Skip to content

Pixel segmentation of roads from dashboard camera using Fully Convolutional Network

License

Notifications You must be signed in to change notification settings

DhruvaKumar/CarND-Semantic-Segmentation

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

48 Commits
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

Semantic Segmentation

The goal of this project is to perform semantic segmentation on images to label pixels of a road using a Fully Convolutional Network. Semantic segmentation is the task of finding what's in an image at the pixel level. It can be used by autonomous cars for scene understanding. For example, infering the drivable surfaces in an image (road) or objects to avoid (other vehicles, pedestrians) at a fine resolution.

Setup

Dataset

Download the Kitti Road dataset from here. Extract the dataset in the data folder. This will create the folder data_road with all the training and test images.

Pretrained VGG model

helper.py downloads the pretrained frozen vgg model if it doesn't exist. Note that it's already convolutionalized, i.e, the fully connected layers have been replaced by convolutional layers.

Dependencies

conda env create -f environment.yml

Run

python main.py

Implementation

FCN8 from Fully Convolutional Networks for Semantic Segmentation is implemented and trained end to end. A VGG16 network pretrained on ImageNet is used as the encoder network. The final classification layer is removed. Fully connected layers are replaced by convolutional layers by using kernels covering the entire input region to output spatial maps. More explanation about the conversion can be found here. 1x1 convolutions are used to output num_classes as the channel dimensions. num_classes here is 2: road and non-road. It's then upsampled to the original size of the image. Upsampling is done by using transposed convolutional layers. Skip connections are used to combine semantic information from deep coarse layers with location information from shallow fine layers (1x1 convolutionalized pool3 and pool4 layers). Before this, pool3 and pool4 layers are scaled as mentioned by the authors in their github repo. The loss function is the sum of the cross entropy loss between the pixel predictions and ground truth and L2 regularization loss of the decoder kernels. The network is trained with an Adam optimizer with a fixed learning rate of 1e-3 for 50 epochs.

Results

alt text alt text alt text alt text alt text alt text alt text alt text alt text alt text alt text alt text alt text alt text alt text alt text alt text alt text

References

Releases

No releases published

Packages

No packages published