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Cascaded Hierarchical Model Automatic Segmentation Algorithm

This is an algorithm designed for automatic segmention of images, including natural scene processing and cellular structures in electron microscopy data.

The core algorithm is in the "algorithm" directory while wrappers for it to do things such as run on a cluster are in the "wrappers" directory.

Some additional details about running the algorithm or any of the wrappers is contained in readmes in the respective directories. However, for general usage this readme will suffice.

If you use this program please cite the following paper: M. Seyedhosseini, M. Sajjadi, and T. Tasdizen. Image segmentation with cascaded hierarchical models and logistic disjunctive normal networks. In ICCV 2013.

Basic Usage

The two main entry points are CHM_train.sh and CHM_test.sh. The raw MATLAB and compiled versions work very similarly. It is recommend for most people to use these scripts as they simplify many of the options. However in some cases the use of the MATLAB functions CHM_test and CHM_train may be desirable and are fairly similar. All optional arguments must be at the end.

Prerequisites

If you have a MATLAB R2009a or newer license with the Image Processing toolbox you need the entire algorithm folder. If you don't then you need the wrappers/compiled folder along with installing the the MCR for the MATLAB version listed in the file matlab-version.txt. The MCR can be downloaded for free from the Mathworks website: http://www.mathworks.com/products/compiler/mcr/. Then make sure the 'matlab' command is on your PATH (basically which matlab works on the command-line).

Currently both are made and tested on Linux 64-bit machines. The compiled version cannot be run on any other architectures. To run the source version on a different architecture you must run the "compile_mex_files.m" script inside MATLAB.

Training

The first thing you need to run in CHM_train.sh. In the most basic usage it takes a set of training data images (grayscale) and a set of training label images (0=no label, 1=labeled). These file sets are specified as a comma seperated list of the following:

  • path to a folder - all PNGs and TIFFs in that folder
  • path to a file - only that file
  • path with numerical pattern - get all files matching the pattern pattern must have #s in it and end with a semicolon and number range the #s are replaced by the values at the end with leading zeros example: in/####.png;5-15 would do in/0005.png through in/0015.png
    Note: the semicolon needs to be escaped or in quotes in some shells
  • path with wildcard pattern - get all files matching the pattern pattern has * in it which means any number of any characters example: in/lbl_*.tif does all TIFF images starting with lbl_ in "in" Note: the asterisk needs to be escaped or in quotes in some shells

All training images must be the same size.

Training will take on the order of a day to complete and require lots of memory (50-150 GB) depending on the size of the dataset. Recommended that you use between 500x500 and 1000x1000 size training images with a total of 20-40 slices.

If training fails for some reason (such as running out of memory) you can restart from the last completed stage/level by using the -r flag. The -r flag has no effect if the model directory does not exist/is empty.

Testing

CHM_test.sh then takes the model generated with CHM_train and creates probability maps for how likely a pixel is the same thing as what was labelled during training. The basic usage is to give a set of data images to process and the output directory. The set of data images uses the same format as training image inputs. The output must be a directory though. This will take about 5-15 min per training-image-sized region and 5-15 GB of RAM depending on data image and training data size.

Make sure the test images are comparable to the training images: same pixel size, same acquitision parameters, same source (e.g. brain region). Testing images do not need to be all the same size.

Model Directory

The output model is by default stored in ./temp. The only files required to save are the .mat files in the root directory (the subdirectories contain actual temporary files).

To change the model directory used by either CHM_train or CHM_test you can use the -m argument.

Quality of Results

Many factors influence the quality of results, including some that are still be investigated.

The quality of the training data and labels is by far the most important. Within the training set, every example of your feature must be labelled. Additionally, a large portion of the data must be that feature. For some datasets/features applying histogram equalization to a uniform histogram can help significantly. See the HistogramEqualize tool in wrappers/image-proc.

During training you can also change the number of stages and levels of training that are performed using the -S and -L arguments respectively (they default to 2 and 4). It currently seems unlikely that values larger than this will ever be necessary, but in some cases smaller values provide better results than larger values (smaller values also run faster).

During testing there are less adjustments you can make for quality and the defaults provided should be good in most cases. First, if you are seeing edge effects (either along the edge or in the middle of the image) you have to increase the amount of overlap between tiles using the -o argument. The default is 50 pixels. Additionally, the input images have their histograms equalized to the training data histogram. To prevent this from happening use the -h flag (this is probably only needed if you perform some equalization on the images youself).

Speeding It Up

Training can be sped up by reducing the size of the training data and/or reducing the number of stages and levels trained on. This has to be done carefully as to not reduce quality. Typically, large structures can have the data binned (e.g. we bin by 8 for neucli of cells) which greatly reduces the training data size. Additionally, we have been experimenting with lowering the number of levels, and in many cases it barely effect results and sometimes even produces better results.

By default (except for compiled version) training will attempt to use all physical cores (up to 12) on your machine while "generating outputs". This isn't the most computationally heavy step so doesn't save too much time (relative to how long training takes). To disable this, use the -s flag.

If training goes faster, then testing with that model will go faster as well.

Testing has a lot more room for speed-ups since it can be heavily parallelized. First, in the basic usage, testing will attempt to use all physical cores (up to 12) for the bulk of each image (note that the first 3 "tiles" of each image will not be done in parallel). It won't run parallel across seperate images though (so the beginning and end of each image will not be fuly parallel).

However, it is actually faster to run many seperate instances of CHM_test with each operating over a portion of the test images. If you do it this way, use the -s flag to make each CHM_test not parallel itself. You can run these across multiple machines at this point.

If you are trying to run CHM_test on a single very large image or have access to a cluster, you can divide single images down even further by using -t to specify a tile to process. You can chain multiple -t to process multiple tiles. Be careful to use seperate output directories for each tile-set in this case. To combine the images after they have been run you can use ImageMagick:

convert -compose plus tiles1.png tiles2.png -composite tiles3.png -composite ... output.png

Another way to get some speed up is to reduce the overlap between tiles with -o. The default is 50 pixels and in many cases 25 is probably sufficient. However if this causes edges effects to appear (either at the edges or in the middle of the image) then you went too small.

The time required for testing is directly poportional to the following formula:

CEIL(test_image_width / (training_image_width - 2*overlap_width)) * CEIL(test_image_height / (training_image_height - 2*overlap_height))

Due to the CEIL, you may as well make the overlap width and height as large as possible before hitting the next integer.

Compiled Version Differences

The compiled version always runs in single-threaded mode (and thus ignores the -s flag). Also, you can specify the MATLAB/MCR location using the -M argument. It also looks for two environmental variables: MCR_DIR (same as -M argument) and MCR_CACHE_ROOT which sets where the program should unpack itself to, and should be some local file path (not on the network). The cache dir defaults to /tmp/mcr_cache_root_$USER. Setting it to a non-existent directory disables caching.