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comparison execute_dwt_cor_aVb_all.xml @ 0:0f2eda4ea8dc draft

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author devteam
date Mon, 27 Jan 2014 09:26:52 -0500
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1 <tool id="compute_p-values_correlation_coefficients_featureA_featureB_occurrences_between_two_datasets_using_discrete_wavelet_transfom" name="Compute P-values and Correlation Coefficients for Occurrences of Two Set of Features" version="1.0.0">
2 <description>between two datasets using Discrete Wavelet Transfoms</description>
3
4 <command interpreter="perl">
5 execute_dwt_cor_aVb_all.pl $inputFile1 $inputFile2 $outputFile1 $outputFile2
6 </command>
7
8 <inputs>
9 <param format="tabular" name="inputFile1" type="data" label="Select the first input file"/>
10 <param format="tabular" name="inputFile2" type="data" label="Select the second input file"/>
11 </inputs>
12
13 <outputs>
14 <data format="tabular" name="outputFile1"/>
15 <data format="pdf" name="outputFile2"/>
16 </outputs>
17
18 <help>
19
20 .. class:: infomark
21
22 **What it does**
23
24 This program generates plots and computes table matrix of coefficient correlations and p-values at multiple scales for the correlation between the occurrences of features in one dataset and their occurrences in another using multiscale wavelet analysis technique.
25
26 The program assumes that the user has two sets of DNA sequences, S1 and S1, each of which consists of one or more sequences of equal length. Each sequence in each set is divided into the same number of multiple intervals n such that n = 2^k, where k is a positive integer and k >= 1. Thus, n could be any value of the set {2, 4, 8, 16, 32, 64, 128, ...}. k represents the number of scales.
27
28 The program has two input files obtained as follows:
29
30 For a given set of features, say motifs, the user counts the number of occurrences of each feature in each interval of each sequence in S1 and S1, and builds two tabular files representing the count results in each interval of S1 and S1. These are the input files of the program.
31
32 The program gives two output files:
33
34 - The first output file is a TABULAR format file representing the coefficient correlations and p-values for each feature at each scale.
35 - The second output file is a PDF file consisting of as many figures as the number of features, such that each figure represents the values of the coefficient correlations for that feature at every scale.
36
37 -----
38
39 .. class:: warningmark
40
41 **Note**
42
43 In order to obtain empirical p-values, a random perumtation test is implemented by the program, which results in the fact that the program gives slightly different results each time it is run on the same input file.
44
45 -----
46
47 **Example**
48
49 Counting the occurrences of 5 features (motifs) in 16 intervals (one line per interval) of the DNA sequences in S1 gives the following tabular file::
50
51 deletionHoptspot insertionHoptspot dnaPolPauseFrameshift topoisomeraseCleavageSite translinTarget
52 82 162 158 79 459
53 111 196 154 75 459
54 98 178 160 79 475
55 113 201 170 113 436
56 113 173 147 95 446
57 107 150 155 84 436
58 106 166 175 96 448
59 113 176 135 106 514
60 113 170 152 87 450
61 95 152 167 93 467
62 91 171 169 118 426
63 84 139 160 100 459
64 92 154 164 104 440
65 100 145 154 98 472
66 91 161 152 71 461
67 117 164 139 97 463
68
69 And counting the occurrences of 5 features (motifs) in 16 intervals (one line per interval) of the DNA sequences in S2 gives the following tabular file::
70
71 deletionHoptspot insertionHoptspot dnaPolPauseFrameshift topoisomeraseCleavageSite translinTarget
72 269 366 330 238 1129
73 239 328 327 283 1188
74 254 351 358 297 1151
75 262 371 355 256 1107
76 254 361 352 234 1192
77 265 354 367 240 1182
78 255 359 333 235 1217
79 271 389 387 272 1241
80 240 305 341 249 1159
81 272 351 337 257 1169
82 275 351 337 233 1158
83 305 331 361 253 1172
84 277 341 343 253 1113
85 266 362 355 267 1162
86 235 326 329 241 1230
87 254 335 360 251 1172
88
89
90 We notice that the number of scales here is 4 because 16 = 2^4. Running the program on the above input files gives the following output:
91
92 The first output file::
93
94 motif1 motif2 1_cor 1_pval 2_cor 2_pval 3_cor 3_pval 4_cor 4_pval
95
96 deletionHoptspot insertionHoptspot -0.1 0.346 -0.214 0.338 1 0.127 1 0.467
97 deletionHoptspot dnaPolPauseFrameshift 0.167 0.267 -0.214 0.334 1 0.122 1 0.511
98 deletionHoptspot topoisomeraseCleavageSite 0.167 0.277 0.143 0.412 -0.667 0.243 1 0.521
99 deletionHoptspot translinTarget 0 0.505 0.0714 0.441 1 0.124 1 0.518
100 insertionHoptspot dnaPolPauseFrameshift -0.202 0.238 0.143 0.379 -1 0.122 1 0.517
101 insertionHoptspot topoisomeraseCleavageSite -0.0336 0.457 0.214 0.29 0.667 0.252 1 0.503
102 insertionHoptspot translinTarget 0.0672 0.389 0.429 0.186 -1 0.119 1 0.506
103 dnaPolPauseFrameshift topoisomeraseCleavageSite -0.353 0.101 0.357 0.228 0 0.612 -1 0.49
104 dnaPolPauseFrameshift translinTarget -0.151 0.303 -0.571 0.09 -0.333 0.37 -1 1
105 topoisomeraseCleavageSite translinTarget -0.37 0.077 -0.222 0.297 0.667 0.234 -1 0.471
106
107 The second output file:
108
109 .. image:: ${static_path}/operation_icons/dwt_cor_aVb_all_1.png
110 .. image:: ${static_path}/operation_icons/dwt_cor_aVb_all_2.png
111 .. image:: ${static_path}/operation_icons/dwt_cor_aVb_all_3.png
112 .. image:: ${static_path}/operation_icons/dwt_cor_aVb_all_4.png
113 .. image:: ${static_path}/operation_icons/dwt_cor_aVb_all_5.png
114 .. image:: ${static_path}/operation_icons/dwt_cor_aVb_all_6.png
115 .. image:: ${static_path}/operation_icons/dwt_cor_aVb_all_7.png
116 .. image:: ${static_path}/operation_icons/dwt_cor_aVb_all_8.png
117 .. image:: ${static_path}/operation_icons/dwt_cor_aVb_all_9.png
118 .. image:: ${static_path}/operation_icons/dwt_cor_aVb_all_10.png
119
120
121 </help>
122
123 </tool>