Spring 2021
CIG is looking for motivated WashU students for the following projects. We have a history of mentoring undergraduate and graduate students interested in research, with many of our alumni becoming PhD students in top programs (including WashU) and many projects leading to publications in top venues (see below). If you are interested in a given project, please apply by emailing your resume and a short description of your interests to the project supervisor.
Deep learning for quantitative brain imaging
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Status: reserved (Eddie Chandler, Flora Sun) Description: Quantitative brain imaging is extensively used for early detection of neurodegenerative diseases such as Alzheimer disease and Dementia. This project seeks to build on the latest progress in self-supervised deep learning to enable the next generation algorithms that are robust to noise and other artifacts. This project is well-suited for those students interested in learning advanced concepts in deep learning and imaging. Supervision: Xiaojian Xu (xiaojianxu@wustl.edu), Ulugbek Kamilov Areas: Medical Imaging, Deep Learning |
Deep learning for diagnosis of post-traumatic elbow disease
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Status: reserved (Yanpeng Yuan) Description: Deep learning may revolutionize the study of musculoskeletal conditions by automating the evaluation pipeline. This project seeks to develop tissue and modality-specific DL algorithms for automatic evaluation of disease stage and explore multi-modal in post-traumatic elbow conditions using histology, computed tomography, and magnetic resonance imaging. This project is in collaboration with the Musculoskeletal Soft Tissue Laboratory. Supervision: Weijie Gan (weijie.gan@wustl.edu), Michael David, Spencer Lake, Ulugbek Kamilov Areas: Image Analysis, Deep Learning |
Low-complexity learning for large-scale imaging
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Status: reserved (Ziwen Wang) Description: Model-based deep learning refers to a new family of methods that integrate both physics-based and trainable parameters within a single neural network. For many large-scale applications, computing gradients of such networks via backpropagation is infeasible due to the memory limitations of GPUs. This project seeks to address this issue by designing memory-efficient architectures obtained by trading off computation storage and computational complexity. We will consider large-scale biomedical imaging applications. Supervision: Jiaming Liu (jiaming.liu@wustl.edu), Ulugbek Kamilov Areas: Deep Learning, Algorithm Design |
Tunable deep learning for computational imaging
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Status: reserved (Ann Zhou) Description: Deep learning has led to a paradigm shift in computational imaging. In this project, we will explore the topic of tunable deep learning, where the goal is to design techniques that enable us to adjust convolutional neural networks without retraining them. We will explore the applications of the techniques in biomedical imaging. Supervision: Xiaojian Xu (xiaojianxu@wustl.edu), Ulugbek Kamilov Areas: Deep Learning, Image Restoration |
Synthesizing high-resolution videos using deep learning
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Status: reserved (Wentao Shangguan) Description: Video reconstruction is aimed to restore clear videos from corrupted observations, where state-of-the-art methods have achieved promising performance via supervised deep learning technologies. However, those methods require ground-truth videos, which may be inaccessible in some cases. Our goal is to develop a novel video reconstruction algorithm without the need of ground-truth. Supervision: Yu Sun (sun.yu@wustl.edu), Ulugbek Kamilov Areas: Deep Learning, Low-Level and Physics-Based Vision |
Accurate calibration of coil sensitivities in MRI
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Status: reserved (Yuyang Hu) Description: Parallel MR image reconstruction yields optimal results when the coil sensitivity maps are accurately known. Unfortunately, in practical scenarios, obtaining accurate estimates of the sensitivity maps is not possible. In this project, we explore the potential of deep learning to enable accurate estimation of coil sensitivity maps. Supervision: Weijie Gan (weijie.gan@wustl.edu), Ulugbek Kamilov Areas: Deep Learning, Image Restoration |
Next generation robust learning algorithms
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Status: reserved (Renhao Liu) Description: Imposing mathematical properties to convolutional neural networks is an active area of research. In this project, we will specifically focus on training CNNs that are Lipschitz continuous. The application of such neural nets include computational imaging, generative models, and robustness in machine learning. Supervision: Yu Sun (sun.yu@wustl.edu), Ulugbek Kamilov Areas: Deep Learning, Large-Scale Optimization |
Fall 2020
- Deep Learning for quantitative brain imaging (E. Chandler, X. Xu, Y. Sun, and U. S. Kamilov)
- Cycle GAN for quantitative MRI (Y. Li, X. Xu, and U. S. Kamilov)
- Training robust convolutional neural networks (R. Liu, Y. Sun, and U. S. Kamilov)
- Implementing CNNs with Tensorflow 2.0 (Z. Wang, Y. Sun, and U. S. Kamilov)
- Autocalibration for regularization by denoising (M. Xie, Y. Sun, and U. S. Kamilov)
Spring 2020
- Machine learning for 4D MRI (W. Gan, H. An, U. S. Kamilov)
- Proximal Optimization for Computerized Tomography (R. Schurz, J. Liu, U. S. Kamilov)
- End-to-End Training of VAE-GAN Priors (G. Meng, J. Liu, U. S. Kamilov)
- Design of GAN Prios for Iterative Algorithms (A. Bani, J. Liu, U. S. Kamilov)
- Recovery Experiments for Deep Learning (J. Liu, Y. Sun, U. S. Kamilov)
- Autocalibration for Regularization by Denoising (M. Xie, Y. Sun, and U. S. Kamilov)
- Stochastic Algorithms using Deep Priors (Z. Wu, Y. Sun, U. S. Kamilov)
- Fast Automatic Focal Plane Selection for Brightfield Microscopy using Machine Learning (Y. Song, X. Xu, N. Laird, Z. Pincus, U. S. Kamilov)
- Nonlocal Learning for Image Restoration (Y. Li, X. Xu, U. S. Kamilov)
- Motion-artifact Correction in Quantitative MRI (H. Tang, X. Xu, U. S. Kamilov)
Fall 2019
- Motion artifact reduction in quantitative brain MRI (N. Woythaler, X. Xu, U. S. Kamilov)
- Large-Scale Optimization for Computational Imaging (Y. Jia, U. S. Kamilov)
- Generative Adversarial Networks for Image Restoration (R. Suzuki, X. Xu, U. S. Kamilov)
- Adversarially robust classifiers for image reconstruction (E. Tang, X. Xu, U. S. Kamilov)
- Stochastic Algorithms using Deep Priors (Z. Wu, Y. Sun, U. S. Kamilov)
- Asynchronous large-scale optimization for imaging (Y. Sun, Y. Sun, U. S. Kamilov)
- Next generation Cryo-EM imaging (M. Xie, Y. Sun, U. S. Kamilov)
- Computational methods for quantitative brain MR imaging (M. Torop, Y. Sun, U. S. Kamilov)
Spring 2019
- Deep Single-Molecule Super-Resolution Imaging (S. Xu, Y. Sun, H. Mazidi, M. Lew, U. S. Kamilov)
- Learning for material imaging with light (Z. Wu, Y. Sun, U. S. Kamilov)
- Regularization with ConvNets (J. Liu, Y. Sun, U. S. Kamilov)
Fall 2018
- Regularization with ConvNets (J. Liu, Y. Sun, U. S. Kamilov)
- Learning for 3D computational imaging (W. Gan, X. Xu, U. S. Kamilov)
- Convolutional dictionary learning for image reconstruction (F. Long, X. Xu, U. S. Kamilov)
- Unsupervised deep image learning (H. Zou, Y. Sun, U. S. Kamilov)
- Distributed algorithms for nonconvex stochastic optimization (M. Abijaoude, U. S. Kamilov)
- Image restoration with GANs (F. Zhai, Y. Sun, U. S. Kamilov)
- Learning for MRI (J. Xing, X. Xu, U. S. Kamilov)
- Learning for material imaging with light (Z. Wu, Y. Sun, U. S. Kamilov)
- Dictionary Learning for Fourier Ptychographic Microscopy (S. Xu, X. Xu, U. S. Kamilov)