Yung-Hong Sun, Jianwei Ke, Jayer Fernandes, Jiangang Chen, Hongrui Jiang, Yu Hen Hu
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引用次数: 0
Abstract
EasyVis is an emerging immersive 3D laparoscopic visualization system for improving the efficiency of laparoscopic surgery. It integrates multiple micro-cameras and light sources with the surgical ports to provide intra-abdominal stereo vision of surgery at a desired viewpoint. In this work, we develop a visualization algorithm using the EasyVis micro-camera array assembly in a laparoscopic surgery training box environment with simplified training tasks to validate the feasibility of this novel technology. Since most laparoscopic surgical tools are rigid-body objects, their 3D shape may be acquired offline. We developed 2D object detection and track algorithms to acquire the 2D pose of each object and a 3D fusion algorithm to estimate and track the 3D pose of each object using estimated 2D poses. Then, together with the acquired 3D model of each object, we are able to render each object at a desired view using the 3D surface model (acquired offline) and images acquired from individual micro-cameras. In addition to the foreground rigid objects, the background 3D model is acquired using structured lights and structure from motion. The background is assumed to be slowly varying compared to the rapid motion of the foreground objects. As such, the background 3D model needs to be updated only occasionally. Our rendering algorithm is capable of integrating the foreground and background 3D models to facilitate image-based rendering from a desirable viewing angle. We performed experiments to validate the accuracy and quality of the rendered images.
EasyVis 是一种新兴的沉浸式 3D 腹腔镜可视系统,用于提高腹腔镜手术的效率。它将多个微型摄像头和光源与手术端口集成在一起,以所需视角提供腹腔内手术立体视觉。在这项工作中,我们利用 EasyVis 微型摄像头阵列组件在腹腔镜手术训练箱环境中开发了一种可视化算法,并简化了训练任务,以验证这项新技术的可行性。由于大多数腹腔镜手术工具都是刚体物体,因此可以离线获取它们的三维形状。我们开发了二维物体检测和跟踪算法来获取每个物体的二维姿态,并开发了三维融合算法,利用估计的二维姿态来估计和跟踪每个物体的三维姿态。然后,连同获取的每个物体的三维模型,我们能够利用(离线获取的)三维表面模型和从单个微型摄像头获取的图像,在所需视角渲染每个物体。除了前景刚性物体外,我们还利用结构光和运动结构获取背景三维模型。与前景物体的快速运动相比,假定背景是缓慢变化的。因此,背景 3D 模型只需偶尔更新。我们的渲染算法能够整合前景和背景三维模型,以便从理想的视角进行基于图像的渲染。我们通过实验验证了渲染图像的准确性和质量。
期刊介绍:
Updates in Surgery (UPIS) has been founded in 2010 as the official journal of the Italian Society of Surgery. It’s an international, English-language, peer-reviewed journal dedicated to the surgical sciences. Its main goal is to offer a valuable update on the most recent developments of those surgical techniques that are rapidly evolving, forcing the community of surgeons to a rigorous debate and a continuous refinement of standards of care. In this respect position papers on the mostly debated surgical approaches and accreditation criteria have been published and are welcome for the future.
Beside its focus on general surgery, the journal draws particular attention to cutting edge topics and emerging surgical fields that are publishing in monothematic issues guest edited by well-known experts.
Updates in Surgery has been considering various types of papers: editorials, comprehensive reviews, original studies and technical notes related to specific surgical procedures and techniques on liver, colorectal, gastric, pancreatic, robotic and bariatric surgery.
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