It's the project which train neural net to detect dark digits on light background. Then neural net converted to verilog HDL representation using several techniques to reduce needed resources on FPGA and increase speed of processing. Code is production ready to use in real device. It can be easily extended to be used with detection of other objects with different neural net structure.
Python 3.5, Tensorflow 1.4.0, Keras 2.1.3
- python r01_train_neural_net_and_prepare_initial_weights.py
- python r02_rescale_weights_to_use_fixed_point_representation.py
- python r03_find_optimal_bit_for_weights.py
- python r04_verilog_generator_grayscale_file.py
- python r05_verilog_generator_neural_net_structure.py
Verilog already added in repository in ''verilog'' folder. It has everything you need including all code to interact with camera or screen. Neural net verilog description is located in ''verliog/code/neuroset'' folder.
To recreate the device you need 3 components:
- De0Nano board (~80$)
- Camera OV7670 (~7$)
- Display ILI9341 (~7$)
- You need to connect pins with same name
- 'x' pins are not used
- You can see our connection variant on photo below
- Detailed guide how to use project in Altera Quartus.
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You can change constant num_conv = 2 in r05_verilog_generator_neural_net_structure.py to 1, 2 or 4 convolutional blocks which will work in parallel. More blocks will require more LE in FPGA, but increase the overall speed.
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Comparison table for different bit weights and number of convolution blocks below (red rows: unable to synthesize, due to Cyclone IV limitations).
You can find more detailed description here: