Dandan Zhang scite author profile

Three-dimensional (3D) pose estimation of micro/nano-objects is essential for the implementation of automatic manipulation in micro/nano-robotic systems. However, out-of-plane pose estimation of a micro/nano-object is challenging, since the images are typically obtained in 2D using a scanning electron microscope (SEM) or an optical microscope (OM). Traditional deep learning based methods require the collection of a large amount of labeled data for model training to estimate the 3D pose of an object from a monocular image. Here we present a sim-to-real learning-to-match approach for 3D pose estimation of micro/nano-objects. Instead of collecting large training datasets, simulated data is generated to enlarge the limited experimental data obtained in practice, while the domain gap between the generated and experimental data is minimized via image translation based on a generative adversarial network (GAN) model. A learning-to-match approach is used to map the generated data and the experimental data to a low-dimensional space with the same data distribution for different pose labels, which ensures effective feature embedding. Combining the labeled data obtained from experiments and simulations, a new training dataset is constructed for robust pose estimation. The proposed method is validated with images from both SEM and OM, facilitating the development of closed-loop control of micro/nano-objects with complex shapes in micro/nano-robotic systems.

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One-Shot Domain-Adaptive Imitation Learning via Progressive Learning Applied to Robotic Pouring

Zhang

Fan

Lloyd

et al. 2024

IEEE Trans. Automat. Sci. Eng.

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Fabrication and optical manipulation of micro-robots for biomedical applications

Zhang

Ren

Barbot

et al. 2022

Matter

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From Teleoperation to Autonomous Robot-assisted Microsurgery: A Survey

Zhang

Fang

et al. 2022

Mach. Intell. Res.

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Robot-assisted microsurgery (RAMS) has many benefits compared to traditional microsurgery. Microsurgical platforms with advanced control strategies, high-quality micro-imaging modalities and micro-sensing systems are worth developing to further enhance the clinical outcomes of RAMS. Within only a few decades, microsurgical robotics has evolved into a rapidly developing research field with increasing attention all over the world. Despite the appreciated benefits, significant challenges remain to be solved. In this review paper, the emerging concepts and achievements of RAMS will be presented. We introduce the development tendency of RAMS from teleoperation to autonomous systems. We highlight the upcoming new research opportunities that require joint efforts from both clinicians and engineers to pursue further outcomes for RAMS in years to come.

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Sim-to-Real Model-Based and Model-Free Deep Reinforcement Learning for Tactile Pushing

Yang

Lin

Church

et al. 2023

IEEE Robot. Autom. Lett.

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TacMMs: Tactile Mobile Manipulators for Warehouse Automation

Zhang

Jones

et al. 2023

IEEE Robot. Autom. Lett.

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Multi-robot platforms are playing an increasingly important role in warehouse automation for efficient goods transport. This paper proposes a novel customization of a multirobot system, called Tactile Mobile Manipulators (TacMMs). Each TacMM integrates a soft optical tactile sensor and a mobile robot with a load-lifting mechanism, enabling cooperative transportation in tasks requiring coordinated physical interaction. More specifically, we mount the TacTip (biomimetic optical tactile sensor) on the Distributed Organisation and Transport System (DOTS) mobile robot. The tactile information then helps the mobile robots adjust the relative robot-object pose, thereby increasing the efficiency of load-lifting tasks. This study compares the performance of using two TacMMs with tactile perception with traditional vision-based pose adjustment for load-lifting. The results show that the average success rate of the TacMMs (66%) is improved over a purely visual-based method (34%), with a larger improvement when the mass of the load was non-uniformly distributed. Although this initial study considers two TacMMs, we expect the benefits of tactile perception to extend to multiple mobile robots. Website: https://sites.google.com/view/tacmms.

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Bi-Touch: Bimanual Tactile Manipulation With Sim-to-Real Deep Reinforcement Learning

Lin

Church

Yang

et al. 2023

IEEE Robot. Autom. Lett.

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Dandan Zhang

Micro-object pose estimation with sim-to-real transfer learning using small dataset

One-Shot Domain-Adaptive Imitation Learning via Progressive Learning Applied to Robotic Pouring

Fabrication and optical manipulation of micro-robots for biomedical applications

From Teleoperation to Autonomous Robot-assisted Microsurgery: A Survey

Sim-to-Real Model-Based and Model-Free Deep Reinforcement Learning for Tactile Pushing

TacMMs: Tactile Mobile Manipulators for Warehouse Automation

Bi-Touch: Bimanual Tactile Manipulation With Sim-to-Real Deep Reinforcement Learning

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