Explore Workflows
View already parsed workflows here or click here to add your own
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HBA_calibrator.cwl
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https://git.astron.nl/eosc/prefactor3-cwl.git
Path: workflows/HBA_calibrator.cwl Branch/Commit ID: 5f6da86a561d1b1c5b7ef56dc8bbbb1f1d7e9cbe |
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Trim Galore RNA-Seq pipeline paired-end
The original [BioWardrobe's](https://biowardrobe.com) [PubMed ID:26248465](https://www.ncbi.nlm.nih.gov/pubmed/26248465) **RNA-Seq** basic analysis for a **pair-end** experiment. A corresponded input [FASTQ](http://maq.sourceforge.net/fastq.shtml) file has to be provided. Current workflow should be used only with the single-end RNA-Seq data. It performs the following steps: 1. Trim adapters from input FASTQ files 2. Use STAR to align reads from input FASTQ files according to the predefined reference indices; generate unsorted BAM file and alignment statistics file 3. Use fastx_quality_stats to analyze input FASTQ files and generate quality statistics files 4. Use samtools sort to generate coordinate sorted BAM(+BAI) file pair from the unsorted BAM file obtained on the step 1 (after running STAR) 5. Generate BigWig file on the base of sorted BAM file 6. Map input FASTQ files to predefined rRNA reference indices using Bowtie to define the level of rRNA contamination; export resulted statistics to file 7. Calculate isoform expression level for the sorted BAM file and GTF/TAB annotation file using GEEP reads-counting utility; export results to file |
https://github.com/datirium/workflows.git
Path: workflows/trim-rnaseq-pe.cwl Branch/Commit ID: 4a80f5b8f86c83af39494ecc309b789aeda77964 |
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PCA - Principal Component Analysis
Principal Component Analysis -------------- Principal component analysis (PCA) is a statistical procedure that uses an orthogonal transformation to convert a set of observations of possibly correlated variables (entities each of which takes on various numerical values) into a set of values of linearly uncorrelated variables called principal components. The calculation is done by a singular value decomposition of the (centered and possibly scaled) data matrix, not by using eigen on the covariance matrix. This is generally the preferred method for numerical accuracy. |
https://github.com/datirium/workflows.git
Path: workflows/pca.cwl Branch/Commit ID: ddc35c559d1ac6aab4972fe1a2b63300c4373f54 |
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any-type-compat.cwl
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https://github.com/common-workflow-language/cwltool.git
Path: cwltool/schemas/v1.0/v1.0/any-type-compat.cwl Branch/Commit ID: 7c7615c44b80f8e76e659433f8c7875603ae0b25 |
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scatter-wf3.cwl#main
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https://github.com/common-workflow-language/cwltool.git
Path: cwltool/schemas/v1.0/v1.0/scatter-wf3.cwl Branch/Commit ID: 203797516329f7fb8aa5e763e6f9b331c63c3060 Packed ID: main |
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pipeline-se-blacklist-removal.cwl
ATAC-seq pipeline - reads: SE - with blacklist removal |
https://github.com/alexbarrera/GGR-cwl.git
Path: v1.0/ATAC-seq_pipeline/pipeline-se-blacklist-removal.cwl Branch/Commit ID: 3a4314c66c1eb090e656af5a0d388cec87d65318 |
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wf_rescue_ratio_1input.cwl
Calculates the rescue ratio (see Gabe's protocols paper), given two eCLIP IP samples and 2 size-matched input samples. Also returns the reproducible peaks given these two samples. This is different from the 1input workflow in that each INPUT is first merged together and is used downstream instead of the 1input version, which remains unmodified. Merged inputs are NOT used in calculating true reproducible peaks. |
https://github.com/YeoLab/merge_peaks.git
Path: cwl/wf_rescue_ratio_1input.cwl Branch/Commit ID: 55f4f4f9c10a09ce03c5c531dd176e6080118977 |
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Bismark Methylation - pipeline for BS-Seq data analysis
Sequence reads are first cleaned from adapters and transformed into fully bisulfite-converted forward (C->T) and reverse read (G->A conversion of the forward strand) versions, before they are aligned to similarly converted versions of the genome (also C->T and G->A converted). Sequence reads that produce a unique best alignment from the four alignment processes against the bisulfite genomes (which are running in parallel) are then compared to the normal genomic sequence and the methylation state of all cytosine positions in the read is inferred. A read is considered to align uniquely if an alignment has a unique best alignment score (as reported by the AS:i field). If a read produces several alignments with the same number of mismatches or with the same alignment score (AS:i field), a read (or a read-pair) is discarded altogether. On the next step we extract the methylation call for every single C analysed. The position of every single C will be written out to a new output file, depending on its context (CpG, CHG or CHH), whereby methylated Cs will be labelled as forward reads (+), non-methylated Cs as reverse reads (-). The output of the methylation extractor is then transformed into a bedGraph and coverage file. The bedGraph counts output is then used to generate a genome-wide cytosine report which reports the number on every single CpG (optionally every single cytosine) in the genome, irrespective of whether it was covered by any reads or not. As this type of report is informative for cytosines on both strands the output may be fairly large (~46mn CpG positions or >1.2bn total cytosine positions in the human genome). |
https://github.com/datirium/workflows.git
Path: workflows/bismark-methylation-se.cwl Branch/Commit ID: ce058d892d330125cd03d0a0d5fb3b321cda0be3 |
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count-lines12-wf.cwl
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https://github.com/common-workflow-language/cwltool.git
Path: cwltool/schemas/v1.0/v1.0/count-lines12-wf.cwl Branch/Commit ID: 4635090ef98247b1902b3c7a25c007d9db1cb883 |
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scatter-valuefrom-wf4.cwl#main
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https://github.com/common-workflow-language/cwl-v1.2.git
Path: tests/scatter-valuefrom-wf4.cwl Branch/Commit ID: c7c97715b400ff2194aa29fc211d3401cea3a9bf Packed ID: main |
