The experiment is based on Caffe.
It is also possible to conduct this experiment with TensorFlow, and the
instructions are on our working list.
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The original part annotation data is provided as the supplemental material of this paper". As detailed in Section 5.3 of our paper, the point cloud in the original dataset is relatively sparse and the normal information is missing. We convert the sparse point clouds to dense points with normal information and correct part annotation.
Here is one converted dataset for your convenience. Since we upgraded the octree format in this version of code, please run the following command to upgrade the lmdb:upgrade_octree_database.exe --node_label <input lmdb> <output lmdb>. And the dense point clouds withsegmentation labelscan be downloaded here. Again, before using them, upgrade with the following command:upgrade_points.exe --filenames <the txt file containing the filenames> --has_label 1. -
Run the
octree.exeto convert these point clouds to octree files. Then you can get the octree files, which also contains the segmentation label. -
Convert the dataset to a
lmdbdatabase. Since the segmentation label is contained in each octree file, the object label for each octree file can be set to any desirable value. And the object label is just ignored in the segmentation task. -
Download the protocol buffer files, which are contained in the folder
caffe/experiments. -
In the testing stage, the output label and probability of each finest leaf node can also be obtained. Specifically, open the file
segmentation_5.prototxt, uncomment line 458~485, set thebatch_sizein line 31 to 1, and run the following command to dump the result.caffe.exe test --model=segmentation_5.prototxt --weights=segmentation_5.caffemodel --gpu=0 --blob_prefix=feature/segmentation_5_test_ --binary_mode=false --save_seperately=true --iterations=[...]
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For CRF refinement, please refer to the code provided here.
We implement the HRNet within our O-CNN framework, and conduct the shape segmentation on PartNet. On the testing set of PartNet, we achieve an average IoU of 58.4, significantly better than PointNet (IoU: 35.6), PointNet++ (IoU: 42.5), SpiderCNN (IoU: 37.0), and PointCNN(IoU: 46.5). For more details, please refer to Section 4.3 of our paper on 3D Unsupervised Learning.
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Download PartNet according the provided instructions (about 100G). Then unzip the data to the folder
tensorflow/script/dataset/partnet_segmentation. -
Run the following script to convert the original data to
tfrecords. This process may take several hours to complete. For convenience, we also provide the convertedtfrecords(6.6G) here. Download and unzip the data to the foldertensorflow/script/dataset.cd tensorflow python data/seg_partnet.py -
Run the following script to train the network. The trained weights and logs can also be downloaded (6.6G) here.
cd script python run_seg_partnet_cmd.py
Follow the instructions below to train the HRNet based on our O-CNN framework and conduct the shape segmentation on ShapeNet Part.
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Change the working directory to
tensorflow/data. Run the following script to download the data and convert the data totfrecords.python seg_shapenet.py
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Change the working directory to
tensorflow/script. Run the following script to train the network.python run_seg_shapenet_cmd.py
Follow the instructions below to train a shallow SegNet used in our O-CNN paper, which consists of pooling and unpooling layers.
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Change the working directory to
tensorflow/data. Run the following script to download the data, then make a symbolic link to the folderpytorch/projects/dataset:python seg_shapenet.py ln -s `pwd`/../script/dataset/shapenet_segmentation `pwd`/../../pytorch/projects/data
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Change the working directory to
pytorch/projects. Run the following script to train the network.python segmentation.py --config configs/seg_shapenet.yaml