English | 中文
Convolutional Recurrent Neural Network (CRNN) integrates CNN feature extraction and RNN sequence modeling as well as transcription into a unified framework.
As shown in the architecture graph (Figure 1), CRNN firstly extracts a feature sequence from the input image via Convolutional Layers. After that, the image is represented by a squence extracted features, where each vector is associated with a receptive field on the input image. For futher process the feature, CRNN adopts Recurrent Layers to predict a label distribution for each frame. To map the distribution to text field, CRNN adds a Transcription Layer to translate the per-frame predictions into the final label sequence. [1]
Figure 1. Architecture of CRNN [1]
According to our experiments, the training (following the steps in Model Training) performance and evaluation (following the steps in Model Evaluation) accuracy are as follows:
| Model | Context | Backbone | Train Dataset | Model Params | Batch size per card | Graph train 8P (s/epoch) | Graph train 8P (ms/step) | Graph train 8P (FPS) | Avg Eval Accuracy | Recipe | Download |
|---|---|---|---|---|---|---|---|---|---|---|---|
| CRNN | D910x8-MS1.8-G | VGG7 | MJ+ST | 8.72 M | 16 | 2488.82 | 22.06 | 5802.71 | 82.03% | yaml | ckpt | mindir |
| CRNN | D910x8-MS1.8-G | ResNet34_vd | MJ+ST | 24.48 M | 64 | 2157.18 | 76.48 | 6694.84 | 84.45% | yaml | ckpt | mindir |
-
Detailed accuracy results for each benchmark dataset (IC03, IC13, IC15, IIIT, SVT, SVTP, CUTE):
Model Backbone IC03_860 IC03_867 IC13_857 IC13_1015 IC15_1811 IC15_2077 IIIT5k_3000 SVT SVTP CUTE80 Average CRNN VGG7 94.53% 94.00% 92.18% 90.74% 71.95% 66.06% 84.10% 83.93% 73.33% 69.44% 82.03% CRNN ResNet34_vd 94.42% 94.23% 93.35% 92.02% 75.92% 70.15% 87.73% 86.40% 76.28% 73.96% 84.45%
The inference performance is tested on Mindspore Lite, please take a look at Mindpore Lite Inference for more details.
| Device | Env | Model | Backbone | Params | Test Dataset | Batch size | Graph infer 1P (FPS) |
|---|---|---|---|---|---|---|---|
| Ascend310P | Lite2.0 | CRNN | ResNet34_vd | 24.48 M | IC15 | 1 | 361.09 |
| Ascend310P | Lite2.0 | CRNN | ResNet34_vd | 24.48 M | SVT | 1 | 274.67 |
Notes:
- Context: Training context denoted as {device}x{pieces}-{MS mode}, where mindspore mode can be G-graph mode or F-pynative mode with ms function. For example, D910x8-MS1.8-G is for training on 8 pieces of Ascend 910 NPU using graph mode based on Minspore version 1.8.
- To reproduce the result on other contexts, please ensure the global batch size is the same.
- The characters supported by model are lowercase English characters from a to z and numbers from 0 to 9. More explanation on dictionary, please refer to 4. Character Dictionary.
- The models are trained from scratch without any pre-training. For more dataset details of training and evaluation, please refer to Dataset Download & Dataset Usage section.
- The input Shapes of MindIR of CRNN_VGG7 and CRNN_ResNet34_vd are both (1, 3, 32, 100).
Please refer to the installation instruction in MindOCR.
Please download lmdb dataset for traininig and evaluation from here (ref: deep-text-recognition-benchmark). There're several zip files:
data_lmdb_release.zipcontains the entire datasets including training data, validation data and evaluation data.validation.zip: same as the validation/ within data_lmdb_release.zipevaluation.zip: same as the evaluation/ within data_lmdb_release.zip
Unzip the data_lmdb_release.zip, the data structure should be like
data_lmdb_release/
├── evaluation
│ ├── CUTE80
│ │ ├── data.mdb
│ │ └── lock.mdb
│ ├── IC03_860
│ │ ├── data.mdb
│ │ └── lock.mdb
│ ├── IC03_867
│ │ ├── data.mdb
│ │ └── lock.mdb
│ ├── IC13_1015
│ │ ├── data.mdb
│ │ └── lock.mdb
│ ├── ...
├── training
│ ├── MJ
│ │ ├── MJ_test
│ │ │ ├── data.mdb
│ │ │ └── lock.mdb
│ │ ├── MJ_train
│ │ │ ├── data.mdb
│ │ │ └── lock.mdb
│ │ └── MJ_valid
│ │ ├── data.mdb
│ │ └── lock.mdb
│ └── ST
│ ├── data.mdb
│ └── lock.mdb
└── validation
├── data.mdb
└── lock.mdb
Here we used the datasets under training/ folders for training, and the union dataset validation/ for validation. After training, we used the datasets under evaluation/ to evluation model accuracy.
Training: (total 14,442,049 samples)
- MJSynth (MJ)
- Train: 21.2 GB, 7224586 samples
- Valid: 2.36 GB, 802731 samples
- Test: 2.61 GB, 891924 samples
- SynthText (ST)
- Train: 16.0 GB, 5522808 samples
Validation:
- Valid: 138 MB, 6992 samples
Evaluation: (total 12,067 samples)
- CUTE80: 8.8 MB, 288 samples
- IC03_860: 36 MB, 860 samples
- IC03_867: 4.9 MB, 867 samples
- IC13_857: 72 MB, 857 samples
- IC13_1015: 77 MB, 1015 samples
- IC15_1811: 21 MB, 1811 samples
- IC15_2077: 25 MB, 2077 samples
- IIIT5k_3000: 50 MB, 3000 samples
- SVT: 2.4 MB, 647 samples
- SVTP: 1.8 MB, 645 samples
Data configuration for model training
To reproduce the training of model, it is recommended that you modify the configuration yaml as follows:
...
train:
...
dataset:
type: LMDBDataset
dataset_root: dir/to/data_lmdb_release/ # Root dir of training dataset
data_dir: training/ # Dir of training dataset, concatenated with `dataset_root` to be the complete dir of training dataset
# label_file: # Path of training label file, concatenated with `dataset_root` to be the complete path of training label file, not required when using LMDBDataset
...
eval:
dataset:
type: LMDBDataset
dataset_root: dir/to/data_lmdb_release/ # Root dir of validation dataset
data_dir: validation/ # Dir of validation dataset, concatenated with `dataset_root` to be the complete dir of validation dataset
# label_file: # Path of validation label file, concatenated with `dataset_root` to be the complete path of validation label file, not required when using LMDBDataset
...Data configuration for model evaluation
We use the dataset under evaluation/ as the benchmark dataset. On each individual dataset (e.g. CUTE80, IC03_860, etc.), we perform a full evaluation by setting the dataset's directory to the evaluation dataset. This way, we get a list of the corresponding accuracies for each dataset, and then the reported accuracies are the average of these values.
To reproduce the reported evaluation results, you can:
-
Option 1: Repeat the evaluation step for all individual datasets: CUTE80, IC03_860, IC03_867, IC13_857, IC131015, IC15_1811, IC15_2077, IIIT5k_3000, SVT, SVTP. Then take the average score.
-
Option 2: Put all the benchmark datasets folder under the same directory, e.g.
evaluation/. And use the scripttools/benchmarking/multi_dataset_eval.py.
- Evaluate on one specific dataset
For example, you can evaluate the model on dataset CUTE80 by modifying the config yaml as follows:
...
train:
# NO NEED TO CHANGE ANYTHING IN TRAIN SINCE IT IS NOT USED
...
eval:
dataset:
type: LMDBDataset
dataset_root: dir/to/data_lmdb_release/ # Root dir of evaluation dataset
data_dir: evaluation/CUTE80/ # Dir of evaluation dataset, concatenated with `dataset_root` to be the complete dir of evaluation dataset
# label_file: # Path of evaluation label file, concatenated with `dataset_root` to be the complete path of evaluation label file, not required when using LMDBDataset
...By running tools/eval.py as noted in section Model Evaluation with the above config yaml, you can get the accuracy performance on dataset CUTE80.
- Evaluate on multiple datasets under the same folder
Assume you have put all benckmark datasets under evaluation/ as shown below:
data_lmdb_release/
├── evaluation
│ ├── CUTE80
│ │ ├── data.mdb
│ │ └── lock.mdb
│ ├── IC03_860
│ │ ├── data.mdb
│ │ └── lock.mdb
│ ├── IC03_867
│ │ ├── data.mdb
│ │ └── lock.mdb
│ ├── IC13_1015
│ │ ├── data.mdb
│ │ └── lock.mdb
│ ├── ...
then you can evaluate on each dataset by modifying the config yaml as follows, and execute the script tools/benchmarking/multi_dataset_eval.py.
...
train:
# NO NEED TO CHANGE ANYTHING IN TRAIN SINCE IT IS NOT USED
...
eval:
dataset:
type: LMDBDataset
dataset_root: dir/to/data_lmdb_release/ # Root dir of evaluation dataset
data_dir: evaluation/ # Dir of evaluation dataset, concatenated with `dataset_root` to be the complete dir of evaluation dataset
# label_file: # Path of evaluation label file, concatenated with `dataset_root` to be the complete path of evaluation label file, not required when using LMDBDataset
...Apart from the dataset setting, please also check the following important args: system.distribute, system.val_while_train, common.batch_size, train.ckpt_save_dir, train.dataset.dataset_root, train.dataset.data_dir, train.dataset.label_file,
eval.ckpt_load_path, eval.dataset.dataset_root, eval.dataset.data_dir, eval.dataset.label_file, eval.loader.batch_size. Explanations of these important args:
system:
distribute: True # `True` for distributed training, `False` for standalone training
amp_level: 'O3'
seed: 42
val_while_train: True # Validate while training
drop_overflow_update: False
common:
...
batch_size: &batch_size 64 # Batch size for training
...
train:
ckpt_save_dir: './tmp_rec' # The training result (including checkpoints, per-epoch performance and curves) saving directory
dataset_sink_mode: False
dataset:
type: LMDBDataset
dataset_root: dir/to/data_lmdb_release/ # Root dir of training dataset
data_dir: training/ # Dir of training dataset, concatenated with `dataset_root` to be the complete dir of training dataset
# label_file: # Path of training label file, concatenated with `dataset_root` to be the complete path of training label file, not required when using LMDBDataset
...
eval:
ckpt_load_path: './tmp_rec/best.ckpt' # checkpoint file path
dataset_sink_mode: False
dataset:
type: LMDBDataset
dataset_root: dir/to/data_lmdb_release/ # Root dir of validation/evaluation dataset
data_dir: validation/ # Dir of validation/evaluation dataset, concatenated with `dataset_root` to be the complete dir of validation/evaluation dataset
# label_file: # Path of validation/evaluation label file, concatenated with `dataset_root` to be the complete path of validation/evaluation label file, not required when using LMDBDataset
...
loader:
shuffle: False
batch_size: 64 # Batch size for validation/evaluation
...Notes:
- As the global batch size (batch_size x num_devices) is important for reproducing the result, please adjust
batch_sizeaccordingly to keep the global batch size unchanged for a different number of GPUs/NPUs, or adjust the learning rate linearly to a new global batch size.
- Distributed Training
It is easy to reproduce the reported results with the pre-defined training recipe. For distributed training on multiple Ascend 910 devices, please modify the configuration parameter distribute as True and run
# distributed training on multiple GPU/Ascend devices
mpirun --allow-run-as-root -n 8 python tools/train.py --config configs/rec/crnn/crnn_resnet34.yaml- Standalone Training
If you want to train or finetune the model on a smaller dataset without distributed training, please modify the configuration parameterdistribute as False and run:
# standalone training on a CPU/GPU/Ascend device
python tools/train.py --config configs/rec/crnn/crnn_resnet34.yamlThe training result (including checkpoints, per-epoch performance and curves) will be saved in the directory parsed by the arg ckpt_save_dir. The default directory is ./tmp_rec.
To evaluate the accuracy of the trained model, you can use eval.py. Please set the checkpoint path to the arg ckpt_load_path in the eval section of yaml config file, set distribute to be False, and then run:
python tools/eval.py --config configs/rec/crnn/crnn_resnet34.yaml
To transform the groud-truth text into label ids, we have to provide the character dictionary where keys are characters and values are IDs. By default, the dictionary is "0123456789abcdefghijklmnopqrstuvwxyz", which means id=0 will correspond to the charater "0". In this case, the dictionary only considers numbers and lowercase English characters, excluding spaces.
There are some built-in dictionaries, which are placed in mindocr/utils/dict/, and you can choose the appropriate dictionary to use.
en_dict.txtis an English dictionary containing 94 characters, including numbers, common symbols, and uppercase and lowercase English letters.ch_dict.txtis a Chinese dictionary containing 6623 characters, including commonly used simplified and traditional Chinese, numbers, common symbols, uppercase and lowercase English letters.
You can also customize a dictionary file (***.txt) and place it under mindocr/utils/dict/, the format of the dictionary file should be a .txt file with one character per line.
To use a specific dictionary, set the parameter character_dict_path to the path of the dictionary, and change the parameter num_classes to the corresponding number, which is the number of characters in the dictionary + 1.
Notes:
- You can include the space character by setting the parameter
use_space_charin configuration yaml to True. - Remember to check the value of
dataset->transform_pipeline->RecCTCLabelEncode->lowerin the configuration yaml. Set it to False if you prefer case-sensitive encoding.
Currently, this model supports multilingual recognition and provides pre-trained models for different languages. Details are as follows:
We use a public Chinese text benchmark dataset Benchmarking-Chinese-Text-Recognition for CRNN training and evaluation.
For detailed instruction of data preparation and yaml configuration, please refer to ch_dataeset.
To train with the prepared datsets and config file, please run:
mpirun --allow-run-as-root -n 4 python tools/train.py --config configs/rec/crnn/crnn_resnet34_ch.yamlAfter training, evaluation results on the benchmark test set are as follows, where we also provide the model config and pretrained weights.
| Model | Language | Context | Backbone | Scene | Web | Document | Train T. | FPS | Recipe | Download |
|---|---|---|---|---|---|---|---|---|---|---|
| CRNN | Chinese | D910x4-MS1.10-G | ResNet34_vd | 60.45% | 65.95% | 97.68% | 647 s/epoch | 1180 | crnn_resnet34_ch.yaml | ckpt | mindir |
Notes:
- The input shape for exported MindIR file in the download link is (1, 3, 32, 320).
You can train models for different languages with your own custom datasets. Loading the pretrained Chinese model to finetune on your own dataset usually yields better results than training from scratch. Please refer to the tutorial Training Recognition Network with Custom Datasets.
To inference with MindSpot Lite on Ascend 310, please refer to the tutorial MindOCR Inference. In short, the whole process consists of the following steps:
1. Model Export
Please download the exported MindIR file first, or refer to the Model Export tutorial and use the following command to export the trained ckpt model to MindIR file:
python tools/export.py --model_name_or_config crnn_resnet34 --data_shape 32 100 --local_ckpt_path /path/to/local_ckpt.ckpt
# or
python tools/export.py --model_name_or_config configs/rec/crnn/crnn_resnet34.yaml --data_shape 32 100 --local_ckpt_path /path/to/local_ckpt.ckptThe data_shape is the model input shape of height and width for MindIR file. The shape value of MindIR in the download link can be found in Notes under results table.
2. Environment Installation
Please refer to Environment Installation tutorial to configure the MindSpore Lite inference environment.
3. Model Conversion
Please refer to Model Conversion,
and use the converter_lite tool for offline conversion of the MindIR file.
4. Inference
Assuming that you obtain output.mindir after model conversion, go to the deploy/py_infer directory, and use the following command for inference:
python infer.py \
--input_images_dir=/your_path_to/test_images \
--rec_model_path=your_path_to/output.mindir \
--rec_model_name_or_config=../../configs/rec/crnn/crnn_resnet34.yaml \
--res_save_dir=results_dir[1] Baoguang Shi, Xiang Bai, Cong Yao. An End-to-End Trainable Neural Network for Image-based Sequence Recognition and Its Application to Scene Text Recognition. arXiv preprint arXiv:1507.05717, 2015.