Application of Ghost-DeblurGAN to Fiducial Marker Detection

Feature extraction or localization based on the fiducial marker could fail due to motion blur in real-world robotic applications. To solve this problem, a lightweight generative adversarial network, named Ghost-DeblurGAN, for real-time motion deblurring is developed in this paper. Furthermore, on account that there is no existing deblurring benchmark for such task, a new large-scale dataset, YorkTag, is proposed that provides pairs of sharp/blurred images containing fiducial markers. With the proposed model trained and tested on YorkTag, it is demonstrated that when applied along with fiducial marker systems to motion-blurred images, Ghost-DeblurGAN improves the marker detection significantly. The datasets and codes used in this paper are available at: https://github.com/York-SDCNLab/Ghost-DeblurGAN.Comment: 6 pages, 6 figure

움직이는 단일 카메라를 이용한 3차원 복원과 디블러링, 초해상도 복원의 동시적 수행 기법

학위논문 (박사)-- 서울대학교 대학원 : 전기·컴퓨터공학부, 2013. 8. 이경무.영상 기반 3차원 복원은 컴퓨터 비전의 기본적인 연구 주제 가운데 하나로 최근 몇 년간 많은 발전이 있어왔다. 특히 자동 로봇을 위한 네비게이션 및 휴대 기기를 이용한 증강 현실 등에 널리 활용될 수 있는 단일 카메라를 이용한 3차원 복원 기법은 복원의 정확도, 복원 가능 범위 및 처리 속도 측면에서 많은 실용 가능성을 보여주고 있다. 그러나 그 성능은 여전히 조심스레 촬영된 높은 품질의 입력 영상에 대해서만 시험되고 있다. 움직이는 단일 카메라를 이용한 3차원 복원의 실제 동작 환경에서는 입력 영상이 화소 잡음이나 움직임에 의한 번짐 등에 의하여 손상될 수 있고, 영상의 해상도 또한 정확한 카메라 위치 인식 및 3차원 복원을 위해서는 충분히 높지 않을 수 있다. 많은 연구에서 고성능 영상 화질 향상 기법들이 제안되어 왔지만 이들은 일반적으로 높은 계산 비용을 필요로 하기 때문에 실시간 동작 능력이 중요한 단일 카메라 기반 3차원 복원에 사용되기에는 부적합하다. 본 논문에서는 보다 정확하고 안정된 복원을 위하여 영상 개선이 결합된 새로운 단일 카메라 기반 3차원 복원 기법을 다룬다. 이를 위하여 영상 품질이 저하되는 중요한 두 요인인 움직임에 의한 영상 번짐과 낮은 해상도 문제가 각각 점 기반 복원 및 조밀 복원 기법들과 결합된다. 영상 품질 저하를 포함한 영상 획득 과정은 카메라 및 장면의 3차원 기하 구조와 관측된 영상 사이의 관계를 이용하여 모델링 할 수 있고, 이러한 영상 품질 저하 과정을 고려함으로써 정확한 3차원 복원을 하는 것이 가능해진다. 또한, 영상 번짐 제거를 위한 번짐 커널 또는 영상의 초해상도 복원을 위한 화소 대응 정보 등이 3차원 복원 과정과 동시에 얻어지는것이 가능하여, 영상 개선이 보다 간편하고 빠르게 수행될 수 있다. 제안되는 기법은 3차원 복원과 영상 개선 문제를 동시에 해결함으로써 각각의 결과가 상호 보완적으로 향상된다는 점에서 그 장점을 가지고 있다. 본 논문에서는 실험적 평가를 통하여 제안되는 3차원 복원 및 영상 개선의 효과성을 입증하도록 한다.Vision-based 3D reconstruction is one of the fundamental problems in computer vision, and it has been researched intensively significantly in the last decades. In particular, 3D reconstruction using a single camera, which has a wide range of applications such as autonomous robot navigation and augmented reality, shows great possibilities in its reconstruction accuracy, scale of reconstruction coverage, and computational efficiency. However, until recently, the performances of most algorithms have been tested only with carefully recorded, high quality input sequences. In practical situations, input images for 3D reconstruction can be severely distorted due to various factors such as pixel noise and motion blur, and the resolution of images may not be high enough to achieve accurate camera localization and scene reconstruction results. Although various high-performance image enhancement methods have been proposed in many studies, the high computational costs of those methods prevent applying them to the 3D reconstruction systems where the real-time capability is an important issue. In this dissertation, novel single camera-based 3D reconstruction methods that are combined with image enhancement methods is studied to improve the accuracy and reliability of 3D reconstruction. To this end, two critical image degradations, motion blur and low image resolution, are addressed for both sparse reconstruction and dense 3D reconstruction systems, and novel integrated enhancement methods for those degradations are presented. Using the relationship between the observed images and 3D geometry of the camera and scenes, the image formation process including image degradations is modeled by the camera and scene geometry. Then, by taking the image degradation factors in consideration, accurate 3D reconstruction then is achieved. Furthermore, the information required for image enhancement, such as blur kernels for deblurring and pixel correspondences for super-resolution, is simultaneously obtained while reconstructing 3D scene, and this makes the image enhancement much simpler and faster. The proposed methods have an advantage that the results of 3D reconstruction and image enhancement are improved by each other with the simultaneous solution of these problems. Experimental evaluations demonstrate the effectiveness of the proposed 3D reconstruction and image enhancement methods.1. Introduction 2. Sparse 3D Reconstruction and Image Deblurring 3. Sparse 3D Reconstruction and Image Super-Resolution 4. Dense 3D Reconstruction and Image Deblurring 5. Dense 3D Reconstruction and Image Super-Resolution 6. Dense 3D Reconstruction, Image Deblurring, and Super-Resolution 7. ConclusionDocto

BALF: Simple and Efficient Blur Aware Local Feature Detector

Local feature detection is a key ingredient of many image processing and computer vision applications, such as visual odometry and localization. Most existing algorithms focus on feature detection from a sharp image. They would thus have degraded performance once the image is blurred, which could happen easily under low-lighting conditions. To address this issue, we propose a simple yet both efficient and effective keypoint detection method that is able to accurately localize the salient keypoints in a blurred image. Our method takes advantages of a novel multi-layer perceptron (MLP) based architecture that significantly improve the detection repeatability for a blurred image. The network is also light-weight and able to run in real-time, which enables its deployment for time-constrained applications. Extensive experimental results demonstrate that our detector is able to improve the detection repeatability with blurred images, while keeping comparable performance as existing state-of-the-art detectors for sharp images

Real-Time Magnetic Resonance Imaging

Real‐time magnetic resonance imaging (RT‐MRI) allows for imaging dynamic processes as they occur, without relying on any repetition or synchronization. This is made possible by modern MRI technology such as fast‐switching gradients and parallel imaging. It is compatible with many (but not all) MRI sequences, including spoiled gradient echo, balanced steady‐state free precession, and single‐shot rapid acquisition with relaxation enhancement. RT‐MRI has earned an important role in both diagnostic imaging and image guidance of invasive procedures. Its unique diagnostic value is prominent in areas of the body that undergo substantial and often irregular motion, such as the heart, gastrointestinal system, upper airway vocal tract, and joints. Its value in interventional procedure guidance is prominent for procedures that require multiple forms of soft‐tissue contrast, as well as flow information. In this review, we discuss the history of RT‐MRI, fundamental tradeoffs, enabling technology, established applications, and current trends