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Segmentation

Deprecated

This interface is deprecated and has been removed from PlantSeg v2. Please use the Napari viewer or the command line interface instead, or install PlantSeg v1.

The segmentation widget allows using very powerful graph partitioning techniques to obtain a segmentation from the input stacks. The input of this widget should be the output of the CNN-prediction widget. If the boundary prediction stage fails for any reason, a raw image could be used (especially if the cell boundaries are very sharp, and the noise is low) but usually does not yield satisfactory results.

  • The Algorithm menu can be used to choose the segmentation algorithm. Available choices are:

    1. GASP (average): is a generalization of the classical hierarchical clustering. It usually delivers very reliable and accurate segmentation. It is the default in PlantSeg.
    2. MutexWS: Mutex Watershed is a derivative of the standard Watershed, where we do not need seeds for the segmentation. This algorithm performs very well in certain types of complex morphology (like )
    3. MultiCut: in contrast to the other algorithms is not based on a greedy agglomeration but tries to find the optimal global segmentation. This is, in practice, very hard, and it can be infeasible for huge stacks.
    4. DtWatershed: is our implementation of the distance transform Watershed. From the input, we extract a distance map from the boundaries. Based this distance map, seeds are placed at local minima. Then those seeds are used for computing the Watershed segmentation. To speed up the computation of GASP, MutexWS, and MultiCut, an over-segmentation is obtained using Dt Watershed.
  • Save Directory defines the sub-directory's name where the segmentation results will be stored.

  • The Under/Over- segmentation factor is the most critical parameters for tuning the segmentation of GASP, MutexWS and MultiCut. A small value will steer the segmentation towards under-segmentation. While a high-value bias the segmentation towards the over-segmentation. This parameter does not affect the distance transform Watershed.

  • If Run Watershed in 2D value is True, the superpixels are created in 2D (over the z slice). While if False makes the superpixels in the whole 3D volume. 3D superpixels are much slower and memory intensive but can improve the segmentation accuracy.

  • The CNN Prediction Threshold is used for the superpixels extraction and Distance Transform Watershed. It has a crucial role for the watershed seeds extraction and can be used similarly to the "Unde/Over segmentation factor." to bias the final result. A high value translates to less seeds being placed (more under segmentation), while with a low value, more seeds are placed (more over-segmentation).

  • The input is used by the distance transform Watershed to extract the seed and find the segmentation boundaries. If Watershed Seeds Sigma and Watershed Boundary Sigma are larger than zero, a gaussian smoothing is applied on the input before the operations above. This is mainly helpful for the seeds computation but, in most cases, does not impact segmentation quality.

  • The Superpixels Minimum Size applies a size filter to the initial superpixels over-segmentation. This removes Watershed often produces small segments and is usually helpful for the subsequent agglomeration. Segments smaller than the threshold will be merged with the nearest neighbor segment.

  • Even though GASP, MutexWS, and MultiCut are not very prone to produce small segments, the Cell Minimum Size can be used as a final size processing filter. Segments smaller than the threshold will be merged with the nearest neighbor cell.