Pinned Repositories
-python-BAT-
针对常见的BAT公司中的大数据面试和笔试问题,列出解决思路,并使用python来实现
3D-CNN-for-Autism-Diagnosis
3d-DenseNet
3D Dense Connected Convolutional Network (3D-DenseNet for action recognition)
3DUnetCNN
Keras 3D U-Net Convolution Neural Network (CNN) designed for medical image segmentation
cardiac-segmentation
Right Ventricle Cardiac MRI Segmentation:2D U-net,2D Dilated u-nets, 2D Dilated densenets: multiple scales at once
cnn4brca
Using Convolutional Neural Networks (CNN) for Semantic Segmentation of Breast Cancer Lesions (BRCA). Master's thesis
ComputerVision-list
materials for deep learning and computer vision
end2end-all-conv
End-to-end training for breast cancer diagnosis using deep all convolutional networks
ild-cnn
Interstitial lung disease project
Volumetric-ConvNet-for-prostate-segmentation
Network architecture for "Volumetric ConvNets with Mixed Residual Connections for Automated Prostate Segmentation from 3D MR Images"
ChelovekHe's Repositories
ChelovekHe/Automated-Lesion-Detection-Public
ChelovekHe/awesome-shell
A curated list of awesome command-line frameworks, toolkits, guides and gizmos. Inspired by awesome-php.
ChelovekHe/deep_learning_papers
A place to collect papers that are related to deep learning and computational biology
ChelovekHe/Emotion-Detection-in-Videos
The aim of this work is to recognize the six emotions (happiness, sadness, disgust, surprise, fear and anger) based on human facial expressions extracted from videos. To achieve this, we are considering people of different ethnicity, age and gender where each one of them reacts very different when they express their emotions. We collected a data set of 149 videos that included short videos from both, females and males, expressing each of the the emotions described before. The data set was built by students and each of them recorded a video expressing all the emotions with no directions or instructions at all. Some videos included more body parts than others. In other cases, videos have objects in the background an even different light setups. We wanted this to be as general as possible with no restrictions at all, so it could be a very good indicator of our main goal. The code detect_faces.py just detects faces from the video and we saved this video in the dimension 240x320. Using this algorithm creates shaky videos. Thus we then stabilized all videos. This can be done via a code or online free stabilizers are also available. After which we used the stabilized videos and ran it through code emotion_classification_videos_faces.py. in the code we developed a method to extract features based on histogram of dense optical flows (HOF) and we used a support vector machine (SVM) classifier to tackle the recognition problem. For each video at each frame we extracted optical flows. Optical flows measure the motion relative to an observer between two frames at each point of them. Therefore, at each point in the image you will have two values that describes the vector representing the motion between the two frames: the magnitude and the angle. In our case, since videos have a resolution of 240x320, each frame will have a feature descriptor of dimensions 240x320x2. So, the final video descriptor will have a dimension of #framesx240x320x2. In order to make a video comparable to other inputs (because inputs of different length will not be comparable with each other), we need to somehow find a way to summarize the video into a single descriptor. We achieve this by calculating a histogram of the optical flows. This is, separate the extracted flows into categories and count the number of flows for each category. In more details, we split the scene into a grid of s by s bins (10 in this case) in order to record the location of each feature, and then categorized the direction of the flow as one of the 8 different motion directions considered in this problem. After this, we count for each direction the number of flows occurring in each direction bin. Finally, we end up with an s by s by 8 bins descriptor per each frame. Now, the summarizing step for each video could be the average of the histograms in each grid (average pooling method) or we could just pick the maximum value of the histograms by grid throughout all the frames on a video (max pooling For the classification process, we used support vector machine (SVM) with a non linear kernel classifier, discussed in class, to recognize the new facial expressions. We also considered a Naïve Bayes classifier, but it is widely known that svm outperforms the last method in the computer vision field. A confusion matrix can be made to plot results better.
ChelovekHe/faster_r_cnn
theano Implementation of "Faster R-CNN: Towards Real-Time Object Detection with Region Proposal Networks"
ChelovekHe/ImageLabel
图像标注工具 Image Label Tool
ChelovekHe/kaggle
A collection of Kaggle solutions. Not very polished.
ChelovekHe/kaggle_diabetic_retinopathy
Fifth place solution of the Kaggle Diabetic Retinopathy competition.
ChelovekHe/landmark_py
Landmark with Regressition in Python (LBF(3000fps), ESR and SDM)
ChelovekHe/lasagne-draw
Implementation of the DRAW network in lasagne
ChelovekHe/lung-nodule-detection-caffe
ChelovekHe/my-awesome-awesomeness
Willard-yuan 自己使用的一些工具
ChelovekHe/OpenDL
屹立深度之巅
ChelovekHe/selective_search_3d
ChelovekHe/ShapeMatching
Shape-based image retrieval experiments
ChelovekHe/ShareTheJourney
ResearchKit app studying Breast Cancer, developed by Sage Bionetworks.
ChelovekHe/SimpleITKTutorialMICCAI2015
SimpleITK tutorial at the 2015 MICCAI conference
ChelovekHe/SimpleITKTutorialSPIE2016
A collection of Jupter Notebooks to be used as instructional material for SPIE 2016 course.
ChelovekHe/SketchRetrieval
A whole application of sketch retrieval written in matlab
ChelovekHe/TCIABrowser
3D Slicer module for browsing and downloading medical imaging collections from The Cancer Imaging Archive (TCIA).
ChelovekHe/Tube-Segmentation-Framework
A software for fast segmentation and centerline extraction of tubular structures (e.g. blood vessels and airways) from different modalities and organs using GPUs and OpenCL