6e63a0e8
/1787/CH2/EX2.12/Exa2_12.sce
eb8a8dd339eb4f611d918edbf05ba5c159db9689
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
591
sce
Exa2_12.sce
//Exa 2.12 clc; clear; close; //given data e=1.6*10^-19;//in coulamb MUh=0.18;//in m^2/V-s MUe=0.38;//in m^2/V-s V=10;//in Volts l=25;//in mm w=4;//in mm t=1.5;//in mm E=V/(l*10^-3);//in //part (i) ve=MUe*E;//in m/s vh=MUh*E;//in m/s disp(ve,"Drift velocity for electrons in m/s : "); disp(vh,"Drift velocity for holes in m/s : "); ni=2.5*10^19;//in m^-3 //part (ii) SIGMAi=ni*e*(MUe+MUh);//in (ohm-m)^-1 disp(SIGMAi,"Conductivity of Ge(intrinsic) in (ohm-m)^-1 "); //part (iii) I=SIGMAi*E*w*10^-3*t*10^-3;//in Ampere disp(I*10^3,"Total current in mili ampere : ");
76058cc9a76dbb547f17acddaae14b2090d354cd
717ddeb7e700373742c617a95e25a2376565112c
/854/CH11/EX11.10/Example11_10.sce
3fb927ad64ff02406c7afe6ea3519c7bd2312fb0
[]
no_license
appucrossroads/Scilab-TBC-Uploads
b7ce9a8665d6253926fa8cc0989cda3c0db8e63d
1d1c6f68fe7afb15ea12fd38492ec171491f8ce7
refs/heads/master
2021-01-22T04:15:15.512674
2017-09-19T11:51:56
2017-09-19T11:51:56
92,444,732
0
0
null
2017-05-25T21:09:20
2017-05-25T21:09:19
null
UTF-8
Scilab
false
false
688
sce
Example11_10.sce
//clear// //Caption:Program to find the input impedance for a line terminated with impedance(with inductive reactance) //Example11.10 //page369 clc; close; ZL = 25+%i*50; //load impdance in ohms Zo = 50; //characteristic impedance in ohms T = reflection_coeff(ZL,Zo);//reflection coefficient in rectandular form [R,teta] = polar(T);//reflection coefficient in polar form L = 60e-02;//length 60 cm Lambda = 2; //wavelength = 2m EL = electrical_length(L,Lambda); EL = EL/57.3; //electrical length in radians Zin =(1+T*exp(-%i*2*EL))/(1-T*exp(-%i*2*EL)); disp(Zin,'Input impedance in ohms Zin =') //Result //Input impedance in ohms Zin = // 0.2756473 - 0.4055013i
ba7d5d333a15c45121c3c69977f55a2ca65b87cf
8217f7986187902617ad1bf89cb789618a90dd0a
/browsable_source/2.4.1/Unix-Windows/scilab-2.4.1/macros/scicos_blocks/ESELECT_f.sci
aa4785c9b26cbb079af91238730c66b0138fe8aa
[ "LicenseRef-scancode-public-domain", "LicenseRef-scancode-warranty-disclaimer" ]
permissive
clg55/Scilab-Workbench
4ebc01d2daea5026ad07fbfc53e16d4b29179502
9f8fd29c7f2a98100fa9aed8b58f6768d24a1875
refs/heads/master
2023-05-31T04:06:22.931111
2022-09-13T14:41:51
2022-09-13T14:41:51
258,270,193
0
1
null
null
null
null
UTF-8
Scilab
false
false
1,109
sci
ESELECT_f.sci
function [x,y,typ]=ESELECT_f(job,arg1,arg2) // Copyright INRIA x=[];y=[];typ=[] select job case 'plot' then standard_draw(arg1) case 'getinputs' then [x,y,typ]=standard_inputs(arg1) case 'getoutputs' then [x,y,typ]=standard_outputs(arg1) case 'getorigin' then [x,y]=standard_origin(arg1) case 'set' then x=arg1; graphics=arg1(2);label=graphics(4) model=arg1(3); while %t do [ok,out,label]=getvalue('Set ESELECT block parameters',.. 'number of output event ports',list('vec',1),label) if ~ok then break,end if out<2 then message('Block must have at least two output ports') else [model,graphics,ok]=check_io(model,graphics,1,[],[1],[ones(out,1)]) if ok then graphics(4)=label;model(5)=ones(out,1);model(9)=out model(1)(2)=-1 x(2)=graphics;x(3)=model break end end end case 'define' then model=list(list('eselect',-1),1,[],1,[1;1],[],[],[],[2],'l',[-1 -1],[%f %f],' ',list()) gr_i=['txt=[''event select''];'; 'xstringb(orig(1),orig(2),txt,sz(1),sz(2),''fill'');'] label=string(2) x=standard_define([3 2],model,label,gr_i) end
b5529043b3e37971bcc3685f9a3a97870511723b
e86f908be00c4a3a017e81d12588d76562c56b75
/macros/kaiser.sci
2c33b3f75c9bd9ba033686f5db44ffe5fd48b412
[]
no_license
ShashikiranYadalam/FOSSEE_SP_task
8869a14f664329625b76e15e771058b90b69b1e1
601ca7b7c91587a430c69c9ceb1f87b196c8e566
refs/heads/master
2020-03-20T06:38:26.598686
2019-03-01T12:31:10
2019-03-01T12:31:10
137,255,176
0
0
null
2018-06-14T05:16:17
2018-06-13T18:27:32
HTML
UTF-8
Scilab
false
false
885
sci
kaiser.sci
function w = kaiser (m, beta) //This function returns the filter coefficients of a Kaiser window. //Calling Sequence //w = kaiser (m) //w = kaiser (m, beta) //Parameters //m: positive integer value //beta: real scalar value //w: output variable, vector of real numbers //Description //This is an Octave function. //This function returns the filter coefficients of a Kaiser window of length m supplied as input, to the output vector w. //The second parameter gives the stop band attenuation of the Fourier transform of the window on derivation. //Examples //kaiser(6,0.2) //ans = // 0.9900745 // 0.9964211 // 0.9996020 // 0.9996020 // 0.9964211 // 0.9900745 funcprot(0); rhs = argn(2) if(rhs<1 | rhs>2) error("Wrong number of input arguments.") end if(rhs==1) w = callOctave("kaiser", m) elseif(rhs==2) w = callOctave("kaiser", m, beta) end endfunction
a8355369304fc01027e8fc19a25d8fd65761f147
449d555969bfd7befe906877abab098c6e63a0e8
/3433/CH8/EX8.3/Ex8_3.sce
e2f102cc91b3d7a16f28cdea3d304e55f953502d
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
945
sce
Ex8_3.sce
clear; clc; funcprot(0); //given data Z = 12;//number of vanes delW = 230;//in kW T01 = 1050;//stagnation temperature in K mdot = 1;//flow rate in kg/s eff_ts = 0.81;//total-to-static efficiency Cp = 1.1502;//in kJ/(kg.K) gamma = 1.333; R = 287;//gas constant //Calculations S = delW/(Cp*T01); alpha2 = (180/%pi)*acos(sqrt(1/Z)); beta2 = 2*(90-alpha2); p3_p01 = (1-(S/eff_ts))^(gamma/(1-gamma)); M02 = sqrt((S/(gamma-1))*((2*cos(beta2*%pi/180))/(1+cos(beta2*%pi/180)))); M2 = sqrt((M02^2)/(1-0.5*(gamma-1)*(M02^2))); U2 = sqrt((gamma*R*T01)*(1/cos(beta2*%pi/180))*(S/(gamma-1))); //Results printf('(i) The absolut and relative flow angles:\n alpha2 = %.2f deg\n beta2 = %.2f deg',alpha2,beta2); printf('\n (ii) The overall pressure ratio = %.3f',p3_p01); printf('\n (iii) The rotor rip speed = %.1f m/s\n The inlet absolute Mach number = %.3f',U2,M2); //there are small errors in the answers given in textbook
d539bdcbdb039ae0119719a81b81d1b54d9ded5d
449d555969bfd7befe906877abab098c6e63a0e8
/443/DEPENDENCIES/1_3_data.sci
452e1dee1d117d8368a1b842a70d342aea4a6727
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
104
sci
1_3_data.sci
//brake power of engine(in kw) bp=42.5; //mechanical efficiency nm=0.85; //load (in percent) l=0.6;
b100bbee549eb87295b4c92edbb8a3c751866495
f84f70d084dfe70f4981267c54aae83638a4d71e
/ACSO-master/ACSO-master/Parcial 2/Punto 4/p4.tst
bb5ae58b8c50242c75e6d0f33153fe4b401f62cb
[]
no_license
nicolaspineros/ACSOM
b85b4b770df5ff204c2c117155102c69fecc2dc6
3f3a05bd60589ba5f6fa5edba9d999af9dd93517
refs/heads/master
2023-03-22T11:34:35.897155
2021-03-03T15:35:00
2021-03-03T15:35:00
344,175,037
0
0
null
null
null
null
UTF-8
Scilab
false
false
276
tst
p4.tst
load p4.hdl; set A 0, set B 0, set C 0, eval; set A 0, set B 0, set C 1, eval; set A 0, set B 1, set C 0, eval; set A 0, set B 1, set C 1, eval; set A 1, set B 0, set C 0, eval; set A 1, set B 0, set C 1, eval; set A 1, set B 1, set C 0, eval; set A 1, set B 1, set C 1, eval;
6ea66b7e749ca80acfd2467091a1ccc291fdd832
449d555969bfd7befe906877abab098c6e63a0e8
/608/CH6/EX6.09/6_09.sce
1bd7c3bfa46f040992cd6ad092ade89df58012d2
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
498
sce
6_09.sce
//Problem 6.09: A parallel plate capacitor has nineteen interleaved plates each 75 mm by 75 mm separated by mica sheets 0.2 mm thick. Assuming the relative permittivity of the mica is 5, calculate the capacitance of the capacitor. //initializing the variables: n = 19; // no. of plates L = 75E-3; // in m B = 75E-3; // in m d = 0.2E-3; // in m e0 = 8.85E-12; // in F/m er = 5; //calculation: A = L*B C = e0*er*A*(n-1)/d printf("\n\nResult\n\n") printf("\n Capacitance %.2E F\n",C)
52845bd801e93409aca8450eca218f2109fa68be
449d555969bfd7befe906877abab098c6e63a0e8
/1938/CH7/EX7.29/7_29.sce
7afb934b1de0f82e445c7f56856f623f7babd040
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
841
sce
7_29.sce
clc,clear printf('Example 7.29\n\n') V_L=6.6*10^3, V_ph=V_L/sqrt(3) I_L=50,I_aph=I_L Z_s=complex(1.5,8) //synchronous impedance theta=(%pi/180)*phasemag(Z_s) //phasemag returns angle in degrees,not radians E_Rph=I_aph*abs(Z_s) //part(i) phi=acos(0.8) P_in= sqrt(3)*V_L*I_L*cos(phi) //for both lag and lead, supplied power will be the same printf('(i)Power supplied to the motor is %.3f kW\n',P_in*10^-3) //part(ii) E_bph_lag = sqrt( E_Rph^2 + V_ph^2 - 2*E_Rph*V_ph*cos(theta-phi) ) //for lagging power factor //Note that E_bph_lag > V_ph printf('(ii)Induced EMF for 0.8 power factor lag is %.3f V\n',E_bph_lag) E_bph_lead = sqrt( E_Rph^2 + V_ph^2 - 2*E_Rph*V_ph*cos(theta+phi) ) //for leading power factor //Note that E_bph_lead < V_ph printf(' Induced EMF for 0.8 power factor lead is %.3f V',E_bph_lead)
2c5fd56a7093e936ed641f0b3fffc291526e6697
449d555969bfd7befe906877abab098c6e63a0e8
/3630/CH10/EX10.2/Ex10_2.sce
46a32b6abc374dbb3f274c348524c5dc4915d784
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
296
sce
Ex10_2.sce
clc; Vcc=0.002; //Volt Re=5000; //Ohm Icsat=Vcc/Re; //Ampere Vceoff=Vcc; //Volt disp(' Amperes',Icsat,"Icsat="); disp('Volt',Vceoff,"Vceoff="); T1=0:2:10 //Here on X-axis T1=Vce=10V T2=2:-0.4:0; //Here on the Y-Axis T2=Ic=2miliAmpere plot(T1,T2) xlabel('Vce(V)') ylabel('Ic(mA)')
75133deb2e80674a5f27e0925b5dd78af4d79610
449d555969bfd7befe906877abab098c6e63a0e8
/443/CH3/EX3.10/3_10.sce
3c631b361988abb81699538a606f35706178b033
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
455
sce
3_10.sce
pathname=get_absolute_file_path('3_10.sce') filename=pathname+filesep()+'3_10_data.sci' exec(filename) //Otto cycle efficiency notto=(1-(1/r^(y-1)))*100 e=(p3/p4n)^(1/y) //Efficiency of Atkinson cycle natk=(1-(y*(e-r))/(e^y-r^y))*100 //Ratio of the efficiencies rn=natk/notto printf("\n\nRESULS\n\n") printf("\nOtto cycle efficiency:%f\n",notto) printf("\nEfficiency of Atkinson cycle:%f\n",natk) printf("\nRatio of the efficiencies:%f\n",rn)
598289973780edbea43dfad811a0fe70e6a7df49
449d555969bfd7befe906877abab098c6e63a0e8
/1367/CH2/EX2.7/2_7.sce
da3447ab229a3adbbbf9b9257789d7fbc1d8c49c
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
262
sce
2_7.sce
//Find Minimum Uncertainity in Position //Ex:2.7 clc; clear; close; h=6.62*10^-34;//planck's constant in Js p=10^-27;//uncertainity in momentum in kg m/s x=h/(2*3.14*p);//uncertainity in position in m disp(x,"Minimum Uncertainity in Position (in m) = ");
da54461d41b3e498bc869e1628209933bceec71f
449d555969bfd7befe906877abab098c6e63a0e8
/331/CH6/EX6.2/Example_6_2.sce
7bf68a7bf5fda441aa18acc1e2d4103c97f88236
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
1,072
sce
Example_6_2.sce
//Caption: Cumulative distribution of the binomial distribution //F(X,n,p) //Example6.2 //Page 176 clear; clc; //(a). Probability of 0 head X1 = 0;// 0 head n = 10; //number of trials Pr = 0.5; //Probability of success in each binomial trial Ompr = 1-Pr; //Probability of failure in each binomial trial [P1,Q1]=cdfbin("PQ",X1,n,Pr,Ompr); disp(P1,'Probability of zero head P(X=0,10,0.5)=') //(b). Probability of 3 head X2 =3;// 3 head P2 = (factorial(n)/(factorial(X2)*factorial(n-X2)))*(Pr^X2)*(Ompr^(n-X2)); disp(P2,'Probability of three heads P(X=3,10,0.5)=') //(c). at most 2 heads X3 = 2; [P3,Q3]=cdfbin("PQ",X3,n,Pr,Ompr); disp(P3,'Probability of atmost 2 heads P(X<=2,10,0.5)=') //(d). at least 3 heads disp(1-P3,'Probability of atleat 3 heads P(X>=3,10,0.5)=') //Result //Probability of zero head P(X=0,10,0.5)= // 0.0009766 //Probability of three heads P(X=3,10,0.5)= // 0.1171875 //Probability of atmost 2 heads P(X<=2,10,0.5)= // 0.0546875 //Probability of atleat 3 heads P(X>=3,10,0.5)= // 0.9453125
557106ffbfa53bcd0a736c15c51efab3e00fa8c3
449d555969bfd7befe906877abab098c6e63a0e8
/2507/CH12/EX12.10/Ex12_10.sce
af17fe0d3c859f7cc40ecd2b3a7ed6b734447e36
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
480
sce
Ex12_10.sce
clc clear printf("Example 12.10 | Page number 435 \n\n"); //Find enthalpy of reaction //Given Data deltaH_gasgas = -2651.4e3 //kJ/kmol butane hfg_butane = 370 //kJ/kg //enthalpies of vaporisation of butance hfg_water = 2442 //kJ/kg //enthalpies of vaporisation of water M_butane = 58 //g/mol M_water = 18 //g/mol //Solution deltaH_liqliq = deltaH_gasgas + M_butane*hfg_butane - 5*M_water*hfg_water printf("Enthalpy of reaction = %.1f kJ/kg",deltaH_liqliq/M_butane)
88070fc9945d5979ddc45b9bad0ef386b2a2f4d7
449d555969bfd7befe906877abab098c6e63a0e8
/2384/CH4/EX4.24/ex4_24.sce
0eeace2addc0accf4bb57a6e5c8935bd5311af1f
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
353
sce
ex4_24.sce
// Exa 4.24 clc; clear; close; format('v',8) // Given data Z1= 10+15*%i;// in ohm Z2= 6-8*%i;// in ohm R1= 10;// in ohm R2= 6;// in ohm I_T= 15;// in A I1= I_T*Z2/(Z1+Z2);// in A I2= I_T*Z1/(Z1+Z2);// in A P1= (abs(I1))^2*R1;// in W P2= (abs(I2))^2*R2;// in W disp(P1,"The value of P1 in W is : ") disp(P2,"The value of P2 in W is : ")
fa2b761904dec042bc452455a9f117de16658466
449d555969bfd7befe906877abab098c6e63a0e8
/3050/CH1/EX1.1/Ex1_1.sce
eeab83b14fd1fbec31d3c7a76bd024ec5d77612b
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
237
sce
Ex1_1.sce
//calculating hardness //Example 1.1 clc clear //100gm of CaCO3 = 136gm of CaSO4 m=204//mass of the substance wt=136//molecular mass Eq=(m*100)/wt//Equivalents of CaCO3 printf('Thus Equivalents of CaCO3 = %3.2f mg/L or ppm',Eq)
0c632f7705205c3bdc62fbcab809ec8904b058af
449d555969bfd7befe906877abab098c6e63a0e8
/620/CH13/EX13.9/example13_9.sce
7616d0465490eea92b80ada2d06d4f6a3a6637cb
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
404
sce
example13_9.sce
r1=3.3*10^(3); r2=1.2*10^(3); r3=310; p1=1; p2=0.1; disp("Part a"); rx=r2*r3/r1; disp("The unknown resistance (in Ω) is"); disp(rx); e=2*p1+p2; disp("the maximum possible error (in %) is"); disp(e); disp("Part b"); v=9; i=v/(r2+rx); disp("the current (in mA) through Rx is"); disp(i*1000); disp("Part c"); i1=v/(r1+r3); p=i1^2*r3; disp("Power dissipated (in mW) in R is"); disp(p*1000);
d7dd59cf38d25d039cf1392caf7dc35d99926dd6
1485852dd59aafc286600126cf832a32e10f117f
/tests/detailEnhance/test_default_values_1.sce~
fce6448b70ffcf2eb083476777f281852968dd24
[]
no_license
rg77/Scilab-Image-Processing-And-Computer-Vision-Toolbox
dec9fbbce32cfd1eab3c45ccb29c89aaa1384758
8adb116da3a9c29a32e5e0727105aff571e5b374
refs/heads/master
2020-12-02T16:14:45.282650
2017-07-07T10:12:04
2017-07-07T10:12:04
96,524,257
0
0
null
2017-07-07T09:43:50
2017-07-07T09:43:50
null
UTF-8
Scilab
false
false
133
test_default_values_1.sce~
src = imread("../images/color2.jpeg"); output = detailEnhance(src);//using default values for all optional parameter imshow(output);
92d852a434ab1eaa9a7bcc65af967870b946b386
449d555969bfd7befe906877abab098c6e63a0e8
/1529/CH10/EX10.15/10_15.sce
90cc6e486b5a6a569e0d680ac6d2a5360e3fe858
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
234
sce
10_15.sce
//Chapter 10, Problem 15 clc; d=14; //amplifier gain P1=8e-3; //input power P2=10^(14/10)*P1; //calculating output power using logarithm printf("Output power = %f mW",P2*1000);
64b222c74e9b407b292056affa054f2d72856848
ded79447177b1df4db9bd1ad7582cd9e2ccc85b3
/Display_n_odd_numbers.sce
ec72d920460dd2bd133f6705b8085a18ed453941
[]
no_license
Anugya-Gogoi/Scilab-programs
7ab352bde16c0d7c9b598af62113f12ab83fc6c6
40bd41b540dd5b6948e4efa4a22fc1d9f7e725f0
refs/heads/main
2023-02-27T09:43:40.263267
2021-02-10T05:19:10
2021-02-10T05:19:10
320,753,016
1
0
null
null
null
null
UTF-8
Scilab
false
false
57
sce
Display_n_odd_numbers.sce
x=input("Enter limit") for i=1:2:10 disp(i); end
951e2386441cf43b72353c3a538cf96ac36a350b
449d555969bfd7befe906877abab098c6e63a0e8
/3845/CH8/EX8.1/Ex8_1.sce
f8a8fe679fd3aad50b03c7bd23105e4d19889069
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
474
sce
Ex8_1.sce
//Example 8.1 m=110;//Mass of football player (kg) v=8;//Speed (m/s) p_player=m*v;//Momentum (kg.m/s) printf('a.Momentum of the player = %0.1f kg.m/s',p_player) m_ball=0.410;//Mass of the ball (kg) v_ball=25;//Velocity of ball (m/s) p_ball=m_ball*v_ball;//Momentum of ball (kg.m/s) printf('\nb.Ratio of momentum of the player to that of the ball = %0.1f',p_player/p_ball) //Openstax - College Physics //Download for free at http://cnx.org/content/col11406/latest
a087b318db2a9cd766a388970b19ddb4c08e6ec1
449d555969bfd7befe906877abab098c6e63a0e8
/3433/CH1/EX1.1/Ex1_1.sce
13cf24b469cf025ed89cba3b0b7362be0c50756e
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
521
sce
Ex1_1.sce
clear all; clc; funcprot(0); //given data gamma = 1.4; pi = 8;//pressure ratio T01 = 300;//inlet temperature in K T02 = 586.4;//outlet temperature in K //Calculations //Calculation of Overall Total to Total efficiency Tot_eff = ((pi^((gamma-1)/gamma))-1)/((T02/T01)-1); //Calculation of polytropic efficiency Poly_eff = ((gamma-1)/gamma)*((log(pi))/log(T02/T01)); //Results printf('The Overall total-to-total efficiency is %.2f.\n',Tot_eff); printf('The polytropic efficiency is %.4f.',Poly_eff);
ddc29e55bfa954344d7cfd930f4ef2be70690f0f
449d555969bfd7befe906877abab098c6e63a0e8
/2438/CH3/EX3.4/Ex3_4.sce
b243b116a60065ea28c76bf01c20b091ab7d4b46
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
414
sce
Ex3_4.sce
// Chapter 3 example 4 clc; clear; // Variable declaration Bo = 2; // magnetic field in tesla r = 5.29*10^-11 // radius in m m = 9.1*10^-31; // mass of electron in kg e = 1.6*10^-19 // charge of electron // calculations du = (e^2 * Bo * r^2)/(4*m) // change in magnetic moment // output mprintf('Change in magnetic moment = %3.1e J/T',du);
9b5240d6b2b095ee40c88e692fcb02d917c294ac
ac66d3377862c825111275d71485e42fdec9c1bd
/Resources/res/map/map2108.sce
82381f7abd3b31d7f50c93d989fb60c70cc5267f
[]
no_license
AIRIA/CreazyBomber
2338d2ad46218180f822682d680ece3a8e0b46c3
68668fb95a9865ef1306e5b0d24fd959531eb7ad
refs/heads/master
2021-01-10T19:58:49.272075
2014-07-15T09:55:00
2014-07-15T09:55:00
19,776,025
0
2
null
null
null
null
UTF-8
Scilab
false
false
1,929
sce
map2108.sce
<?xml version="1.0" encoding="UTF-8"?> <Project Name="map2108" Width="13" Height="15" CellSize="40" BackgroundSize="1" Background="13plus.png"> <Cell Name="木箱" X="8" Y="1" /> <Cell Name="出生点" X="1" Y="2" /> <Cell Name="树" X="2" Y="2" /> <Cell Name="古遗迹1(大型建筑)" X="3" Y="2" arg0="2" arg1="1" arg2="1,1" /> <Cell Name="樱桃树" X="6" Y="2" /> <Cell Name="古遗迹1(大型建筑)" X="7" Y="2" arg0="2" arg1="1" arg2="1,1" /> <Cell Name="木箱" X="11" Y="2" /> <Cell Name="木箱" X="1" Y="3" /> <Cell Name="木箱" X="2" Y="3" /> <Cell Name="樱桃树" X="8" Y="3" /> <Cell Name="木箱" X="9" Y="3" /> <Cell Name="树" X="10" Y="3" /> <Cell Name="树" X="9" Y="4" /> <Cell Name="食人花-右" X="10" Y="4" arg0="3" arg1="1.00" /> <Cell Name="地刺" X="1" Y="5" /> <Cell Name="木箱" X="3" Y="6" /> <Cell Name="古遗迹1(大型建筑)" X="4" Y="6" arg0="2" arg1="1" arg2="1,1" /> <Cell Name="丛林图腾1" X="10" Y="6" /> <Cell Name="cl-瘴气" X="4" Y="7" arg0="1.00" arg1="4.0" arg2="1.00" /> <Cell Name="木箱" X="10" Y="7" /> <Cell Name="豌豆-右" X="2" Y="8" arg0="3" arg1="3,0" arg2="3" /> <Cell Name="猿人-bt" X="6" Y="8" arg0="30" /> <Cell Name="木箱" X="9" Y="9" /> <Cell Name="古遗迹1(大型建筑)" X="3" Y="10" arg0="2" arg1="1" arg2="1,1" /> <Cell Name="古遗迹1(大型建筑)" X="9" Y="10" arg0="2" arg1="1" arg2="1,1" /> <Cell Name="通关点-1" X="4" Y="11" /> <Cell Name="豌豆-左" X="9" Y="11" arg0="2" arg1="3,0" arg2="3" /> <Cell Name="木箱" X="10" Y="11" /> <Cell Name="木箱" X="11" Y="11" /> <Cell Name="木箱" X="2" Y="12" /> <Cell Name="木箱" X="1" Y="13" /> <Cell Name="木箱" X="2" Y="13" /> <Cell Name="木箱" X="3" Y="13" /> <Cell Name="食人花-左" X="6" Y="13" arg0="2" arg1="1.00" /> <Cell Name="木箱" X="9" Y="13" /> <Cell Name="木箱" X="10" Y="13" /> </Project>
02af52c826015de284a006070107788a7a8e2432
449d555969bfd7befe906877abab098c6e63a0e8
/1523/CH4/EX4.89/ex4_89.sce
503513ec37b6e7a5ccf4445ba293841d24793acc
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
576
sce
ex4_89.sce
//AC Circuits : example 4.89 :(pg 4.72 & 4.73) R=20; L=200*10^-6; f=10^6; V=230; Rs=8000; XL=2*%pi*f*L; x=((2*%pi*f)^2); y=((R/L)^2); C=(1/((x+y)*L)); Q=((2*%pi*f*L)/R); Z=(L/(C*R)); ZT=(Rs+Z); IT=(V/ZT); printf("\nR=20 Ohm \nL=200uH \nf=10^6 \nV=230 V \nRs=8000 Ohm \nXL=2.pi.f.L =%.1f Ohm",XL); printf("\nf0=1/2.pi.sqrt(1/LC-R^2/L^2) \nC=%.e F",C); printf("\nQ0=2.pi.f.L/R =%.2f",Q);//quality factor printf("\nZ=L/CR \n=%.f Ohm",Z);//dynamic impedance printf("\nZt=%.f Ohm",ZT);//total equivalent Z at resonance printf("\nIt=%.e A",IT);//total ckt current
ef321997904df6cc488e8e9d81824a279c931d0e
449d555969bfd7befe906877abab098c6e63a0e8
/1826/CH8/EX8.1/ex8_1.sce
b8a0139d3669d31716cd958fcb1f023713e93d10
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
828
sce
ex8_1.sce
// Example 8.1, page no-208 clear clc d_cu=8.96*10^3//density of cu a_cu=63.55//Atomic weight of cu d_z=7100 a_z=65.38 d_al=2700 a_al=27 avg=6.023*10^26 h=6.626*10^-34 m=9.1*10^-31//kg e=1.6*10^-19//C //(i) n_cu=d_cu*avg/a_cu e_cu=(h^2/(8*m))*(3*n_cu/%pi)^(2/3) e_cu=e_cu/e printf("\n(i)For Cu\nThe electron concentration in Cu is %.4f*10^28 per m^3\nFermi energy at 0 k =%.4f eV ",n_cu*10^-28,e_cu) //(ii) n_z=d_z*avg*2/a_z e_z=(h^2/(8*m))*(3*n_z/%pi)^(2/3) e_z=e_z/e printf("\n(i)For Zn\nThe electron concentration in Zn is %.4f*10^28 per m^3\nFermi energy at 0 k =%.4f eV ",n_z*10^-28,e_z) //(i) n_al=d_al*avg*3/a_al e_al=(h^2/(8*m))*(3*n_al/%pi)^(2/3) e_al=e_al/e printf("\n(i)For Al\nThe electron concentration in Al is %.4f*10^28 per m^3\nFermi energy at 0 k =%.4f eV ",n_al*10^-28,e_al)
b667db03b3ccc47e79ea72d7d222844a5d08a6bd
449d555969bfd7befe906877abab098c6e63a0e8
/3760/CH9/EX9.8/ExB_8.sce
588b823f782a8e55258b915e8fe14ed1b63a5d1e
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
445
sce
ExB_8.sce
clc; vl=230; // line voltage f=50; // frequency of supply c=100*10^-6; // value of capacitance in each phase vp=230/sqrt(3); // phase voltage zp=1/(2*%pi*f*c); // phase impedance il=vp/zp; // line current // value of cos(theta) is taken from figB.15 w1=vl*il*cosd(120); w2=vl*il*cosd(60); printf('Reading of wattmeter 1 is %f W\n',w1); printf('Reading of wattmeter 2 is %f W\n',w2); p=w1+w2; printf('Total input power is %f W',p);
a7015e3263e2ce6eda1b4accefbd58c19554798f
449d555969bfd7befe906877abab098c6e63a0e8
/671/CH11/EX11.14/11_14.sce
5bb262604785d84520bc627a46a34063bf89371c
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
277
sce
11_14.sce
V=400 Vt=V/sqrt(3) Ia=50 pf=1 theta=0 Xs=1.3 Ef=Vt-%i*Xs*Ia delta=atan(imag(Ef)/real(Ef)) disp(delta*180/%pi) Pelec=sqrt(3)*V*pf*Ia Pmech=Pelec pf=0.8 theta=acos(0.8) Ia=Pelec/sqrt(3)/V/pf*exp(%i*theta) Ef2=Vt-%i*Xs*Ia If=0.9*norm(Ef2)/norm(Ef) disp(If)
5bb1b0398dbf80b5a8a8d157bcb36b5b8c1ba079
f6f1e0401e7847e8fe9f2229a1679ac4fd8fe357
/servers.yaml.tst
339a8c5baaa29056c8b6de421a99d150a065a37e
[]
no_license
Phoenix0610/puppet
2599a3a12bc27508f7b0483f75716e1044a92955
7baf87d981beaeb0f5d801f55e98f2f6f690a6fc
refs/heads/master
2020-03-11T13:19:27.143109
2018-04-18T07:48:37
2018-04-18T07:48:37
null
0
0
null
null
null
null
UTF-8
Scilab
false
false
512
tst
servers.yaml.tst
- name: Puppet1 box: trusty box_url: https://cloud-images.ubuntu.com/vagrant/trusty/current/trusty-server-cloudimg-amd64-vagrant-disk1.box env: tst role: web_svr ram: 1048 cpus: 1 forwarded_port: web: host: 8080 guest: 80 - name: Puppet2 box: trusty box_url: https://cloud-images.ubuntu.com/vagrant/trusty/current/trusty-server-cloudimg-amd64-vagrant-disk1.box env: tst role: app_svr ram: 1048 cpus: 1 forwarded_port: app: host: 9090 guest: 8080
d1761333926fabcd457a6b3b1a3938c6ff7a7bce
449d555969bfd7befe906877abab098c6e63a0e8
/608/CH7/EX7.04/7_04.sce
e96bc62bfd699bb3b9cd0356ca885f33cde74db3
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
408
sce
7_04.sce
//Problem 7.04: A flux density of 1.2 T is produced in a piece of cast steel by a magnetizing force of 1250 A/m. Find the relative permeability of the steel under these conditions. //initializing the variables: B = 1.2; // in Tesla H = 1250; // in A/m Pi = 3.14; u0 = 4*Pi*1E-7; //calculation: ur = B/(u0*H) printf("\n\nResult\n\n") printf("\n relative permeability of the steel = %.0f \n",ur)
5deb232bd1adb4b2abab74a9a7b6c7bfa2595396
f7e335e2af57c686554eb057f28ddd8d21aab1e4
/tests/fuzz/comment/0036.tst
74d81cbb855a07bbddd485d27184a24daea5699f
[ "MIT" ]
permissive
scravy/abnf
76515bd820b3b9d8e2dbc2cec2a2f845720a6022
cc4228f403b436cc4e34ff4d6a7def83922174be
refs/heads/master
2023-01-09T14:30:50.095268
2020-06-07T16:18:09
2020-06-07T16:18:09
null
0
0
null
null
null
null
UTF-8
Scilab
false
false
5
tst
0036.tst
;d]
2c07c124a60df3dcacdf9b765ff4a9aa353f49aa
449d555969bfd7befe906877abab098c6e63a0e8
/2459/CH11/EX11.7/Ex11_7.sce
6aa057349f596a6ea32a393ef4726f68eb76bac3
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
422
sce
Ex11_7.sce
//chapter11 //example11.7 //page206 Vbe=0.7 // V Vcc=18 // V Vee=8 // V Rc=1.2 // kilo ohm Re=1.5 //kilo ohm // by Kirchoff's voltage law to emitter side loop, we get Vee=Ie*Re+Vbe so Ie=(Vee-Vbe)/Re Ic=Ie // nearly // by Kirchoff's voltage law to collector side loop, we get Vcc=Ic*Rc=Vcb so Vcb=Vcc-Ic*Rc printf("collector curent = %.3f mA \n",Ic) printf("collector base voltage = %3f V \n",Vcb)
50bb20671870c89bfac949e80d6f0e9f5a2595a2
73b5d880fa06943c20ff0a9aee9d0c1d1eeebe10
/tinyos-1.x/regression/cnttorfm/cnt.tst
1a63dc3a5158e2a4d9053fa7b3dd83b4549105ab
[ "Intel" ]
permissive
x3ro/tinyos-legacy
101d19f9e639f5a9d59d3edd4ed04b1f53221e63
cdc0e7ba1cac505fcace33b974b2e0aca1ccc56a
refs/heads/master
2021-01-16T19:20:21.744228
2015-06-30T20:23:05
2015-06-30T20:23:05
38,358,728
0
1
null
null
null
null
UTF-8
Scilab
false
false
678
tst
cnt.tst
#!/usr/bin/perl do "../tools.pm"; $received1 = recv_base(1); ($dest1, $amid1, $group1, $len1, @remainder1) = unpack_message($received1); $received2 = recv_base(1); ($dest2, $amid2, $group2, $len2, @remainder2) = unpack_message($received2); # We test for a distance of 3 because packets are occasionally lost # (hopefully we won't hit a terribly lossy phase...) if (!($dest1 == $BROADCAST && $dest2 == $BROADCAST && (($remainder2[0] - $remainder1[0]) & 0xff) <= 3)) { print "destinations not broadcast and/or counts not consecutive\n"; print "1: "; print_message($received1); print "\n2: "; print_message($received2); print "\n"; exit 2; } exit 0;
0a1050268bf5c527ad49f530fcac3b0fd364376a
717ddeb7e700373742c617a95e25a2376565112c
/3460/CH4/EX4.6/Ex4_6.sce
83688562944a7b55a62d38b4bbd0bb34f4f1597b
[]
no_license
appucrossroads/Scilab-TBC-Uploads
b7ce9a8665d6253926fa8cc0989cda3c0db8e63d
1d1c6f68fe7afb15ea12fd38492ec171491f8ce7
refs/heads/master
2021-01-22T04:15:15.512674
2017-09-19T11:51:56
2017-09-19T11:51:56
92,444,732
0
0
null
2017-05-25T21:09:20
2017-05-25T21:09:19
null
UTF-8
Scilab
false
false
213
sce
Ex4_6.sce
clc; clear all; fi_min=30; //Hz fi_max=15*1e3; //Hz Delta=75*1e3; //Hz mf_max=(Delta/fi_min); mf_min=(Delta/fi_max); disp(mf_max,"maximun modulation index") disp(mf_min,"minimum modulation index")
0cebd2c68a46ebd43a889881336531430d6f155b
bbc11c0776778eadc6701c4eedfe19ae8dfa1584
/scilab/pivotacaoParcial.sce
85e0a08664653471a276eb2b6ba5f0c942a94cb1
[]
no_license
ceconelli/Metodos-Computacionais
842eeebf11cc74acc66fa08d7ca67f9c45f3b268
07f4326c4821facaf5989f89d5d959f8000e062c
refs/heads/master
2020-06-03T03:23:51.762483
2017-06-12T16:12:12
2017-06-12T16:12:12
94,114,311
0
0
null
null
null
null
UTF-8
Scilab
false
false
241
sce
pivotacaoParcial.sce
a=[1 -3 2;-2 8 -1;4 -6 5]; pivot=[0 0 0]; n=3; for i=1:n pvt=a(1,i); for j=1:n if a(j,i) >= pvt then pvt=a(j,i); pivot(i)=j; else end end aux=a(pivot(i),:); end
5d6a1d8e7d4f9891c199ef4063286752dd20805f
449d555969bfd7befe906877abab098c6e63a0e8
/1085/CH7/EX7.3/ex7_3.sce
27fe9758fb1e9cad0351a6cbdf8e61cf77fc7bbc
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
710
sce
ex7_3.sce
//Exam:7.3 clc; clear; close; t_1=736;//Temperature in °C t_2=782;//Temperature in °C T_1=t_1+273;//Temperature in K T_2=t_2+273;//Temperature in K D_1=2*10^(-13);//Coefficient of diffusion at T_1 (in m2/s) D_2=5*10^(-13);//Coefficient of diffusion at T_2 (in m2/s) k=1.38*10^(-23);//in J/K //log(d_1)=log(d_o)-E/(k*T_1) //log(d_2)=log(d_o)-E/(k*T_2) E=(log(D_1)-log(D_2))/((1/(k*T_1))-(1/(k*T_2)));// disp(E,'activation energy(in J)='); D_o=2*10^(-13)/exp(E/(k*T_1)); disp(D_o,'constant of the equation(in m2/s)=') t_4=500;//Temperature in °C T_4=t_4+273;//Temperature in °K D_4=D_o*exp(E/(k*T_4));//diffusion coefficient at 500°C disp(D_4,'diffusion coefficient at 500°C(in m2/s)=')
a6b5f19b935203a054898c95d2bd0d205bc0111a
449d555969bfd7befe906877abab098c6e63a0e8
/50/DEPENDENCIES/secant64.sce
b65a9f3d5c1438d6b086c43ce49d1032bb0adae2
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
469
sce
secant64.sce
function [x]=secant64(a,b,f,fp) N=100; // define max. no. iterations to be performed PE=10^-15 // define tolerance for convergence for n=1:1:N // initiating for loop x=(b*f(a)*fp(b)-a*f(b)*fp(a))/(f(a)*fp(b)-f(b)*fp(a)); if abs(f(x))<=PE then break; //checking for the required condition else a=b; b=x; end end disp(n," no. of iterations =") // endfunction
ae0934ffc5c8b79d8c3488a5ffa98b84595ce674
449d555969bfd7befe906877abab098c6e63a0e8
/1016/CH10/EX10.6/ex10_6.sce
43b1db0b167d58048144fe7c338777f5dc79d210
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
245
sce
ex10_6.sce
clc;clear; //Example in 10.6 //given data m1=1.00814;//mass of proton in a.m.u m2=1.00893;//mass of neutron in a.m.u m3=7.01822;//mass of lithium in a.m.u //calculations dm=(3*m1)+(4*m2)-m3; Q=dm*931; disp(Q,'Binding energy in MeV')
e19077f46fcb55f8cbb72f70b94e1588a79f9dc6
449d555969bfd7befe906877abab098c6e63a0e8
/2213/CH8/EX8.5/ex_8_5.sce
e3634a02cf144f363f6584d79faa892939d802fd
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
503
sce
ex_8_5.sce
//Example 8.5: Current drawn clc; clear; close; format('v',5) //given data : V=500;// in volts Vm=40;// in kmph Ft=1800;// in N Rm=0.4;// in ohm Lm=3200;// losses per motor in watt Mo=(Ft*Vm*1000)/3600; Cl=3200;// consatant losses in watt // formuls: Mi=Po+Cl+C_losses //C_losses=I^2*Rm //Mi=V*I //I1=(V+sqrt(V^2-(4*Rm*(Mo+Cl))))/(2*Rm);leaving as gives a very high value I1=(V-sqrt(V^2-4*Rm*(Mo+Cl)))/(2*Rm); disp(I1,"Current drawn by each motor,(A) ="); It=I1*2; disp(It,"Total current drawn,(A) = ")
2c06d64d4bf8b9b7da801e6aee75affcd670d38b
449d555969bfd7befe906877abab098c6e63a0e8
/2411/CH3/EX3.d.306/Ex3d_6.sce
a3e832a4f83229361c3527ef409dc7d7854f7e1f
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
405
sce
Ex3d_6.sce
// Scilab Code Ex3d.6: Page-207 (2008) clc; clear; n = 2; // Order of diffraction lambda = 5e-005; // Wavelength of light, cm theta = 30; // Angle of diffraction, degree N = sind(theta)/(n*lambda); // Number of lines per cm of grating, lines/cm printf("\nThe number of lines per cm of grating = %4d per cm", ceil(N)); // Result // The number of lines per cm of grating = 5000 per cm
931ae36c716f3482866141d981df9dcb5ef4e57c
8217f7986187902617ad1bf89cb789618a90dd0a
/browsable_source/2.3/Unix-Windows/scilab-2.3/macros/percent/%lsscp.sci
9f1ee1228055fe70d1972f1969936596ebc67c71
[ "LicenseRef-scancode-warranty-disclaimer", "LicenseRef-scancode-public-domain", "MIT" ]
permissive
clg55/Scilab-Workbench
4ebc01d2daea5026ad07fbfc53e16d4b29179502
9f8fd29c7f2a98100fa9aed8b58f6768d24a1875
refs/heads/master
2023-05-31T04:06:22.931111
2022-09-13T14:41:51
2022-09-13T14:41:51
258,270,193
0
1
null
null
null
null
UTF-8
Scilab
false
false
238
sci
%lsscp.sci
function [s]=%lsscp(s1,d2) //s=%lsscp(s1,d2) // u=[u1;u2] y=y1+d2*u1 // s=[s1,d2] [a1,b1,c1,d1,x1,dom1]=s1(2:7) [n1,m1]=size(b1);[p2,m2]=size(d2); s=tlist(['lss','A','B','C','D','X0','dt'],a1,[b1 0*ones(n1,m2)],c1,[d1 d2],x1,dom1)
9e2e62f48a335ce38408266a6dd3c43a79a1165d
b38cc305aa8a93920fa1c8b049e8fbab7cb5bb56
/fasores.sce
a8c9f01efccbe2aa91fc1cb8122dc5f44f14ddae
[]
no_license
JoaoPi314/LCE_2_algorythms
17ab58d0a9304786ac4374574d8acec881f11c56
b2a5a1bc73be37555da0f7c83cba85b9c5e89a35
refs/heads/master
2022-12-19T00:09:39.141230
2020-10-10T06:41:58
2020-10-10T06:41:58
298,599,199
0
1
null
2020-10-10T06:41:59
2020-09-25T14:40:06
Scilab
UTF-8
Scilab
false
false
207
sce
fasores.sce
i1 = 4.47*exp(%i*63.44*%pi); i2 = 3.16/sqrt(2)*exp(%i*(-116.57/180*%pi)); i3 = 2 - %i*2; Ieq = i1 + i2 + i3 plot([0 real(i1)], [0 imag(i1)], [0 real(i2)], [0 imag(i2)], [0 real(i3)], [0 imag(i3)]);
004ac1247002632db0019e599d62a2ae8715acb2
449d555969bfd7befe906877abab098c6e63a0e8
/1472/CH10/EX10.3/10_3.sce
ce633a9900ffa102db897ea363e6885dfa56aba7
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
227
sce
10_3.sce
clc //initialization of varaibles T=250 //F disp("From table 1,") p=29.825 //psia hg=1164 //B/lb vg=13.821 //cu ft/lb //calculations ug=hg-(p)*144*vg/778 //results printf("Internal energy of the gas = %.1f B/lb",ug)
be00540831d13d7e4097a61fa942ccafde4ff07f
750baafb72c1d930c9b57d18963fc323754d1e84
/projects/04/sort/Sort-small.tst
8b8a4a178063cb256fbf4511409fa36069573f8a
[]
no_license
johny1122/Nand2Tetris
e765108e6613ea9efa19b66b01139f4139f6ad77
eda016bbc06f0a7c651395c7f24d94e168cd0739
refs/heads/main
2023-05-08T01:38:04.471987
2021-05-24T20:31:13
2021-05-24T20:31:13
370,477,048
0
0
null
null
null
null
UTF-8
Scilab
false
false
626
tst
Sort-small.tst
load Sort.asm, output-file Sort-small.out, compare-to Sort-small.cmp, output-list RAM[0]%D1.6.1 RAM[1]%D1.6.1 RAM[2]%D1.6.1 RAM[3]%D1.6.1 RAM[4]%D1.6.1 RAM[5]%D1.6.1 RAM[6]%D1.6.1 RAM[7]%D1.6.1 RAM[8]%D1.6.1 RAM[9]%D1.6.1 RAM[10]%D1.6.1 RAM[11]%D1.6.1 RAM[12]%D1.6.1 RAM[13]%D1.6.1 RAM[14]%D1.6.1 RAM[15]%D1.6.1; set RAM[11] 0, set RAM[12] 1, set RAM[14] 11, set RAM[15] 2; repeat 150 { ticktock; } output; set PC 0, set RAM[11] 4, set RAM[12] 5, set RAM[14] 11, set RAM[15] 2; repeat 150 { ticktock; } output; set PC 0, set RAM[11] 8, set RAM[12] 9, set RAM[14] 11, set RAM[15] 2; repeat 150 { ticktock; } output;
ae9415eaedb20b5ed1cd71dc05ab60a5137ad81b
449d555969bfd7befe906877abab098c6e63a0e8
/1332/CH13/EX13.8/13_8.sce
502a1f6d751c010028028d6f83ddbb756646bc17
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
502
sce
13_8.sce
//Example 13.8 //Application //Page no. 433 clc;close;clear; deff('y=f(x)','y=2/x^2') a=1;b=2;a1=1;b1=0; N=4; h=(b-a)/(N+1); for j=1:N s(j)=f(a+j*h) end for i=1:N for j=1:N if abs(i-j)==1 then A(i,j)=-1 end if i==j then A(i,j)=2+s(i)*h^2 end end if i==1 then k(i,1)=s(i)+a1/h^2 elseif i==N k(i,1)=s(i)+b1/h^2 else k(i,1)=s(i) end end disp(A,'A = ') disp(k,'k = ')
f68682495ac71934c7158fc70c9acffad05eee1f
449d555969bfd7befe906877abab098c6e63a0e8
/257/CH8/EX8.21/example_8_21.sce
5d16fc8d4419869adf55f8ce2e5887ff09ca3a56
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
592
sce
example_8_21.sce
s=%s P=s^6+s^5+5*s^4+s^3+2*s^2-2*s-8 routh=routh_t(P) disp(routh) r=coeff(P) n=length(r) c=0; for i=1:n if (routh(i,1)<0) c=c+1; end end if(c>=1) printf("system has %d roots in RHS",c) else printf("no roots in RHS") end k=0 R=(sqrt(roots(routh(3,:)))) //real part of the roots// disp("s is") disp(R) for(i=1:3) if(real(R(i,1)) == 0) k=k+1 end end printf("%d is in the imaginary axis and ",k) //conjugate pairs// printf(" %d roots are in LHS",6-k-c) //out of 6 roots//
cc8d0a9c20e6e3071cdcefc8115a91861f4b7eff
dacb210e4fc5dbb894a8358ca5b425e801829c17
/Pred-Corrector for ODE/trueval.sci
8e837a53eedb7508e835609f6c0301b7e8f3df45
[]
no_license
amiedemmel/Diff-Eq-Projects
ba0fe0a45cee568b65b2b508bd55d193668f7a14
7edbd8a46aec2df62990c8fb11365498cb583335
refs/heads/master
2020-05-30T04:10:56.223423
2015-05-08T15:50:50
2015-05-08T15:50:50
35,286,857
0
0
null
null
null
null
UTF-8
Scilab
false
false
61
sci
trueval.sci
function [tr]=trueval(t) tr=exp(t)./(16-exp(t)); endfunction
c1821f8252e1deba2df77d0ff2ca4d8a5de1f87c
8217f7986187902617ad1bf89cb789618a90dd0a
/source/2.5/macros/percent/%s_f_r.sci
5ef6c1ee9e5cd5db091d23207df3d674a44652f3
[ "LicenseRef-scancode-public-domain", "LicenseRef-scancode-warranty-disclaimer" ]
permissive
clg55/Scilab-Workbench
4ebc01d2daea5026ad07fbfc53e16d4b29179502
9f8fd29c7f2a98100fa9aed8b58f6768d24a1875
refs/heads/master
2023-05-31T04:06:22.931111
2022-09-13T14:41:51
2022-09-13T14:41:51
258,270,193
0
1
null
null
null
null
UTF-8
Scilab
false
false
104
sci
%s_f_r.sci
function f=%s_f_r(m,f) // [m;f] //! // Copyright INRIA f=rlist([m;f('num')],[ones(m);f('den')],f('dt'))
86943d77b3d286400cab86bdf60a3d0d0cdb8ce8
1b969fbb81566edd3ef2887c98b61d98b380afd4
/Rez/bivariate-lcmsr-post_mi/bfas_nw_usi/~BivLCM-SR-bfas_nw_usi-PLin-VLin.tst
d96812f0f48d854db9eda9ae342e99fdf0067464
[]
no_license
psdlab/life-in-time-values-and-personality
35fbf5bbe4edd54b429a934caf289fbb0edfefee
7f6f8e9a6c24f29faa02ee9baffbe8ae556e227e
refs/heads/master
2020-03-24T22:08:27.964205
2019-03-04T17:03:26
2019-03-04T17:03:26
143,070,821
1
0
null
null
null
null
UTF-8
Scilab
false
false
11,974
tst
~BivLCM-SR-bfas_nw_usi-PLin-VLin.tst
THE OPTIMIZATION ALGORITHM HAS CHANGED TO THE EM ALGORITHM. ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 1 2 3 4 5 ________ ________ ________ ________ ________ 1 0.442359D+00 2 -0.590336D-02 0.361408D-02 3 0.993797D-02 0.112116D-02 0.260833D+00 4 0.606137D-03 0.180702D-03 -0.238234D-02 0.212896D-02 5 -0.347518D-03 0.872400D-05 -0.172549D-02 0.126092D-03 0.202767D-02 6 -0.916539D-03 -0.143206D-03 -0.781678D-03 -0.243862D-04 -0.201653D-03 7 0.221070D-03 0.447214D-04 -0.678149D-03 -0.602650D-04 -0.100980D-04 8 -0.217979D-02 0.265965D-04 0.513569D-03 -0.394571D-04 -0.101088D-04 9 0.342170D+00 -0.351891D-01 -0.220169D+00 0.801336D-02 0.410297D-01 10 0.138483D+00 -0.221257D-02 -0.267605D-02 0.119124D-01 0.122664D+00 11 -0.126540D+00 0.152456D-02 0.149862D+00 -0.141876D-01 0.448954D-02 12 -0.208403D+00 0.109101D-01 0.188166D+00 -0.275520D-03 -0.630645D-03 13 0.202839D-01 0.162161D-03 -0.233364D-01 -0.186973D-02 0.626609D-02 14 0.145388D-01 -0.364284D-02 0.246154D+00 0.321133D-02 -0.105432D-01 15 0.743966D+00 0.594199D-01 -0.996919D+00 0.109500D-01 -0.830496D-01 16 0.545753D-01 0.438091D-03 0.219961D-01 -0.151475D-02 -0.333650D-03 17 -0.531080D-02 0.357728D-03 0.345838D-02 0.338434D-03 -0.636913D-03 18 -0.110126D+01 0.382308D-01 0.130637D+00 0.302224D-01 0.178166D-01 19 0.742310D-01 0.153021D-02 -0.596216D-01 0.849589D-02 0.117099D-01 20 0.181260D+00 0.115067D-01 0.264190D+00 0.248695D-01 -0.661490D-01 21 -0.272520D-01 -0.410238D-02 0.917156D-01 -0.566552D-02 -0.952737D-02 22 0.303942D-02 0.263877D-03 0.130644D-02 0.127899D-03 -0.263719D-03 23 0.875897D-02 0.294652D-02 0.184171D-01 0.259753D-02 0.575626D-03 24 0.162917D-02 0.914043D-04 0.623699D-04 0.112311D-03 0.171186D-03 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 6 7 8 9 10 ________ ________ ________ ________ ________ 6 0.185600D-02 7 0.770928D-03 0.121212D-02 8 0.206504D-03 -0.177287D-03 0.250157D-02 9 0.243157D-01 -0.267116D-02 0.505519D-02 0.980675D+02 10 -0.229560D-02 -0.504064D-02 -0.494436D-02 0.114685D+01 0.260063D+02 11 0.146516D-01 0.167361D-01 -0.155768D-01 0.210723D+00 -0.398032D+00 12 -0.157695D-01 -0.122900D-01 0.789935D-01 0.154849D+01 -0.729808D+00 13 0.567909D-01 0.438128D-01 -0.264220D-03 -0.734143D+00 0.168728D+01 14 0.546850D-02 -0.258937D-02 0.124048D+00 -0.163493D+01 0.999389D+00 15 -0.335107D-01 -0.269721D-01 0.217760D-01 -0.111635D+02 -0.101790D+02 16 -0.139810D-02 -0.148996D-02 -0.173072D-02 0.616831D+00 -0.952486D-01 17 0.229713D-03 0.319745D-03 -0.448070D-04 -0.190314D+00 -0.884253D-01 18 -0.337441D-01 -0.460008D-01 -0.342391D-01 0.493073D+01 -0.747857D+00 19 -0.449698D-03 0.114234D-01 -0.651075D-02 0.166471D+01 0.904894D+00 20 -0.246815D-01 -0.166126D-01 -0.110489D+00 -0.537611D+01 0.702696D+01 21 -0.623385D-04 -0.121006D-01 0.552936D-02 -0.154655D+01 -0.106665D+01 22 -0.368253D-03 -0.199184D-03 0.162930D-03 -0.891389D-02 -0.100396D-01 23 0.184076D-03 0.308085D-03 0.746758D-04 0.107932D+00 0.426063D-01 24 0.397541D-04 -0.300563D-06 -0.262986D-03 0.696643D-02 -0.427273D-01 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 11 12 13 14 15 ________ ________ ________ ________ ________ 11 0.253257D+02 12 0.210878D+01 0.429767D+02 13 -0.202963D+01 -0.649243D+00 0.820334D+01 14 -0.285498D+01 0.143244D+01 0.903838D+00 0.206220D+02 15 0.347195D+01 0.529353D+01 -0.225485D+01 -0.380683D+01 0.517789D+03 16 -0.109700D+00 -0.224401D+00 -0.101739D+00 -0.238185D+00 0.592442D+01 17 -0.198439D-01 -0.237011D-01 0.204008D-01 0.292185D-01 -0.263317D+01 18 -0.570751D+01 0.294598D+01 -0.404948D+00 -0.293750D+01 0.261273D+01 19 0.104115D+01 0.174130D+00 0.559751D+00 -0.282286D+00 -0.537101D+01 20 0.693697D+01 -0.171979D+02 -0.326306D+01 -0.919076D+01 0.155928D+02 21 -0.660236D+00 -0.377265D+00 -0.592011D+00 0.227386D+00 0.596589D+01 22 -0.200915D-01 -0.118530D-02 -0.380576D-01 0.178276D-01 -0.175886D-02 23 0.217661D-01 0.185290D+00 -0.338401D-01 -0.383026D-01 0.160312D+00 24 -0.318182D-01 -0.102685D-01 0.823757D-02 -0.264125D-01 -0.113948D+00 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 16 17 18 19 20 ________ ________ ________ ________ ________ 16 0.816567D+00 17 -0.730784D-01 0.292693D-01 18 0.228589D+00 -0.693445D-01 0.196548D+03 19 -0.121732D+00 0.301016D-01 -0.980605D+00 0.447776D+01 20 -0.472610D-01 -0.854640D-01 0.148268D+02 -0.128673D+01 0.166598D+03 21 0.144794D+00 -0.216041D-01 0.426921D+01 -0.391004D+01 0.202707D+01 22 0.611862D-02 0.894017D-03 -0.980956D+00 -0.249488D-01 -0.874273D-01 23 0.283267D-02 -0.233185D-02 0.404955D+00 0.951085D-01 0.117904D+01 24 0.114925D-03 0.101270D-02 -0.961958D-01 0.991479D-03 -0.764019D+00 ESTIMATED COVARIANCE MATRIX FOR PARAMETER ESTIMATES 21 22 23 24 ________ ________ ________ ________ 21 0.453265D+01 22 -0.267754D-01 0.108488D-01 23 -0.280977D-01 -0.231974D-02 0.213032D+00 24 -0.564158D-02 0.130287D-02 -0.164240D-01 0.778042D-02 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 1 2 3 4 5 ________ ________ ________ ________ ________ 1 1.000 2 -0.148 1.000 3 0.029 0.037 1.000 4 0.020 0.065 -0.101 1.000 5 -0.012 0.003 -0.075 0.061 1.000 6 -0.032 -0.055 -0.036 -0.012 -0.104 7 0.010 0.021 -0.038 -0.038 -0.006 8 -0.066 0.009 0.020 -0.017 -0.004 9 0.052 -0.059 -0.044 0.018 0.092 10 0.041 -0.007 -0.001 0.051 0.534 11 -0.038 0.005 0.058 -0.061 0.020 12 -0.048 0.028 0.056 -0.001 -0.002 13 0.011 0.001 -0.016 -0.014 0.049 14 0.005 -0.013 0.106 0.015 -0.052 15 0.049 0.043 -0.086 0.010 -0.081 16 0.091 0.008 0.048 -0.036 -0.008 17 -0.047 0.035 0.040 0.043 -0.083 18 -0.118 0.045 0.018 0.047 0.028 19 0.053 0.012 -0.055 0.087 0.123 20 0.021 0.015 0.040 0.042 -0.114 21 -0.019 -0.032 0.084 -0.058 -0.099 22 0.044 0.042 0.025 0.027 -0.056 23 0.029 0.106 0.078 0.122 0.028 24 0.028 0.017 0.001 0.028 0.043 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 6 7 8 9 10 ________ ________ ________ ________ ________ 6 1.000 7 0.514 1.000 8 0.096 -0.102 1.000 9 0.057 -0.008 0.010 1.000 10 -0.010 -0.028 -0.019 0.023 1.000 11 0.068 0.096 -0.062 0.004 -0.016 12 -0.056 -0.054 0.241 0.024 -0.022 13 0.460 0.439 -0.002 -0.026 0.116 14 0.028 -0.016 0.546 -0.036 0.043 15 -0.034 -0.034 0.019 -0.050 -0.088 16 -0.036 -0.047 -0.038 0.069 -0.021 17 0.031 0.054 -0.005 -0.112 -0.101 18 -0.056 -0.094 -0.049 0.036 -0.010 19 -0.005 0.155 -0.062 0.079 0.084 20 -0.044 -0.037 -0.171 -0.042 0.107 21 -0.001 -0.163 0.052 -0.073 -0.098 22 -0.082 -0.055 0.031 -0.009 -0.019 23 0.009 0.019 0.003 0.024 0.018 24 0.010 0.000 -0.060 0.008 -0.095 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 11 12 13 14 15 ________ ________ ________ ________ ________ 11 1.000 12 0.064 1.000 13 -0.141 -0.035 1.000 14 -0.125 0.048 0.069 1.000 15 0.030 0.035 -0.035 -0.037 1.000 16 -0.024 -0.038 -0.039 -0.058 0.288 17 -0.023 -0.021 0.042 0.038 -0.676 18 -0.081 0.032 -0.010 -0.046 0.008 19 0.098 0.013 0.092 -0.029 -0.112 20 0.107 -0.203 -0.088 -0.157 0.053 21 -0.062 -0.027 -0.097 0.024 0.123 22 -0.038 -0.002 -0.128 0.038 -0.001 23 0.009 0.061 -0.026 -0.018 0.015 24 -0.072 -0.018 0.033 -0.066 -0.057 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 16 17 18 19 20 ________ ________ ________ ________ ________ 16 1.000 17 -0.473 1.000 18 0.018 -0.029 1.000 19 -0.064 0.083 -0.033 1.000 20 -0.004 -0.039 0.082 -0.047 1.000 21 0.075 -0.059 0.143 -0.868 0.074 22 0.065 0.050 -0.672 -0.113 -0.065 23 0.007 -0.030 0.063 0.097 0.198 24 0.001 0.067 -0.078 0.005 -0.671 ESTIMATED CORRELATION MATRIX FOR PARAMETER ESTIMATES 21 22 23 24 ________ ________ ________ ________ 21 1.000 22 -0.121 1.000 23 -0.029 -0.048 1.000 24 -0.030 0.142 -0.403 1.000
8c27c3244dc5cee2e0b847fea21dce273b926e6f
449d555969bfd7befe906877abab098c6e63a0e8
/1691/CH2/EX2.31/exmp2_31.sce
bf78deb0e87b95698beaf13984410fbdf4bee931
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
476
sce
exmp2_31.sce
//Example 2.31 clc disp("The series and parallel resonating frequencies are,") disp("f_s = 1 / 2*pi*sqrt(C*L) while f_p = 1 / 2*pi*sqrt(L*C_eq)") disp("f_p/f_s = 1/2*pi*sqrt(L*C_eq) * 2*pi*sqrt(LC) = sqrt(c/C_eq) but C_eq = C*C_M/C+C_M") fp=sqrt(1+(0.04/2)) format(8) disp(fp,"f_p/f_s = sqrt(C/(C*C_M/C+C_M)) = sqrt(C*(C+C_M)/C*C_M) = sqrt(1+(C/C_M)) =") disp("f_p = 1.00995*f_s") inc=0.00995*100 disp(inc,"Therefore, %increase = (1.00995*f_s-f_s / f_s)*100 =")
996c90300432d73af8a9a2111cdd120b05fe9875
8217f7986187902617ad1bf89cb789618a90dd0a
/source/2.4.1/macros/m2sci/sci_stairs.sci
0c6fd51b0be95b94931ec8bb826bc6791bbafc82
[ "LicenseRef-scancode-public-domain", "LicenseRef-scancode-warranty-disclaimer" ]
permissive
clg55/Scilab-Workbench
4ebc01d2daea5026ad07fbfc53e16d4b29179502
9f8fd29c7f2a98100fa9aed8b58f6768d24a1875
refs/heads/master
2023-05-31T04:06:22.931111
2022-09-13T14:41:51
2022-09-13T14:41:51
258,270,193
0
1
null
null
null
null
UTF-8
Scilab
false
false
1,420
sci
sci_stairs.sci
function [stk,txt,top]=sci_stairs() // Copyright INRIA txt=[] if lhs==2 then if rhs==1 then stk=list('mtlb_stairs'+rhsargs(stk(top)(1)),'0','?','1','1') else r=list('mtlb_stairs'+rhsargs([stk(top-1)(1),stk(top)(1)]),'0','?','1','1') stk=list(r,r) top=top-1 end else if rhs==1 then x=gettempvar(1) if isname(stk(top)(1)) then y=stk(top)(1) else y=gettempvar(2) txt=y+' = '+stk(top)(1); end if stk(top)(4)=='1' then // column vector txt='plot2d2'+rhsargs([sci2exp('enn'),'0',y]) else // unknown shape txt='plot2d2'+rhsargs([sci2exp('enn'),'0',y+'(:)']) end elseif rhs==2 then if isname(stk(top)(1)) then y=stk(top)(1) else y=gettempvar(2) txt=[txt;y+' = '+stk(top)(1)]; end if isname(stk(top-1)(1)) then x=stk(top-1)(1) else x=gettempvar(2) txt=[txt;x+' = '+stk(top-1)(1)]; end if stk(top)(4)=='1' then //y is a column vector txt=[txt;y+' = '+y+''''] elseif stk(top)(3)<>'1' then //y has unknown shape txt=[txt;y+' = '+y(:)+''''] end if stk(top-1)(4)=='1' then //x is a column vector txt=[txt;x+' = '+x+''''] elseif stk(top-1)(3)<>'1' then //x has unknown shape txt=[txt;x+' = '+x(:)+''''] end txt=[txt; 'plot2d2'+rhsargs([sci2exp('gnn'),x,y])] top=top-1 end stk=list(' ','-2','0','0','0') end
a5e158cc3899b4555aa8bda3312cc56390a2ca61
449d555969bfd7befe906877abab098c6e63a0e8
/343/CH2/EX2.35/ex2_35.sce
6d0b4ecf3ae8b92de0a9d15945631932cc28cb1c
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
172
sce
ex2_35.sce
clc Z1=12.5+%i*21; //Assigning values to parameters V=50+%i*0; I1=V/Z1; I2=0.722-0.723*%i; Z=V/I2; Z2=Z-Z1; [r,t]=polar(Z2); disp("Ohms",r,"Impedance Z2");
82b46703b74e4279aa2777711a882758eeabd304
449d555969bfd7befe906877abab098c6e63a0e8
/1895/CH6/EX6.14/EXAMPLE6_14.SCE
37375ef023e8a9014074fc1aac32079859d57a07
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
1,020
sce
EXAMPLE6_14.SCE
//ANALOG AND DIGITAL COMMUNICATION //BY Dr.SANJAY SHARMA //CHAPTER 6 //NOISE clear all; clc; printf("EXAMPLE 6.14(PAGENO 308)"); //given A = 60//gain of noiseless amplifier V_n1 = 1*10^-3//output of the amplifier B = 20*10^3//initial bandwidth B1 = 5*10^3//change in bandwidth k = 1.38*10^-23//boltzman's constant T = 273 + 80//temperature in degree kelvin //calculaitons //since the bandwidth is reesuced to 1/4th of its value,therefore the noise voltage //will be V_n proportional to sqrt(B) //Hence, the noise voltage at 5KHz will become half its value at 20KHz bandwidth i.e, V_n = .5*10^-3//noise voltage in volts V_no = V_n1/A;//noise ouput voltage R = (V_no^2/(4*k * T * B ));//resistance at 80degree celcius //results printf("\n\ni.Meter reading in volts = %.10f V",V_n); printf("\n\nii.Resistance at 80 degree celcius = %.2f ohms",R); printf("\n\nNote: There is calculation mistake in textbook in the measurement of resistance they took constant in formula as 1 instead of 4");
00f0f9a031ad245abb5e9213d7c3deea2f83ca7c
04227b0d1bb094503d6c9ca0b21de26102c7572c
/ExtractionLbpCouleur.sce
700f33d365aece3af127d509dc950a4611bbf00f
[]
no_license
C-ELAzouzi/Reconnaissance-facial-matlab
be48b496aab193ec07f7aaa95cae2915ea5badfa
ee8073c77bd5fd3f9647ddd18b0115b4a9d27ae3
refs/heads/master
2023-06-05T16:25:23.844539
2021-06-16T12:46:06
2021-06-16T12:46:06
377,476,453
0
0
null
null
null
null
UTF-8
Scilab
false
false
556
sce
ExtractionLbpCouleur.sce
function attribut =ExtractionLbpCouleur(image,rayon,nb_voisin) //extraction des compsosnates RGB R=image(:,:,1); G=image(:,:,2); B=image(:,:,3); //extraction lbp attribut_R=lbp(R,rayon,nb_voisin,0,'h'); attribut_G=lbp(G,rayon,nb_voisin,0,'h'); attribut_B=lbp(B,rayon,nb_voisin,0,'h'); taille_lbp=size(attribut_R); taille=taille_lbp(2); attribut=zeros(1,taille*3); attribut(1,1:taille)=attribut_R; attribut(1,taille+1:taille*2)=attribut_G; attribut(1,taille*2+1:taille*3)=attribut_B; endfunction
e47b5d65a17048be76345189153508b3689cf8d3
449d555969bfd7befe906877abab098c6e63a0e8
/2939/CH7/EX7.3/Ex7_3.sce
9189389239b1d3c8fb0f10813d352b84e10ff825
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
622
sce
Ex7_3.sce
// Ex7_3 clc; // Given: a1=687; // neutron absorption cross section for U 235 in barns a2=0.66 // neutron absorption cross section for H2O in barns a3=0.0093; // neutron absorption cross section for D2O in barns a4=0.0045; // neutron absorption cross section for C in barns //Solution: F1=1.07*a1/a2;//design parameter for H2O part(a) printf("\n The design parameter for H2O is = %f",F1) F2=1.07*a1/a3;//design parameter for D2O part(b) printf("\n \n The design parameter for D2O is = %f",F2) F3=1.07*a1/a4;//design parameter for C part(c) printf("\n \n The design parameter for C is = %f",F3)
da8c84214b04ff9781cf5e7e63b3396d17bdff08
449d555969bfd7befe906877abab098c6e63a0e8
/275/CH1/EX1.1.75/Ch1_1_75.sce
81407610e8ab20572aac19418ed85dda7c2e1ded
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
296
sce
Ch1_1_75.sce
clc disp("Example 1.75") printf("\n") disp("Find the current through diode at 50c & 80c") T1=50 T2=80 D=3.2*10^-3 Pd1=400*10^-3 Vz=6.2 //at 50c Izm1=Pd1/Vz //at 80c Pd2=Pd1-((T2-T1)*D) Izm2=Pd2/Vz printf("the current through diode at 50c & 80c=\n%f ampere\n%f ampere\n",Izm1,Izm2)
6d45ce8608dabdb7dca0f3d85c003da4958294c8
33853a22c16bbef16269aad93c9d51d1c34cb1d6
/05/Decode.tst
033c63792685896c124cc5b8e66471708b75859d
[]
no_license
kazu914/nand2tetris
e05769726a72517d2a2025ebaedbb4b270313d95
84669515d8b70e810a4685b4004e0452bcad2cd5
refs/heads/master
2023-01-02T18:49:04.365128
2020-10-18T11:21:57
2020-10-18T11:21:57
302,681,169
0
0
null
null
null
null
UTF-8
Scilab
false
false
342
tst
Decode.tst
load Decode.hdl, output-file Decode.out, compare-to Decode.cmp, output-list instruction%B0.16.0 a c1 c2 c3 c4 c5 c6 d1 d2 d3 j1 j2 j3 ; set instruction %B1111111111111111, eval, output; set instruction %B0111111111111111, eval, output; set instruction %B1110101010101010, eval, output;
29d7a65145fb190eeb2c86cda4d80abe1de16d91
449d555969bfd7befe906877abab098c6e63a0e8
/1100/CH16/EX16.3/16_3.sce
17edb5604bd0b52b19b68581024b5659504167c4
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
578
sce
16_3.sce
clc //initialisation of variables k=1.4 ptbyp0=0.53 T0=800 //R cp=778 R=0.0425864 P0=150 //psia Pt=15 //psia w=1 //lb/sec cw=1.0043782 //Calculations Pt2=ptbyp0*Pt Tts=T0*(ptbyp0)^((k-1)/k) Vts=sqrt(2*32.174*cp*0.24*(T0-Tts)) printf ('Exit velocity case 1= %.2f fps',Vts) vts=3.12 //cu ft/lb at=w*vts/(cw*Vts) printf ('\n Throat Area = %.5f ft^2', at) T2s=T0*(Pt/P0)^((k-1)/k) eta=0.88 T2=T0-eta*(T0-T2s) V2=sqrt(2*32.174*cp*0.24*(T0-T2)) printf ('\n Exit velocity = %.2f fps', V2) v2=11.4 //cu ft/lb a2=w*v2/V2 printf('\n Exit area = %.5f ft^2',a2)
bd1172f9e0e449569fc06302b482cb2ab93033bf
449d555969bfd7befe906877abab098c6e63a0e8
/2792/CH5/EX5.12/Ex5_12.sce
223278ce1c0a4b6b6769458f6fa074c8e6190d2c
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
1,021
sce
Ex5_12.sce
clc apsilen = 11.9*8.85*10^-14 disp("apsilen = "+string(apsilen)+"F/cm") //initializing value of relative permitivity Na=10^19 disp("Na = "+string(Na)+"cm^-3") //initializing value of acceptor atoms Nd=10^16 disp("Nd = "+string(Nd)+"cm^-3") //initializing value of donor atoms e = 1.6*10^-19 disp("e= "+string(e)+"C")//initializing value of charge of electron Fcrit1 = 4*10^5 disp("Fcrit1= "+string(Fcrit1)+"V/cm")//initializing value of critical field of silicon Fcrit2 = 10^7 disp("Fcrit2= "+string(Fcrit2)+"V/cm")//initializing value of critical field of diamond VBD_Si = (apsilen*Fcrit1^2)/(2*e*Nd) disp("The breakdown field for silicon is ,VBD_Si = (apsilen*Fcrit1^2)/(2*e*Nd) = "+string(VBD_Si)+" V")//calculation VBD_C = (apsilen*Fcrit2^2)/(2*e*Nd) disp("The breakdown field for diomond is ,VBD_C = (apsilen*Fcrit2^2)/(2*e*Nd) = "+string(VBD_C)+" V")//calculation // Note : In the textbook answer of breakdown voltage of silicon is wrong due to which breakdown voltage of diomand also differ
7c43153e5fd2450ec326db72ed58b6af520eb420
449d555969bfd7befe906877abab098c6e63a0e8
/181/CH1/EX1.5/example1_5.sce
625127dcefcf71bd920ebf74400a404cf521f536
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
676
sce
example1_5.sce
// Energies of electrons in conduction band // Basic Electronics // By Debashis De // First Edition, 2010 // Dorling Kindersley Pvt. Ltd. India // Example 1-5 in page 21 clear; clc; close; // Data given h=1.05*10^-34; // Constant of calculation Js k=0.1,0.1,0,0; // Values of k-vector m_c=0.067*0.091*10^-30; // Effective mass of conduction electron // Calculation E=(h^2*(((0.1*10^10)^2)+((0.1*10^10)^2)))/(2*m_c); A= E/(1.6*10^-19); printf("Energy of conduction electron is %0.3f eV",A); // Result // Energy of conduction electron in the vertically upward direction = 11.302 eV // The non parabolic E-k dispersion relation is more appropriate here
636cc4a9afe40729ba4847408a228c07676f5f30
449d555969bfd7befe906877abab098c6e63a0e8
/3554/CH15/EX15.2/Ex15_2.sce
3dfba4a17d163374e9f52f28ae3c9dd96cee8afc
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
249
sce
Ex15_2.sce
// Exa 15.2 clc; clear all; // Given data Wc=20*10^3; // Angular cutoff frequency in rad/s C=0.01*10^-6; //in farads // Solution // As Wc=1/(R*C); R=1/(Wc*C); printf(' The value of resistance required = %d k Ohms \n',R/1000);
15938c24f8a07f317b0faa3f98f0b87cc88f6318
31cfd6fac62ce1e0f8bb81f96db3978b301d4fd2
/Raízes (zero de funções reais)/Regula Falsi/regula falsi.sci
5495b600711bba86cfe7f6d5d3f26f3fedec805d
[]
no_license
PierreVieira/Scilab_Programs
2205084b7356cf9ab68e8b04525e55fd7e29636c
63d717f04db929c81dc1ff7fa9eb886f3c6b6a8c
refs/heads/master
2020-09-09T00:59:34.924700
2020-03-17T18:46:50
2020-03-17T18:46:50
221,296,397
0
0
null
null
null
null
UTF-8
Scilab
false
false
1,383
sci
regula falsi.sci
/* Objetivo: Clcular a raiz de uma equação pelo método da regula falsi Parâmetros de entrada: a, b, Toler, IterMax Parâmetros de saída: Raiz, Iter, CondErro Pierre Vieira */ function [Raiz, Iter, CondErro] = RegulaFalsi(a, b, Toler, IterMax) deff('y = f(x)', 'y = 2*x^3 - cos(x+1) - 3') Fa = f(a) Fb = f(b) if Fa * Fb > 0 then printf("Função não muda de sinal nos extremos do intervalo dado\n") exit(0) end if Fa > 0 then t = a a = b b = t t = Fa Fa = Fb Fb = t end Iter = 0 x = b Fx = Fb DeltaX = -Fx/(Fb-Fa)*(b-a) printf("Iter\ta\tFa\t\tb\tFb\tx\t\tFx\tDeltaX\n") while 1 do DeltaX = -Fx/(Fb-Fa)*(b-a) x = x + DeltaX Fx = f(x) //Avakiar a função em x printf("%d, %f, %f, %f, %f, %f, %f, %f\n", Iter, a, Fa, b, Fb, x, Fx, DeltaX) if abs(DeltaX) <= Toler & abs(Fx) <= Toler | Iter >= IterMax then break end if Fx < 0 then a = x Fa = Fx else b = x Fb = Fx end Iter = Iter + 1 end Raiz = x //Teste de convergência if abs(DeltaX) <= Toler & abs(Fx) <= Toler then CondErro = 0 else CondErro = 1 end endfunction
1e1242793a47a00c10fcd3c09246afac221818db
449d555969bfd7befe906877abab098c6e63a0e8
/45/CH8/EX8.13/example_8_13.sce
878ac77991809a163579701ea6d8f4137f240905
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
184
sce
example_8_13.sce
//example 8.13 clc; clear; disp('For SR flip flop Qn+1 = S + R`Qn and for D flip-flop Qn+1 = D .'); disp('Thus with D = S + R`Qn we get circuit which behaves like SR flip-flop.');
118a8c8e1949de7945b920621bb7709b131dd841
449d555969bfd7befe906877abab098c6e63a0e8
/72/CH9/EX9.7.1/9_7_1.sce
f5d8d6b435ae5fbc32823d770a06c0c8f672b2e4
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
1,052
sce
9_7_1.sce
//chapter_no.-9, page_no.-427 //Example_no.9-7-1 clc; //(a) Calculate_the_number_of_electrons_returned_per_second Ir=.85;//returned_current q=1.6*(10^-19);//electronic_charge Nr=Ir/q; disp(Nr,'the_number_of_electrons_returned_(per_second) is ='); //(b)Calculate_the_Energy_associated_with_these_returning_electrons_in_20ms V=11*(10^3);//overdepreesion_collector_voltage t=20*(10^-3); W=V*Nr*t; disp(W,'the_Energy_associated_with_these_returning_electrons_in_20ms(in eV) is ='); //(c) Calculate_the_Power_for_returning_electrons P=V*Ir; P=P/1000; disp(P,'the_Power_for_returning_electrons(in KW)is ='); //(d) Calculate_the_Heat_associated_with_the_returning_electrons t=20*(10^-3); H=.238*P*1000*t; disp(H,'the_Heat_associated_with_the_returning_electrons(in calories)is ='); //(e) Calculate_the_temperature mass=250*(10^-3); specificheat=.108; T=H/(mass*specificheat); disp(T,'the_temperature(in degree Celsius)is ='); //(f) Calculate_whether_the_output_iron_pole_piece_is_melted disp('the_output_iron_pole_piece_is_melted');
436070045a302a3eaa48d197b71c6f5a46b4ac0e
7c74252476ecbb33ff6b44b6360b314586cc345e
/Fonction Vitesse Modélisé Morin.sci
eb89dfb11f2ba2ae24f4690d30415d4673f96daf
[]
no_license
Gaetan43/Scilab-Master-2-PFV
5d254ab060ba0096660f38ed64a0717d2a88adf5
cd890518af755e905f2089a8cfcc1d5a438f3492
refs/heads/master
2020-04-22T10:10:37.229172
2019-02-12T10:15:00
2019-02-12T10:15:00
170,296,003
0
0
null
null
null
null
UTF-8
Scilab
false
false
84
sci
Fonction Vitesse Modélisé Morin.sci
function y= yExp(x,c) y = c(1)*(1-exp(-((x-c(2))/c(3)))); endfunction
27ab9e7c93e5880f269645220adce22c160b31a2
993c10f7706af779d36ea4b5254792a34da554c1
/ann/Praticas/rede_camada_unica/run.sci
1a739fc48958c230f0b2e2da106126849bcfa951
[]
no_license
francislz/college_codes
e1c113a29fcb704a243e5a942bf2c629157d315a
41bbefbe13135eb2654815aeb546a44462847b87
refs/heads/master
2022-01-29T11:15:15.597217
2018-11-01T22:40:13
2018-11-01T22:40:13
155,784,263
1
0
null
null
null
null
UTF-8
Scilab
false
false
1,438
sci
run.sci
clear; warning off; exec('../Classificacao_gaussiana/geragauss.sce',-1); exec('../Plota_Dados_E_Reta/plotdata.sce',-1); exec('../Treinamento_Perceptron/treina_perceptron.sce',-1); exec('../Perceptron/perceptron.sci',-1); max_epocas = 100; //DEfine max de epocas alfa = 1.2; // Alfa de ajuste tol = 10; //Tolerancia function bits = de2bi(Yd) str = dec2bin(Yd); bits = [] sz = size(str) for i=1:sz(2), if Yd(i) ~= 0 bits(1,i) = 0; bits(2,i) = strtod(part(str(i),1)); bits(3,i) = strtod(part(str(i),2)); else bits(1,i) = 1; bits(2,i) = strtod(part(str(i),1)); bits(3,i) = strtod(part(str(i),2)); end end endfunction nc = 3; npc = [20 50 40]; mc = [1.2 3 4.7; 1.1 3.1 5.1]; varc = [0.1 0.1 0.1; 0.1 0.1 0.1]; [X Yd] = geragauss(nc, npc, mc, varc); [X Yd] = mixvalues(X, Yd); W = []; b = []; for i=1:nc, aux = [rand() rand()]; W = [W; aux]; b = [b; rand()]; end Yd_ = de2bi(Yd); for i = 1:nc, [Wout(i,:), bout(i,:), VetorSEQ] = treina_perceptron(W(i,:), b(i), X, Yd_(i,:), alfa, max_epocas, tol); //Plotar o Gráfico dos erros quadraticos. scf(1); title("Erros Quadraticos 1"); plot(VetorSEQ); xlabel('Epoca'); ylabel('VetorSEQ'); end // Grafico de dados e da reta em duas dimensões para a função 1 scf(2); title("1"); plotadc2d(X, Yd); for i = 1:nc, plotareta(Wout(i,:), bout(i,:), [0 5]); end
db472b5ecbb55bd7005011ba28de855ce3fea811
449d555969bfd7befe906877abab098c6e63a0e8
/3843/CH4/EX4.8/Ex4_8.sce
56b96ed3d9cdaea3658e3240f5e86da765c7859b
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
792
sce
Ex4_8.sce
// Example 4_8 clc;funcprot(0); // Given data m=1;// The mass of nitrogen in kg T_1=300;// K T_2=1200;// K M=28;// kg/kmol // Calculation // (a) // Using the gas table in Appendix F,find the enthalpy change h_1=8723;// kJ/kmol h_2=36777;// kJ/kmol delh=h_2-h_1;// kJ/mol delh=delh/M;// kJ/kg printf("\n(a)The enthalpy change,delh=%5.0f kJ/kmol or %4.0f kJ/kg",delh*M,delh); // (b) // The expression for c_p(T) is found in Table B-5. delh=integrate('(39.06-(519.79*(T/100)^(-1.5))+(1072.7*(T/100)^(-2))-(820.4*(T/100)^(-3)))','T',T_1,T_2);// kJ/kmol delh=delh/M;// kJ/kg printf("\n(b)The enthalpy change,delh=%5.0f kJ/kmol or %4.0f kJ/kg",delh*M,delh); // (c) c_p=1.042;// kJ/kg.K delh=c_p*(T_2-T_1);// kJ/kg printf("\n(c)The enthalpy change,delh=%3.0f kJ/kg",delh);
597c2401507c81e1d50f3a1c27814a7d3306e94c
7b040f1a7bbc570e36aab9b2ccf77a9e59d3e5c2
/Scilab/virtual/2dof_controller/dc/ident/scilab/oe_est.sce
69ea8fbd6a717402d47fb549ecba46a7a71ee84b
[]
no_license
advait23/sbhs-manual
e2c380051117e3a36398bb5ad046781f7b379cb9
d65043acd98334c44a0f0dbf480473c4c4451834
refs/heads/master
2021-01-16T19:50:40.218314
2012-11-16T04:11:12
2012-11-16T04:11:12
null
0
0
null
null
null
null
UTF-8
Scilab
false
false
525
sce
oe_est.sce
// Updated(9-8-07) // 6.17 getf armac1.sci; getf oe.sci; b = [0 0 0.6 -0.2]; f = [1 -0.5]; c = 1; d = 1; process_oe = armac1(1,b,c,d,f,0.05); u = prbs_a(2555,250); xi = rand(1,2555,'normal'); y = arsimul(process_oe,[u xi]); z = [y(1:length(u))' u']; zd = detrend(z,'constant'); // Compute IR for time-delay estimation [ir,r,cl_s] = cra(zd); // Time-delay = 2 samples // Estimate ARX model (assume known orders) nb = 2; nf = 1; nk = 2; // tic(); [thetaN,covfN,nvar] = oe(zd,nb,nf,nk); // toc()
285ceb8de337a3d1254ee648e5c0bfde4bd00256
449d555969bfd7befe906877abab098c6e63a0e8
/2495/CH1/EX1.5.10/Ex1_5_10.sce
24edd9961aa65d79393af683a4e035cef5e1ac73
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
124
sce
Ex1_5_10.sce
clear clc T=273;//in K R=8.314;//in J/Kmol DelHm=T*2.303*R;//in J/mol printf('DelHm=%.1d J/mol',DelHm) //page 16
fb80e502ad73727f9cd65b2fd8ea2a93f901ef8f
449d555969bfd7befe906877abab098c6e63a0e8
/2744/CH12/EX12.2/Ex12_2.sce
d07fe1ff74e0709394dbdd553a876cc18aab0859
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
178
sce
Ex12_2.sce
clear; clc; D = 2;// inches N = 150;// RPM f_s = 9000;// lb/in^2 M_r = f_s*(%pi/16)*D^3;// lb-inches HP = M_r*2*%pi*N/(12*33000);// printf('H.P transmitted is %.2f',HP);
4d1e6d02b7e0d9ddd1bef147d401bc6f78d5c6e3
e0124ace5e8cdd9581e74c4e29f58b56f7f97611
/3913/CH12/EX12.46/Ex12_46.sce
ad271da9beaaa64c6dcc96caaed797761d135d17
[]
no_license
psinalkar1988/Scilab-TBC-Uploads-1
159b750ddf97aad1119598b124c8ea6508966e40
ae4c2ff8cbc3acc5033a9904425bc362472e09a3
refs/heads/master
2021-09-25T22:44:08.781062
2018-10-26T06:57:45
2018-10-26T06:57:45
null
0
0
null
null
null
null
UTF-8
Scilab
false
false
291
sce
Ex12_46.sce
//Chapter 12 : Solutions to the Exercises //Scilab 6.0.1 //Windows 10 clear; clc; //Solution for 11.2 A=[1 -2 3 -4;-5 6 -7 8;9 -10 11 -12;-13 14 -15 16] eigv=spec(A) eigv(3)=round(eigv(3)) eigv(4)=round(eigv(4)) disp(eigv,'eigen values are') //eigen value 1 is wrong in book
c3f007108c32cfa805a522e18f16827a993c91f4
449d555969bfd7befe906877abab098c6e63a0e8
/182/CH16/EX16.1/example16_1.sce
a5b1b452948824b72a84329cb46e0f48c35eb1b7
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
620
sce
example16_1.sce
//to find the source & load effects and load & line regulation // example 16-1 in page 423 clc; //Data Given Es=[12 11.95]; // change in Dc power supply when ac drops by 10% Eo=[12 11.9];// change in output voltage when load current goes from zero to maximum //calculation printf("source effect=%d mV\n",(Es(1)-Es(2))*1000); printf("line regulation=%.2f percent\n",(Es(1)-Es(2))*100/Es(1)); printf("load effect=%d mV\n",(Eo(1)-Eo(2))*1000); printf("line regulation=%.2f percent\n",(Eo(1)-Eo(2))*100/Eo(1)); //result //source effect=50 mV //line regulation=0.42 percent //load effect=99 mV //line regulation=0.83 percent
86c2027ed6dde143f7d08ddede421f597e924aed
53bdf5ec3d505c23a6dbff1555c838c03e7ce670
/Assignment 2/q4.sce
52b091d4168794ea2b1f75e80dfd7a43e5a50817
[]
no_license
dishvyas/AI
6e7fb662a04b99d5fca4380f97ac94eb5b18debe
a0903084fe210faee4b571b4cade5e5d410ad504
refs/heads/master
2020-05-22T00:50:06.362841
2019-05-12T20:29:20
2019-05-12T20:29:20
186,180,759
0
1
null
null
null
null
UTF-8
Scilab
false
false
58
sce
q4.sce
x=-10:10; k=1./(1+exp(-x)); clf; plot(x,k); xgrid();
a4078161134834a11abdf0c7e364db66cee049a7
449d555969bfd7befe906877abab098c6e63a0e8
/839/CH17/EX17.1/Example_17_1.sce
95f2097991622b5e0bcbe014dce8a6f588ee0982
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
1,102
sce
Example_17_1.sce
//clear// clear; clc; //Example 17.1 //Given yb = 0.30; //Let Vb = 100; //[mol] Ace_in = yb*Vb; //[mol] Air_in = Vb-Ace_in; //[mol] //97 percent acetone aborbed, Acetone leaving is Ace_out = 0.03*Ace_in; //[mol] ya = Ace_out/(Air_in+Ace_out); //Acetone absorbed Ace_abs = Ace_in-Ace_out; //[mol] //10 percent acetone in the leaving solution and no acetone in the entering oil Lb = Ace_abs/0.1; //[mol] La = Lb-Ace_abs; //[mol] //To find out as intermediate point on the operating line, making an acetone balance //around the top part of the tower, assuming a particular value of yV the moles of //acetone left in the gas. for i=1:30 y(i) = i/(i+Air_in); //The moles of acetone lost by the gas in the secion, must equal to the moles gained by //the liquid Ace_lost = i-Ace_out; //[mol] //Hence x(i) = Ace_lost/(La+Ace_lost); end xe = linspace(0.001,0.15,100); ye = 1.9*xe; plot(x,y) plot(xe,ye,'r') xlabel('x') ylabel('y') legend('Operating line','Equilibrium line') title('Diagram Example 17.1') //The number of ideal stages determined from Fig is 4
6fc229b4d8c8a543bec86ac2254acca0ae370743
449d555969bfd7befe906877abab098c6e63a0e8
/3808/CH4/EX4.16/Ex4_16.sce
894d8d0408de476f514f3f815a7c4040adf0a957
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
328
sce
Ex4_16.sce
//Chapter 04:Number Theory and Cryptography clc; clear all; //To find the GCD using euclidean algorithm function gcd(a,b) x=a y=b while y ~=0 r=modulo(x,y) x=y y=r end mprintf("GCD(%d,%d) = %d",a,b,x) endfunction n1=input("Enter 1st Number:") n2=input("Enter 2nd Number:") gcd(n1,n2)
1ac658c2f2fbeeb638f0c8287e9dd7bf9af2103c
449d555969bfd7befe906877abab098c6e63a0e8
/1244/CH1/EX1.8/Example18.sce
573e393cdd24d922e3e49963cd9807267d139b8c
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
1,010
sce
Example18.sce
// Display mode mode(0); // Display warning for floating point exception ieee(1); clc; disp("Principles of Heat Transfer, 7th Ed. Frank Kreith et. al Chapter - 1 Example # 1.8 ") //Length for heat transfer for stainless steel in m Lss = 0.1; //Area for heat transfer for stainless steel in m2 A = 0.01; //Thermal conductivity for stainless steel in W/m-K kss = 144; //Length for heat transfer for Duralumin in m La1 = 0.02; //Area for heat transfer for Duralumin in m2 A = 0.01; //Thermal conductivity for Duralumin in W/m-K ka1 = 164; //Resistance in case of steel in K/W Rk1 = Lss/(A*kss); //Resistance in case of Duralumin in K/W Rk2 = La1/(A*ka1); //From Fig. 1.20, contact resistance in K/W Ri = 0.05; //Total resistance to heat transfer in K/W Rtotal = Rk1+Rk2+Ri; //Temperature diff. is given in K deltaT = 40; disp("Maximum allowable rate of heat dissipation in W is") //Maximum allowable rate of heat dissipation in W q = deltaT/Rtotal
30b207908906f969cdc6d0c5c61efa71501e0f64
449d555969bfd7befe906877abab098c6e63a0e8
/1529/CH2/EX2.16/2_16.sce
afb58c98fc660a5e4f0c3284d230fa751d4f118d
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
329
sce
2_16.sce
//Chapter 2, Problem 16 clc; V=240; //supply voltage I=13; //current t=30; //time in hours P=V*I; //power E=P*t; //energy printf("Energy used per week = %.1f kWh\n\n",E/1000); printf("hence weekly cost of electricity = %.2f £ euro",(E*12.5/1000)/100);
8f6eba31f972c004067e601eb4e0f6fedf312d16
449d555969bfd7befe906877abab098c6e63a0e8
/249/CH3/EX3.2/3_02.sce
bb129725c87c102924da724c14cc737321574e44
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
1,414
sce
3_02.sce
clear clc function [coefs]=regress(x,y) coefs=[] if (type(x) <> 1)|(type(y)<>1) then error(msprintf(gettext("%s: Wrong type for input arguments: Numerical expected.\n"),"regress")), end lx=length(x) if lx<>length(y) then error(msprintf(gettext("%s: Wrong size for both input arguments: same size expected.\n"),"regress")), end if lx==0 then error(msprintf(gettext("%s: Wrong size for input argument #%d: Must be > %d.\n"),"regress", 1, 0)), end x=matrix(x,lx,1) y=matrix(y,lx,1) xbar=sum(x)/lx ybar=sum(y)/lx coefs(2)=sum((x-xbar).*(y-ybar))/sum((x-xbar).^2) coefs(1)=ybar-coefs(2)*xbar endfunction CA=[10;8;6;5;3;2;1];//mol/litre T=[0;20;40;60;120;180;300];//sec //plot(T,CA) //xlabel('Time(sec)');ylabel('CA(mol/litre)'); //From graph y=-dCA/dt at different points are y=[-0.1333;-0.1031;-0.0658;-0.0410;-0.0238;-0.0108;-0.0065]; //Guessing nth rate order //rA=kCA^n //log(-dCA/dt)=logk+nlogCA for i=1:7 log_y(i)=log10(y(i)); log_CA(i)=log10(CA(i)); end plot(log_CA,log_y) xlabel('logCA');ylabel('log(-dCA/dt)') coeff1=regress(log_CA,log_y); n=coeff1(2); k=-10^(coeff1(1)); printf("\n After doing linear regression,the slope and intercept of the graph is %f , %f",coeff(2),coeff(1)) printf("\n The rate equation is therefore given by %f",k) printf("CA^1.375 mol/litre.sec") disp('The answer slightly differs from those given in book as regress fn is used for calculating slope and intercept')
115b88fe24917e9a2b815f128d0e778dbcb93827
449d555969bfd7befe906877abab098c6e63a0e8
/1445/CH2/EX2.9/Ex2_9.sce
f2779616b4462658dafd3c74539e612a9db087ec
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
488
sce
Ex2_9.sce
//CHAPTER 2- STEADY-STATE ANALYSIS OF SINGLE-PHASE A.C. CIRCUIT //Example 9 clc; disp("CHAPTER 2"); disp("EXAMPLE 9"); //VARIABLE INITIALIZATION v1=120; //voltage of lamp in Volts p=100; //in Watts v2=220; //supply voltage in Volts f=50; //in Hertz //SOLUTION vl=sqrt((v2^2)-(v1^2)); xl=(v1*vl)/p; L=xl/(2*%pi*f); disp(sprintf("The pure inductance should have a value of %f H",L)); //END
3c9023f1a9956050132450227e67bc05d0e45027
d9361899121113cb290a6dac6f988fd5b829b917
/funcionesYpolinomios.sce
44af513d3550362cdefaaec8afa39f1c0662dc17
[]
no_license
AgustinGurvich/MetodosScilab
139243d925fe8b7381551d6c65b59f14b2d4069b
7fe62e9948160cf3fa9aa5844023307678bb79aa
refs/heads/master
2022-04-11T13:54:44.337939
2019-11-29T02:59:07
2019-11-29T02:59:07
null
0
0
null
null
null
null
UTF-8
Scilab
false
false
2,313
sce
funcionesYpolinomios.sce
function x = metodoRobusto(p) //Solucion de ecuaciones cuadraticas con discriminante positivo c = coeff(p,0) b = coeff(p,1) a = coeff(p,2) if((b*b-4*a*c)>0) then if(b < 0) then x(1) = (2*c)/(-b + sqrt(b^2 - 4*a*c)) x(2) = (-b + sqrt(b^2 - 4*a*c)) / (2*a) elseif (b > 0) then x(1) = (-b-sqrt(b^2-4*a*c))/(2*a) x(2) = (2*c)/(-b - sqrt(b^2 - 4*a*c)) else x(1) = (sqrt(-c*a)) x(2) = -(sqrt(-c*a)) end else x(1) = %nan x(2) = %nan end endfunction function x = evaluarHorner(p,a) //Evaluacion eficiente utilizando el metodo de Horner coefAnterior = coeff(p,degree(p)) coefActual = 0 for i = (degree(p)-1):-1:0 coefActual = coeff(p,i) coefAnterior = (coefActual + a*coefAnterior) end x = coefAnterior endfunction function x = derivarYEvaluarHorner(p,a) //Evalua un polinomio en un punto y devuelve el valor y su derivada coefAnterior = coeff(p,degree(p)) coefActual = 0 coeffDerivado = 0 for i = (degree(p)-1):-1:0 coeffDerivado = coeffDerivado + coefAnterior * (a**(i)) coefActual = coeff(p,i) coefAnterior = (coefActual + a*coefAnterior) end x(1) = coefAnterior x(2) = coeffDerivado endfunction function e = errorAbsoluto(x,y) e(1) = abs(x(1)-y(1)) e(2) = abs(x(2)-y(2)) endfunction function e = errorRelativo(x,y) e(1) = abs(x(1)-y(1))/abs(x(1)) e(2) = abs(x(2)-y(2))/abs(x(2)) endfunction function x = derivar(f,v,n,h) //Recibe una funcion, un valor, un orden y un paso //Consume MUCHA memoria if (n ==0) then x = f(v) else x = (derivar(f,v+h,n-1,h)-derivar(f,v,n-1,h))/h end endfunction function x = derivarIterativo(f,v,n,h) //Recibe una funcion, un valor, un orden y un paso //Metodo iterativo deff("y=D0F(x)", "y="+f) for i = 1:1:n-1 deff("y=D"+string(i)+"F(x)", "y=(D"+string(i-1)+"F(x+h)-D"+string(i-1)+"F(x))/h") end deff ("y=DnF(x)", "y=(D"+string(n-1)+"F(x+h)-D"+string(n-1)+"F(x))/h") x = DnF(v) endfunction //-*- Epsilon e = 0.0001 //-*- function x = taylor(f,n,a,v,e) x=f(a) for i = 1:n x = x + (derivar(f,a,i,e)*(v-a))/factorial(i) end endfunction
32f135e4134c14e4014eacfd8634156a0ebe143d
449d555969bfd7befe906877abab098c6e63a0e8
/764/CH5/EX5.10.b/solution5_10.sce
e3019495ab97bc0882f0247136eb9082cfed04c3
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
1,093
sce
solution5_10.sce
//Obtain path of solution file path = get_absolute_file_path('solution5_10.sce') //Obtain path of data file datapath = path + filesep() + 'data5_10.sci' //Obtain path of function file funcpath = path + filesep() + 'functions5_10.sci' //Clear all clc //Execute the data file exec(datapath) exec(funcpath,[-1]) //Calculate Sdash (N/mm2) Sdash = (50/100)*Sut //Calculate Ka, Kb and Kc [Ka, Kb, Kc] = fluctuate(op, d, reliability) //From Fig.5.24 //Ka = 0.78 //Caluclate Kf Kf = 1 + (q*(Kt - 1)) //Calculate Kd Kd = (1/Kf) //Calculate Se (N/mm2) Se = Ka * Kb * Kc * Kd * Sdash //Plot S-N Curve funcprot(0) [a, b, c, z] = SNplot(Sut,Se) Nval = log10(N) //Calculate Sf corresponding to N (N/mm2) Sfval = a - (((a - b)*(Nval - c))/(z - c)) Sf = (10^Sfval) //Calculate the value of actual d (mm) d = ((32 * P * dist)/(%pi * Sf))^(1/3) //Print results printf('\nThe diameter of the beam(d) = %f mm\n',d) printf('\nAnswer is slightly different because of use of equation 5.18\n') printf('Use value of Ka from Fig.5.24 in order to obtain the mentioned result\n')
af9e02669d92d877cd8b71a26b452789b93be8bb
449d555969bfd7befe906877abab098c6e63a0e8
/40/CH6/EX6.4/Exa_6_4.sce
04548d4606a46789a6365fb89cda84237a8eda66
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
405
sce
Exa_6_4.sce
//linear phase filters z=%z H1Z=((z^3)+2*(z^2)+2*z+1)/(z^3); //from pole zero diagram its not a linear phase filter H2Z=(z^4+4.25*z^2+1)/(z^4); xset('window',1); plzr(H2Z); //from pole zero diagram and LPF // characteristics its a linear phase filter H3Z=((z^4+2.5*z^3-2.5*z-1)/(z^4)); xset('window',2); plzr(H3Z); //from pole zero diagram and LPF // characteristics its a linear phase filter
0c136f4dd85407bd382c26d52610d0b3f22c53b7
449d555969bfd7befe906877abab098c6e63a0e8
/1658/CH32/EX32.11/Ex32_11.sce
749955b14d38af26f3eaad076260f367c75874ea
[]
no_license
FOSSEE/Scilab-TBC-Uploads
948e5d1126d46bdd2f89a44c54ba62b0f0a1f5e1
7bc77cb1ed33745c720952c92b3b2747c5cbf2df
refs/heads/master
2020-04-09T02:43:26.499817
2018-02-03T05:31:52
2018-02-03T05:31:52
37,975,407
3
12
null
null
null
null
UTF-8
Scilab
false
false
162
sce
Ex32_11.sce
clc; Acm=0.001; AOL=180000; Zin=1*10**6; Zout=80; SR=0.5; Acl=1; CMRR=Acl/Acm; disp(CMRR); Vpk=3; fmax=SR/(2*%pi*Vpk) disp('kHZ',fmax*10**3,"fmax=");