Your search keyword '"Chao, Jun-Jee"' showing total 12 results

1. Map-Aware Human Pose Prediction for Robot Follow-Ahead

Author

Jiang, Qingyuan, Susam, Burak, Chao, Jun-Jee, and Isler, Volkan

Subjects

Computer Science - Robotics

Abstract

In the robot follow-ahead task, a mobile robot is tasked to maintain its relative position in front of a moving human actor while keeping the actor in sight. To accomplish this task, it is important that the robot understand the full 3D pose of the human (since the head orientation can be different than the torso) and predict future human poses so as to plan accordingly. This prediction task is especially tricky in a complex environment with junctions and multiple corridors. In this work, we address the problem of forecasting the full 3D trajectory of a human in such environments. Our main insight is to show that one can first predict the 2D trajectory and then estimate the full 3D trajectory by conditioning the estimator on the predicted 2D trajectory. With this approach, we achieve results comparable or better than the state-of-the-art methods three times faster. As part of our contribution, we present a new dataset where, in contrast to existing datasets, the human motion is in a much larger area than a single room. We also present a complete robot system that integrates our human pose forecasting network on the mobile robot to enable real-time robot follow-ahead and present results from real-world experiments in multiple buildings on campus. Our project page, including supplementary material and videos, can be found at: https://qingyuan-jiang.github.io/iros2024_poseForecasting/

Published

2024

2. VioLA: Aligning Videos to 2D LiDAR Scans

Author

Chao, Jun-Jee, Engin, Selim, Chavan-Dafle, Nikhil, Lee, Bhoram, and Isler, Volkan

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

We study the problem of aligning a video that captures a local portion of an environment to the 2D LiDAR scan of the entire environment. We introduce a method (VioLA) that starts with building a semantic map of the local scene from the image sequence, then extracts points at a fixed height for registering to the LiDAR map. Due to reconstruction errors or partial coverage of the camera scan, the reconstructed semantic map may not contain sufficient information for registration. To address this problem, VioLA makes use of a pre-trained text-to-image inpainting model paired with a depth completion model for filling in the missing scene content in a geometrically consistent fashion to support pose registration. We evaluate VioLA on two real-world RGB-D benchmarks, as well as a self-captured dataset of a large office scene. Notably, our proposed scene completion module improves the pose registration performance by up to 20%., Comment: 8 pages

Published

2023

3. 3D Surface Reconstruction in the Wild by Deforming Shape Priors from Synthetic Data

Author

Häni, Nicolai, Chao, Jun-Jee, and Isler, Volkan

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Reconstructing the underlying 3D surface of an object from a single image is a challenging problem that has received extensive attention from the computer vision community. Many learning-based approaches tackle this problem by learning a 3D shape prior from either ground truth 3D data or multi-view observations. To achieve state-of-the-art results, these methods assume that the objects are specified with respect to a fixed canonical coordinate frame, where instances of the same category are perfectly aligned. In this work, we present a new method for joint category-specific 3D reconstruction and object pose estimation from a single image. We show that one can leverage shape priors learned on purely synthetic 3D data together with a point cloud pose canonicalization method to achieve high-quality 3D reconstruction in the wild. Given a single depth image at test time, we first transform this partial point cloud into a learned canonical frame. Then, we use a neural deformation field to reconstruct the 3D surface of the object. Finally, we jointly optimize object pose and 3D shape to fit the partial depth observation. Our approach achieves state-of-the-art reconstruction performance across several real-world datasets, even when trained only on synthetic data. We further show that our method generalizes to different input modalities, from dense depth images to sparse and noisy LIDAR scans.

Published

2023

4. Category-Level Global Camera Pose Estimation with Multi-Hypothesis Point Cloud Correspondences

Author

Chao, Jun-Jee, Engin, Selim, Häni, Nicolai, and Isler, Volkan

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Correspondence search is an essential step in rigid point cloud registration algorithms. Most methods maintain a single correspondence at each step and gradually remove wrong correspondances. However, building one-to-one correspondence with hard assignments is extremely difficult, especially when matching two point clouds with many locally similar features. This paper proposes an optimization method that retains all possible correspondences for each keypoint when matching a partial point cloud to a complete point cloud. These uncertain correspondences are then gradually updated with the estimated rigid transformation by considering the matching cost. Moreover, we propose a new point feature descriptor that measures the similarity between local point cloud regions. Extensive experiments show that our method outperforms the state-of-the-art (SoTA) methods even when matching different objects within the same category. Notably, our method outperforms the SoTA methods when registering real-world noisy depth images to a template shape by up to 20% performance., Comment: 8 pages

Published

2022

5. Continuous Object Representation Networks: Novel View Synthesis without Target View Supervision

Author

Häni, Nicolai, Engin, Selim, Chao, Jun-Jee, and Isler, Volkan

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Novel View Synthesis (NVS) is concerned with synthesizing views under camera viewpoint transformations from one or multiple input images. NVS requires explicit reasoning about 3D object structure and unseen parts of the scene to synthesize convincing results. As a result, current approaches typically rely on supervised training with either ground truth 3D models or multiple target images. We propose Continuous Object Representation Networks (CORN), a conditional architecture that encodes an input image's geometry and appearance that map to a 3D consistent scene representation. We can train CORN with only two source images per object by combining our model with a neural renderer. A key feature of CORN is that it requires no ground truth 3D models or target view supervision. Regardless, CORN performs well on challenging tasks such as novel view synthesis and single-view 3D reconstruction and achieves performance comparable to state-of-the-art approaches that use direct supervision. For up-to-date information, data, and code, please see our project page: https://nicolaihaeni.github.io/corn/., Comment: To appear at Advances in Neural Information Processing Systems 33 (NeurIPS 2020)

Published

2020

6. Semantics-Aware Image to Image Translation and Domain Transfer

Author

Roy, Pravakar, Häni, Nicolai, Chao, Jun-Jee, and Isler, Volkan

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Image to image translation is the problem of transferring an image from a source domain to a different (but related) target domain. We present a new unsupervised image to image translation technique that leverages the underlying semantic information for object transfiguration and domain transfer tasks. Specifically, we present a generative adversarial learning approach that jointly translates images and labels from a source domain to a target domain. Our main technical contribution is an encoder-decoder based network architecture that jointly encodes the image and its underlying semantics and translates both individually to the target domain. Additionally, we propose object transfiguration and cross-domain semantic consistency losses that preserve semantic labels. Through extensive experimental evaluation, we demonstrate the effectiveness of our approach as compared to the state-of-the-art methods on unsupervised image-to-image translation, domain adaptation, and object transfiguration.

Published

2019

7. Online semi-supervised learning applied to an automated insect pest monitoring system

Author

Rustia, Dan Jeric Arcega, Lu, Chen-Yi, Chao, Jun-Jee, Wu, Ya-Fang, Chung, Jui-Yung, Hsu, Ju-Chun, and Lin, Ta-Te

Published

2021

8. Category-Level Global Camera Pose Estimation with Multi-Hypothesis Point Cloud Correspondences

Author

Chao, Jun–Jee, primary, Enginl, Selim, additional, Häni, Nicolai, additional, and Isler, Volkan, additional

Published

2023

9. Continuous Object Representation Networks: Novel View Synthesis without Target View Supervision

Author

H��ni, Nicolai, Engin, Selim, Chao, Jun-Jee, and Isler, Volkan

Subjects

FOS: Computer and information sciences, Computer Vision and Pattern Recognition (cs.CV), Computer Science - Computer Vision and Pattern Recognition

Abstract

Novel View Synthesis (NVS) is concerned with synthesizing views under camera viewpoint transformations from one or multiple input images. NVS requires explicit reasoning about 3D object structure and unseen parts of the scene to synthesize convincing results. As a result, current approaches typically rely on supervised training with either ground truth 3D models or multiple target images. We propose Continuous Object Representation Networks (CORN), a conditional architecture that encodes an input image's geometry and appearance that map to a 3D consistent scene representation. We can train CORN with only two source images per object by combining our model with a neural renderer. A key feature of CORN is that it requires no ground truth 3D models or target view supervision. Regardless, CORN performs well on challenging tasks such as novel view synthesis and single-view 3D reconstruction and achieves performance comparable to state-of-the-art approaches that use direct supervision. For up-to-date information, data, and code, please see our project page: https://nicolaihaeni.github.io/corn/., To appear at Advances in Neural Information Processing Systems 33 (NeurIPS 2020)

Published

2020

10. Automatic greenhouse insect pest detection and recognition based on a cascaded deep learning classification method

Author

Rustia, Dan Jeric Arcega, primary, Chao, Jun‐Jee, additional, Chiu, Lin‐Ya, additional, Wu, Ya‐Fang, additional, Chung, Jui‐Yung, additional, Hsu, Ju‐Chun, additional, and Lin, Ta‐Te, additional

Published

2020

11. <i>An Online Unsupervised Deep Learning Approach for an Automated Pest Insect Monitoring System</i>

Author

Rustia, Dan Jeric Arcega, primary, Chao, Jun-Jee, additional, Chung, Jui-Yung, additional, and Lin, Ta-Te, additional

Published

2019

12. Automatic greenhouse insect pest detection and recognition based on a cascaded deep learning classification method.

Author

Rustia, Dan Jeric Arcega, Chao, Jun‐Jee, Chiu, Lin‐Ya, Wu, Ya‐Fang, Chung, Jui‐Yung, Hsu, Ju‐Chun, and Lin, Ta‐Te

Subjects

*INSECT pests, *DEEP learning, *GREENHOUSE gardening, *CONVOLUTIONAL neural networks, *PHASMIDA, *INTEGRATED pest control

Abstract

Inspection of insect sticky paper traps is an essential task for an effective integrated pest management (IPM) programme. However, identification and counting of the insect pests stuck on the traps is a very cumbersome task. Therefore, an efficient approach is needed to alleviate the problem and to provide timely information on insect pests. In this research, an automatic method for the multi‐class recognition of small‐size greenhouse insect pests on sticky paper trap images acquired by wireless imaging devices is proposed. The developed algorithm features a cascaded approach that uses a convolutional neural network (CNN) object detector and CNN image classifiers, separately. The object detector was trained for detecting objects in an image, and a CNN classifier was applied to further filter out non‐insect objects from the detected objects in the first stage. The obtained insect objects were then further classified into flies (Diptera: Drosophilidae), gnats (Diptera: Sciaridae), thrips (Thysanoptera: Thripidae) and whiteflies (Hemiptera: Aleyrodidae), using a multi‐class CNN classifier in the second stage. Advantages of this approach include flexibility in adding more classes to the multi‐class insect classifier and sample control strategies to improve classification performance. The algorithm was developed and tested for images taken by multiple wireless imaging devices installed in several greenhouses under natural and variable lighting environments. Based on the testing results from long‐term experiments in greenhouses, it was found that the algorithm could achieve average F1‐scores of 0.92 and 0.90 and mean counting accuracies of 0.91 and 0.90, as tested on a separate 6‐month image data set and on an image data set from a different greenhouse, respectively. The proposed method in this research resolves important problems for the automated recognition of insect pests and provides instantaneous information of insect pest occurrences in greenhouses, which offers vast potential for developing more efficient IPM strategies in agriculture. [ABSTRACT FROM AUTHOR]

Published

2021