{"title":"智能超声机器人:基于互信息的从少量演示中进行分离奖励学习","authors":"Zhongliang Jiang, Yuan Bi, Mingchuan Zhou, Ying Hu, Michael Burke, Nassir Navab","doi":"10.1177/02783649231223547","DOIUrl":null,"url":null,"abstract":"Ultrasound (US) imaging is widely used for biometric measurement and diagnosis of internal organs due to the advantages of being real-time and radiation-free. However, due to inter-operator variations, resulting images highly depend on the experience of sonographers. This work proposes an intelligent robotic sonographer to autonomously “explore” target anatomies and navigate a US probe to standard planes by learning from the expert. The underlying high-level physiological knowledge from experts is inferred by a neural reward function, using a ranked pairwise image comparison approach in a self-supervised fashion. This process can be referred to as understanding the “language of sonography.” Considering the generalization capability to overcome inter-patient variations, mutual information is estimated by a network to explicitly disentangle the task-related and domain features in latent space. The robotic localization is carried out in coarse-to-fine mode based on the predicted reward associated with B-mode images. To validate the effectiveness of the proposed reward inference network, representative experiments were performed on vascular phantoms (“line” target), two types of ex vivo animal organ phantoms (chicken heart and lamb kidney representing “point” target), and in vivo human carotids. To further validate the performance of the autonomous acquisition framework, physical robotic acquisitions were performed on three phantoms (vascular, chicken heart, and lamb kidney). The results demonstrated that the proposed advanced framework can robustly work on a variety of seen and unseen phantoms as well as in vivo human carotid data. Code: https://github.com/yuan-12138/MI-GPSR . Video: https://youtu.be/u4ThAA9onE0 .","PeriodicalId":501362,"journal":{"name":"The International Journal of Robotics Research","volume":"19 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-01-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Intelligent robotic sonographer: Mutual information-based disentangled reward learning from few demonstrations\",\"authors\":\"Zhongliang Jiang, Yuan Bi, Mingchuan Zhou, Ying Hu, Michael Burke, Nassir Navab\",\"doi\":\"10.1177/02783649231223547\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Ultrasound (US) imaging is widely used for biometric measurement and diagnosis of internal organs due to the advantages of being real-time and radiation-free. However, due to inter-operator variations, resulting images highly depend on the experience of sonographers. This work proposes an intelligent robotic sonographer to autonomously “explore” target anatomies and navigate a US probe to standard planes by learning from the expert. The underlying high-level physiological knowledge from experts is inferred by a neural reward function, using a ranked pairwise image comparison approach in a self-supervised fashion. This process can be referred to as understanding the “language of sonography.” Considering the generalization capability to overcome inter-patient variations, mutual information is estimated by a network to explicitly disentangle the task-related and domain features in latent space. The robotic localization is carried out in coarse-to-fine mode based on the predicted reward associated with B-mode images. To validate the effectiveness of the proposed reward inference network, representative experiments were performed on vascular phantoms (“line” target), two types of ex vivo animal organ phantoms (chicken heart and lamb kidney representing “point” target), and in vivo human carotids. To further validate the performance of the autonomous acquisition framework, physical robotic acquisitions were performed on three phantoms (vascular, chicken heart, and lamb kidney). The results demonstrated that the proposed advanced framework can robustly work on a variety of seen and unseen phantoms as well as in vivo human carotid data. Code: https://github.com/yuan-12138/MI-GPSR . 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引用次数: 0
摘要
由于超声(US)成像具有实时和无辐射的优点,因此被广泛用于内脏器官的生物测量和诊断。然而,由于操作员之间的差异,成像结果在很大程度上取决于超声技师的经验。这项工作提出了一种智能机器人超声技师,通过向专家学习,自主 "探索 "目标解剖结构,并将 US 探头导航到标准平面。专家提供的基本高级生理知识是通过神经奖励函数,以自我监督的方式使用排序配对图像比较方法推断出来的。这一过程可称为理解 "超声语言"。考虑到克服患者间差异的泛化能力,通过网络估算互信息,明确地将潜在空间中与任务相关的特征和领域特征区分开来。根据与 B 型图像相关的预测奖励,以从粗到细的模式进行机器人定位。为了验证所提出的奖励推理网络的有效性,在血管模型("线 "目标)、两种活体动物器官模型(代表 "点 "目标的鸡心和羊肾模型)和活体人体颈动脉上进行了代表性实验。为了进一步验证自主采集框架的性能,对三个模型(血管、鸡心和羊肾)进行了物理机器人采集。结果表明,所提出的先进框架能在各种可见和未知模型以及活体人体颈动脉数据上稳健工作。代码: https://github.com/yuan-12138/MI-GPSR 。视频: https://youtu.be/u4ThAA9onE0 。
Intelligent robotic sonographer: Mutual information-based disentangled reward learning from few demonstrations
Ultrasound (US) imaging is widely used for biometric measurement and diagnosis of internal organs due to the advantages of being real-time and radiation-free. However, due to inter-operator variations, resulting images highly depend on the experience of sonographers. This work proposes an intelligent robotic sonographer to autonomously “explore” target anatomies and navigate a US probe to standard planes by learning from the expert. The underlying high-level physiological knowledge from experts is inferred by a neural reward function, using a ranked pairwise image comparison approach in a self-supervised fashion. This process can be referred to as understanding the “language of sonography.” Considering the generalization capability to overcome inter-patient variations, mutual information is estimated by a network to explicitly disentangle the task-related and domain features in latent space. The robotic localization is carried out in coarse-to-fine mode based on the predicted reward associated with B-mode images. To validate the effectiveness of the proposed reward inference network, representative experiments were performed on vascular phantoms (“line” target), two types of ex vivo animal organ phantoms (chicken heart and lamb kidney representing “point” target), and in vivo human carotids. To further validate the performance of the autonomous acquisition framework, physical robotic acquisitions were performed on three phantoms (vascular, chicken heart, and lamb kidney). The results demonstrated that the proposed advanced framework can robustly work on a variety of seen and unseen phantoms as well as in vivo human carotid data. Code: https://github.com/yuan-12138/MI-GPSR . Video: https://youtu.be/u4ThAA9onE0 .