wdika
/

REC_LPDNet_CC359_12_channel_poisson2d_5x_10x_NNEstimationCSM

+---
+language:
+- en
+license: apache-2.0
+library_name: atommic
+datasets:
+- CC359
+thumbnail: null
+tags:
+- image-reconstruction
+- LPDNet
+- ATOMMIC
+- pytorch
+model-index:
+- name: REC_LPDNet_CC359_12_channel_poisson2d_5x_10x_NNEstimationCSM
+  results: []
+---
+## Model Overview
+Learned Primal Dual Network (LPDNet) for 5x & 10x accelerated MRI Reconstruction on the CC359 dataset.
+## ATOMMIC: Training
+To train, fine-tune, or test the model you will need to install [ATOMMIC](https://github.com/wdika/atommic). We recommend you install it after you've installed latest Pytorch version.
+```
+pip install atommic['all']
+```
+## How to Use this Model
+The model is available for use in ATOMMIC, and can be used as a pre-trained checkpoint for inference or for fine-tuning on another dataset.
+Corresponding configuration YAML files can be found [here](https://github.com/wdika/atommic/tree/main/projects/REC/CC359/conf).
+### Automatically instantiate the model
+```base
+pretrained: true
+checkpoint: https://huggingface.co/wdika/REC_LPDNet_CC359_12_channel_poisson2d_5x_10x_NNEstimationCSM/blob/main/REC_LPDNet_CC359_12_channel_poisson2d_5x_10x_NNEstimationCSM.atommic
+mode: test
+```
+### Usage
+You need to download the CC359 dataset to effectively use this model. Check the [CC359](https://github.com/wdika/atommic/blob/main/projects/REC/CC359/README.md) page for more information.
+## Model Architecture
+```base
+model:
+  model_name: LPDNet
+  num_primal: 5
+  num_dual: 5
+  num_iter: 5
+  primal_model_architecture: UNET
+  primal_in_channels: 2
+  primal_out_channels: 2
+  primal_unet_num_filters: 16
+  primal_unet_num_pool_layers: 2
+  primal_unet_dropout_probability: 0.0
+  primal_unet_padding_size: 11
+  primal_unet_normalize: true
+  dual_model_architecture: UNET
+  dual_in_channels: 2
+  dual_out_channels: 2
+  dual_unet_num_filters: 16
+  dual_unet_num_pool_layers: 2
+  dual_unet_dropout_probability: 0.0
+  dual_unet_padding_size: 11
+  dual_unet_normalize: true
+  dimensionality: 2
+  reconstruction_loss:
+    l1: 0.1
+    ssim: 0.9
+  estimate_coil_sensitivity_maps_with_nn: true
+```
+## Training
+```base
+  optim:
+    name: adamw
+    lr: 1e-4
+    betas:
+      - 0.9
+      - 0.999
+    weight_decay: 0.0
+    sched:
+        name: CosineAnnealing
+        min_lr: 0.0
+        last_epoch: -1
+        warmup_ratio: 0.1
+trainer:
+  strategy: ddp_find_unused_parameters_false
+  accelerator: gpu
+  devices: 1
+  num_nodes: 1
+  max_epochs: 20
+  precision: 16-mixed
+  enable_checkpointing: false
+  logger: false
+  log_every_n_steps: 50
+  check_val_every_n_epoch: -1
+  max_steps: -1
+```
+## Performance
+To compute the targets using the raw k-space and the chosen coil combination method, accompanied with the chosen coil sensitivity maps estimation method, you can use [targets](https://github.com/wdika/atommic/tree/main/projects/REC/CC359/conf/targets) configuration files.
+Evaluation can be performed using the [evaluation](https://github.com/wdika/atommic/blob/main/tools/evaluation/reconstruction.py) script for the reconstruction task, with --evaluation_type per_slice.
+Results
+-------
+Evaluation against RSS targets
+------------------------------
+5x: MSE = 0.001668 +/- 0.001584 NMSE = 0.02567 +/- 0.0265 PSNR = 28.26 +/- 4.222 SSIM = 0.8493 +/- 0.07524
+10x: MSE = 0.002367 +/- 0.002247 NMSE = 0.03687 +/- 0.03859 PSNR = 26.73 +/- 4.229 SSIM = 0.8096 +/- 0.09866
+## Limitations
+This model was trained on the CC359 using a UNet coil sensitivity maps estimation and might differ from the results reported on the challenge leaderboard.
+## References
+[1] [ATOMMIC](https://github.com/wdika/atommic)
+[2] Beauferris, Y., Teuwen, J., Karkalousos, D., Moriakov, N., Caan, M., Yiasemis, G., Rodrigues, L., Lopes, A., Pedrini, H., Rittner, L., Dannecker, M., Studenyak, V., Gröger, F., Vyas, D., Faghih-Roohi, S., Kumar Jethi, A., Chandra Raju, J., Sivaprakasam, M., Lasby, M., … Souza, R. (2022). Multi-Coil MRI Reconstruction Challenge—Assessing Brain MRI Reconstruction Models and Their Generalizability to Varying Coil Configurations. Frontiers in Neuroscience, 16. https://doi.org/10.3389/fnins.2022.919186