Wei Yang scite author profile

Prostate cancer (PCa) is a major cause of death since ancient time documented in Egyptian Ptolemaic mummy imaging. PCa detection is critical to personalized medicine and varies considerably under an MRI scan. 172 patients with 2,602 morphologic images (axial 2D T2-weighted imaging) of the prostate were obtained. A deep learning with deep convolutional neural network (DCNN) and a non-deep learning with SIFT image feature and bag-of-word (BoW), a representative method for image recognition and analysis, were used to distinguish pathologically confirmed PCa patients from prostate benign conditions (BCs) patients with prostatitis or prostate benign hyperplasia (BPH). In fully automated detection of PCa patients, deep learning had a statistically higher area under the receiver operating characteristics curve (AUC) than non-deep learning (P = 0.0007 < 0.001). The AUCs were 0.84 (95% CI 0.78–0.89) for deep learning method and 0.70 (95% CI 0.63–0.77) for non-deep learning method, respectively. Our results suggest that deep learning with DCNN is superior to non-deep learning with SIFT image feature and BoW model for fully automated PCa patients differentiation from prostate BCs patients. Our deep learning method is extensible to image modalities such as MR imaging, CT and PET of other organs.

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DexPilot: Vision-Based Teleoperation of Dexterous Robotic Hand-Arm System

Handa

Wyk

Yang

et al. 2020

120

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Reactive Human-to-Robot Handovers of Arbitrary Objects

Yang

Paxton

Mousavian

et al. 2021

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Human-robot object handovers have been an actively studied area of robotics over the past decade; however, very few techniques and systems have addressed the challenge of handing over diverse objects with arbitrary appearance, size, shape, and rigidity. In this paper, we present a visionbased system that enables reactive human-to-robot handovers of unknown objects. Our approach combines closed-loop motion planning with real-time, temporally-consistent grasp generation to ensure reactivity and motion smoothness. Our system is robust to different object positions and orientations, and can grasp both rigid and non-rigid objects. We demonstrate the generalizability, usability, and robustness of our approach on a novel benchmark set of 26 diverse household objects, a user study with naive users (N=6) handing over a subset of 15 objects, and a systematic evaluation examining different ways of handing objects. More results and videos can be found at https://sites.google.com/nvidia.com/ handovers-of-arbitrary-objects.

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Privacy-Preserving Federated Learning in Fog Computing

Zhou

et al. 2020

IEEE Internet Things J.

196

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Human Grasp Classification for Reactive Human-to-Robot Handovers

Yang

Paxton

Çakmak

et al. 2020

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Wei Yang

Searching for prostate cancer by fully automated magnetic resonance imaging classification: deep learning versus non-deep learning

DexPilot: Vision-Based Teleoperation of Dexterous Robotic Hand-Arm System

Reactive Human-to-Robot Handovers of Arbitrary Objects

Privacy-Preserving Federated Learning in Fog Computing

Human Grasp Classification for Reactive Human-to-Robot Handovers

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