napari-annotatorj

napari-annotatorj

The napari adaptation of the ImageJ/Fiji plugin AnnotatorJ for easy image annotation.

This plugin allows easy object annotation on 2D images. Annotation is made quick, easy and fun, just start drawing! See a quick start guide below.

image

It is the napari version of the ImageJ plugin AnnotatorJ.

What kind of data it works on

2D images. That's the only requirement. Whether you have microscopy images of cells or tissue, natural photos of cats and dogs, vehichle dash-cam footage, industrial pipeline monitoring etc., just open the image and you can start annotating.

Annotations are save to ImageJ-compatible roi.zip files. Export is possible to several file formats depending on the intended application.

Intended users

Anyone. No experience in computer science or underlying technology is needed; if you know how to use MS Paint, you are ready to start annotating. Biologists, programmers, even children can use it. See quick start guide or demos. If you experience any issues or have questions, feel free to open an issue on GitHub.

Main features

Why choose napari-annotatorj?

See demos.

Quick start

Demo data is available in the GitHub repository's demo folder.

napari-annotatorj has several convenient functions to speed up the annotation process, make it easier and more fun. These modes can be activated by their corresponding checkboxes on the left side of the main AnnotatorJ widget.

Freehand drawing is enabled in the plugin. The "Add polygon" tool is selected by default upon startup. To draw a freehand object (shape) simply hold the mouse and drag it around the object. The contour is visualized when the mouse button is released.

See the guide below or a demo script.

Instance annotation

Allows freehand drawing of object contours (shapes) with the mouse as in ImageJ.

Shape contour points are tracked automatically when the left mouse button is held and dragged to draw a shape. The shape is closed when the mouse button is released, automatically, and added to the default shapes layer (named "ROI"). In direct selection mode (from the layer controls panel), you can see the saved contour points. The slower you drag the mouse, the more contour points saved, i.e. the more refined your contour will be.

Click to watch demo video below.

instance-annot-demo

How to annotate

  1. Open --> opens an image

  2. (Optionally)

    • ... --> Select annotation type --> Ok --> a default tool is selected from the toolbar that fits the selected annotation type
    • The default annotation type is instance
    • Selected annotation type is saved to a config file
  3. Start annotating objects

  4. Save --> Select class --> saves the annotation to a file in a sub-folder of the original image folder with the name of the selected class

  5. (Optionally)

    • Load --> continue a previous annotation
    • Overlay --> display a different annotation as overlay (semi-transparent) on the currently opened image
    • Colours --> select annotation and overlay colours
    • ... (coming soon) --> set options for semantic segmentation and Contour assist mode
    • checkboxes --> Various options
      • (default) Add automatically --> adds the most recent annotation to the ROI list automatically when releasing the left mouse button
      • Smooth (coming soon) --> smooths the contour (in instance annotation type only)
      • Show contours --> displays all the contours in the ROI list
      • Contours assist --> suggests a contour in the region of an initial, lazily drawn contour using the deep learning method U-Net
      • Show overlay --> displays the overlayed annotation if loaded with the Overlay button
      • Edit mode --> edits a selected, already saved contour in the ROI list by clicking on it on the image
      • Class mode --> assigns the selected class to the selected contour in the ROI list by clicking on it on the image and displays its contour in the class's colour (can be set in the Class window); clicking on the object a second time unclassifies it
    • [^] --> quick export in 16-bit multi-labelled .tiff format; if classified, also exports by classes

Semantic annotation

Allows painting with the brush tool (labels).

Useful for semantic (e.g. scene) annotation. Currently saves all labels to binary mask only (foreground-background).

Bounding box annotation

Allows drawing bounding boxes (shapes, rectangles) around objects with the mouse.

Useful for object detection annotation.

Demo

Instance annotation mode

See above.

Contour assist mode

Assisted annotation via a pre-trained deep learning model's suggested contour.

  1. initialize a contour with mouse drag around an object
  2. the suggested contour is displayed automatically
  3. modify the contour:
    • edit with mouse drag or
    • erase holding "Alt" or
    • invert with pressing "u"
  4. finalize it
    • accept with pressing "q" or
    • reject with pressing "Ctrl" + "Del"
  • if the suggested contour is a merge of multiple objects, you can erase the dividing line around the object you wish to keep, and keep erasing (or splitting with the eraser) until the object you wish to keep is the largest, then press "q" to accept it
  • this mode requires a Keras model to be present in the model folder

Click to watch demo video below

contour-assist-demo

Edit mode

Allows to modify created objects with a brush tool.

  1. select an object (shape) to modify by clicking on it
  2. an editing layer (labels layer) is created for painting automatically
  3. modify the contour:
    • edit with mouse drag or
    • erase holding "Alt"
  4. finalize it
    • accept with pressing "q" or
    • delete with pressing "Ctrl" + "Del" or
    • revert changes with pressing "Esc" (to the state before editing)
  • if the edited contour is a merge of multiple objects, you can erase the dividing line around the object you wish to keep, and keep erasing (or splitting with the eraser) until the object you wish to keep is the largest, then press "q" to accept it

Click to watch demo video below

edit-mode-demo

Class mode

Allows to assign class labels to objects by clicking on shapes.

  1. select a class from the class list to assign
  2. click on an object (shape) to assign the selected class label to it
  3. the contour colour of the clicked object will be updated to the selected class colour, plus the class label is updated in the text properties of object (turn on "display text" on the layer control panel to see the text properties as objectID:(classLabel) e.g. 1:(0) for the first object)
  • optionally, you can set a default class for all currently unlabelled objects on the ROI (shapes) layer by selecting a class from the drop-down menu on the right to the text label "Default class"
  • class colours can be changed with the drop-down menu right to the class list; upon selection, all objects whose class label is the currently selected class will have their contour colour updated to the selected colour
  • clicking on an object that has already been assigned a class label will unclassify it: assign the label 0 to it

Click to watch demo video below

class-mode-demo

Export

See also: Quick export

The exporter plugin AnnotatorJExport can be invoked from the Plugins menu under the plugin name napari-annotatorj. It is used for batch export of annotations to various formats directly suitable to train different types of deep learning models. See a demonstrative figure in the AnnotatorJ repository and further description in its README or documentation.

  1. browse original image folder with either the
    • "Browse original..." button or
    • text input field next to it
  2. browse annotation folder with either the
    • "Browse annot..." button or
    • text input field next to it
  3. select the export options you wish to export the annotations to (see tooltips on hover for help)
    • at least one export option must be selected to start export
    • (optional) right click on the checkbox "Coordinates" to switch between the default COCO format and YOLO format; see explanation
  4. click on "Export masks" to start the export
    • this will open a progress bar in the napari window and close it upon finish

The folder structure required by the exporter is as follows:

image_folder
	|--- image1.png
	|--- another_image.png
	|--- something.png
	|--- ...

annotation_folder
	|--- image1_ROIs.zip
	|--- another_image_ROIs.zip
	|--- something_ROIs.zip
	|--- ...

Multiple export options can be selected at once, any selected will create a subfolder in the folder where the annotations are saved.

Click to watch demo video below

exporter-demo

Quick export

Click on the "[^]" button to quickly save annotations and export to mask image. It saves the current annotations (shapes) to an ImageJ-compatible roi.zip file and a generated a 16-bit multi-labelled mask image to the subfolder "masks" under the current original image's folder.

Coordinate formats

In the AnnotatorJExport plugin 2 coordinates formats can be selecting by right clicking on the Coordinates checkbox: COCO or YOLO. The default is COCO.

COCO format:

  • [x, y, width, height] based on the top-left corner of the bounding box around the object
  • coordinates are not normalized
  • annotations are saved with header to
    • .csv file
    • tab delimeted

YOLO format:

  • [class, x, y, width, height] based on the center point of the bounding box around the object
  • coordinates are normalized to the image size as floating point values between 0 and 1
  • annotations are saved with header to
    • .txt file
    • whitespace delimeted
    • class is saved as the 1st column

Overlay

A separate annotation file can be loaded as overlay for convenience, e.g. to compare annotations.

  1. load another annotation file with the "Overlay" button
  • (optional) switch its visibility with the "Show overlay" checkbox
  • (optional) change the contour colour of the overlay shapes with the "Colours" button

Change colours

Clicking on the "Colours" button opens the Colours widget where you can set the annotation and overlay colours.

  1. select a colour from the drop-down list either next to the text label "overlay" or "annotation"
  2. click the "Ok" button to apply changes
  • contour colour of shapes on the annotation shapes layer (named "ROI") that already have a class label assigned to them will not be updated to the new annotation colour, only those not having a class label (the class label can be displayed with the "display text" checkbox on the layer controls panel as objectID:(classLabel) e.g. 1:(0) for the first object)
  • contour colour of shapes on the overlay shapes layer (named "overlay") will all have the overlay colour set, regardless of any existing class information saved to the annotation file loaded as overlay

Demo scripts

Run a demo of napari-annotatorj with sample data: a small 3-channel RGB image as original image and an ImageJ roi.zip file as annotations loaded.

    # from the napari-annotatorj folder
	python src/napari_annotatorj/load_imagej_roi.py

Alternatively, you can startup the napari-annotatorj plugin by running

    # from the napari-annotatorj folder
	python src/napari_annotatorj/startup_annotatorj.py

Configure model folder

The Contour assist mode imports a pre-trained Keras model from a folder named models under exactly the path napari_annotatorj. This is automatically created on the first startup in your user folder:

  • C:\Users\Username\.napari_annotatorj on Windows
  • \home\username\.napari_annotatorj on Linux

A pre-trained model for nucleus segmentation is automatically downloaded from the GitHub repository of the ImageJ version of AnnotatorJ. The model will be saved to [your user folder]\.napari_annotatorj\models\model_real.h5. This location is printed to the console (command prompt or powershell on Windows, terminal on Linux).

(deprecated) When bulding from source the model folder is located at path\to\napari-annotatorj\src\napari_annotatorj\models whereas installing from pypi it is located at path\to\virtualenv\Lib\site-packages\napari_annotatorj\models.

The model must be in either of these file formats:

  • config .json file + weights file: model_real.json and model_real_weights.h5
  • combined weights file: model_real.hdf5

You can also train a new model on your own data in e.g. Python and save it with this code block:

	# save model as json
	model_json=model.to_json()
	with open(‘model_real.json’, ‘w’) as f:
		f.write(model_json)
	
	# save weights too
	model.save_weights(‘model_real_weights.h5’)

This configuration will change in the next release to allow model browse and custom model name in an options widget.

Setting device for deep learning model prediction

The Contour assist mode uses a pre-trained U-Net model for suggesting contours based on a lazily initialized contour drawn by the user. The default configuration loads and runs the model on the CPU so all users can run it. It is possible to switch to GPU if you have:

  • a CUDA-capable GPU in your computer
  • nVidia's CUDA toolkit + cuDNN installed

See installation guide on nVidia's website according to your system.

To switch to GPU utilization, edit _dock_widget.py and set to the device you would like to use. Valid values are 'cpu','0','1','2',.... The default value is cpu. The default GPU device is 0 if your system has any CUDA-capable GPU. If the device you set cannot be found or utilized by the code, it will fall back to cpu. An informative message is printed to the console upon plugin startup.

License

Distributed under the terms of the BSD-3 license, "napari-annotatorj" is free and open source software.

Getting help

If you experience any issues or have questions, feel free to open an issue on GitHub.

How to cite

Réka Hollandi, Ákos Diósdi, Gábor Hollandi, Nikita Moshkov, Péter Horváth (2020): “AnnotatorJ: an ImageJ plugin to ease hand-annotation of cellular compartments”, Molecular Biology of the Cell, Vol. 31, No. 20, 2179-2186, https://doi.org/10.1091/mbc.E20-02-0156

Version:

  • 0.0.8

Last updated:

  • 14 December 2023

First released:

  • 26 May 2022

License:

Supported data:

  • Information not submitted

Open extension:

Save extension:

Save layers:

GitHub activity:

  • Stars: 9
  • Forks: 0
  • Issues + PRs: 2

Python versions supported:

Operating system:

Requirements:

  • napari
  • napari-plugin-engine >=0.1.4
  • numpy
  • roifile
  • scikit-image
  • opencv-python >=4.5.5
  • keras
  • tensorflow >=2.5.0
  • tifffile
  • imagecodecs
  • tqdm
  • pyqtgraph