Search

Your search keyword '"Wanfeng Shang"' showing total 16 results
Start Over Author "Wanfeng Shang" Topic control and systems engineering
16 results on '"Wanfeng Shang"'

6. Insect-Scale SMAW-Based Soft Robot With Crawling, Jumping, and Loading Locomotion

Author

Wenqiang Huang, Wanfeng Shang, Yueheng Huang, Hongyu Long, and Xinyu Wu

Subjects
Human-Computer Interaction, Control and Optimization, Artificial Intelligence, Control and Systems Engineering, Mechanical Engineering, Biomedical Engineering, Computer Vision and Pattern Recognition, Computer Science Applications
Published
2022

7. Neighborhood Preserving and Weighted Subspace Learning Method for Drift Compensation in Gas Sensor

Author

Wanfeng Shang, Xinyu Wu, Zhengkun Yi, and Tiantian Xu

Subjects
business.industry, Computer science, Gaussian, 020208 electrical & electronic engineering, Pattern recognition, 02 engineering and technology, Function (mathematics), Computer Science Applications, Term (time), Weighting, Human-Computer Interaction, symbols.namesake, ComputingMethodologies_PATTERNRECOGNITION, Discriminative model, Control and Systems Engineering, Classifier (linguistics), 0202 electrical engineering, electronic engineering, information engineering, symbols, 020201 artificial intelligence & image processing, Artificial intelligence, Electrical and Electronic Engineering, business, Software, Distribution (differential geometry), Subspace topology
Abstract

This article presents a novel discriminative subspace-learning-based unsupervised domain adaptation (DA) method for the gas sensor drift problem. Many existing subspace learning approaches assume that the gas sensor data follow a certain distribution such as Gaussian, which often does not exist in real-world applications. In this article, we address this issue by proposing a novel discriminative subspace learning method for DA with neighborhood preserving (DANP). We introduce two novel terms, including the intraclass graph term and the interclass graph term, to embed the graphs into DA. Besides, most existing methods ignore the influence of the subspace learning on the classifier design. To tackle this issue, we present a novel classifier design method (DANP+) that incorporates the DA ability of the subspace into the learning of the classifier. The weighting function is introduced to assign different weights to different dimensions of the subspace. We have verified the effectiveness of the proposed methods by conducting experiments on two public gas sensor datasets in comparison with the state-of-the-art DA methods.

Published
2022

9. Touch Modality Identification With Tensorial Tactile Signals: A Kernel-Based Approach

Author

Wanfeng Shang, Xinyu Wu, Tiantian Xu, and Zhengkun Yi

Subjects
Modality (human–computer interaction), Computer science, business.industry, Pattern recognition, Tactile perception, Data set, Identification (information), Feature Dimension, Control and Systems Engineering, Kernel (statistics), Principal component analysis, Singular value decomposition, Artificial intelligence, Electrical and Electronic Engineering, business
Abstract

Touch modality identification has attracted increasing attention due to its importance in human-robot interactions. There are three issues involved in the tactile perception for the touch modality identification, including the high dimensionality of tactile signals, complex tensor morphology of tactile sensing units, and the misalignment among different tactile time-series samples. In this article, we propose a novel kernel-based approach to deal with these three issues in a unified framework. Specifically, the techniques, including sparse principal component analysis and subsampling, are employed to reduce the feature dimension. Then, a singular value decomposition (SVD)-based kernel is proposed to preserve the spatial information of the tactile sensing elements. The sample misalignment issue is addressed via the employment of a global alignment kernel. Moreover, the merits of these two kernels are fused through an ideal regularized composite kernel, which simultaneously takes the label information of the training set into consideration. The effectiveness of the proposed kernel-based approach is verified on a public touch modality data set with a comprehensive comparison with the competing methods.

Published
2022

11. Local Discriminant Subspace Learning for Gas Sensor Drift Problem

Author

Shifeng Guo, Zhengkun Yi, Xinyu Wu, Wanfeng Shang, and Tiantian Xu

Subjects
Computer science, Linear discriminant analysis, Computer Science Applications, Compensation (engineering), Human-Computer Interaction, ComputingMethodologies_PATTERNRECOGNITION, Discriminant, Control and Systems Engineering, Electrical and Electronic Engineering, Projection (set theory), Algorithm, Software, Subspace topology, Eigendecomposition of a matrix
Abstract

Sensor drift is one of the severe issues that gas sensors suffer from. To alleviate the sensor drift problem, a gas sensor drift compensation approach is proposed based on local discriminant subspace projection (LDSP). The proposed approach aims to find a subspace to reduce the distribution difference between two domains, i.e., the source and target domain. Similar to domain regularized component analysis (DRCA) which is a recently proposed sensor drift correction method, the mean distribution discrepancy is minimized in the common subspace in our approach. LDSP extends DRCA in two aspects, i.e., it not only takes the label information of the source data into consideration to reduce the possibility of the case that samples in the subspace with different class labels stay close to each other, but also borrows the idea of locality-preserving projection to deal with multimodal data. Specifically, inspired by local Fisher discriminant analysis (LFDA), the label information is utilized to maximize the local between-class variance of source data in the latent common subspace and simultaneously minimize the local within-class variance. The formulation of LDSP is a generalized eigenvalue problem that can be readily solved. The experimental results have shown the proposed method outperforms other gas sensor drift compensation methods in terms of classification accuracy on two public gas sensor drift datasets.

Published
2022

12. Tactile Surface Roughness Categorization With Multineuron Spike Train Distance

Author

Xinyu Wu, Shifeng Guo, Zhengkun Yi, Tiantian Xu, and Wanfeng Shang

Subjects
Spiking neural network, 0209 industrial biotechnology, Computer science, business.industry, Spike train, Pattern recognition, Hardware_PERFORMANCEANDRELIABILITY, 02 engineering and technology, ComputerSystemsOrganization_PROCESSORARCHITECTURES, Tactile perception, 020901 industrial engineering & automation, Neuromorphic engineering, Control and Systems Engineering, Metric (mathematics), Feature (machine learning), ComputerSystemsOrganization_SPECIAL-PURPOSEANDAPPLICATION-BASEDSYSTEMS, Train, Spike (software development), Artificial intelligence, Electrical and Electronic Engineering, business
Abstract

Tactile sensing with spiking neural networks (SNNs) has attracted increasing attention in the past decades. In this article, a novel SNN framework is proposed for the tactile surface roughness categorization task. In contrast to supervised SNN methods such as ReSuMe and Tempotron that require prespecifying target spike trains, the presented method performs the classification through directly comparing the distance between multineuron spike trains. Unlike simple spike train fusion methods using average pairwise spike train distance or pooled spike train distance, the proposed method merges spike trains from different neurons with the multineuron spike train distance, which can capture the complex correlation of multiple spike trains. Specifically, the spike trains are generated via the Izhikevich neurons from tactile signals. The similarity of the multineuron spike trains is computed using the multineuron Victor–Purpura spike train distance, which can be efficiently implemented in an inductive manner. The classification can be performed by incorporating $k$ -nearest neighbors and the multineuron spike train distance as a similarity metric. The proposed framework is quite general, i.e., other multineuron spike train distances and spike train kernel-based methods can be readily incorporated. The effectiveness of the proposed method has been demonstrated on a tactile data set by comparing it with various feature- and spike-based methods. Note to Practitioners —In the soft neuromorphic implementation of biomimetic tactile sensing and the development of the tactile sensing capability in neurobotic systems, the processing and analysis of spike-like tactile signals are quite common. Inspired by human tactile perception, this article proposes a novel supervised spiking neural network method for tactile sensing tasks. The traditional methods have to prespecify target spike trains, which is still an open question. In addition, the current ways to fuse spike trains from multiple neurons are far from mature. This article tackles these two problems using spike train similarity comparison with multineuron spike train distance. The direct spike train similarity comparison avoids the need to prespecify target spike trains. The multineuron spike train distance can inherently fuse spike trains from different neurons. It is demonstrated that the proposed method is able to effectively perform classification in a tactile roughness discrimination task.

Published
2021

13. A Fast Soft Continuum Catheter Robot Manufacturing Strategy Based on Heterogeneous Modular Magnetic Units

Author

Tieshan Zhang, Gen Li, Xiong Yang, Hao Ren, Dong Guo, Hong Wang, Ki Chan, Zhou Ye, Tianshuo Zhao, Chengfei Zhang, Wanfeng Shang, and Yajing Shen

Subjects
modular fabrication, magnetic continuum robots, modular robots, biomedical applications, Control and Systems Engineering, Mechanical Engineering, Electrical and Electronic Engineering
Abstract

Developing small-scale continuum catheter robots with inherent soft bodies and high adaptability to different environments holds great promise for biomedical engineering applications. However, current reports indicate that these robots meet challenges when it comes to quick and flexible fabrication with simpler processing components. Herein, we report a millimeter-scale magnetic-polymer-based modular continuum catheter robot (MMCCR) that is capable of performing multifarious bending through a fast and general modular fabrication strategy. By preprogramming the magnetization directions of two types of simple magnetic units, the assembled MMCCR with three discrete magnetic sections could be transformed from a single curvature pose with a large tender angle to a multicurvature S shape in the applied magnetic field. Through static and dynamic deformation analyses for MMCCRs, high adaptability to varied confined spaces can be predicted. By employing a bronchial tree phantom, the proposed MMCCRs demonstrated their capability to adaptively access different channels, even those with challenging geometries that require large bending angles and unique S-shaped contours. The proposed MMCCRs and the fabrication strategy shine new light on the design and development of magnetic continuum robots with versatile deformation styles, which would further enrich broad potential applications in biomedical engineering.

Published
2023

14. Dual Rotating Microsphere Using Robotic Feedforward Compensation Control of Cooperative Flexible Micropipettes

Author

Xinyu Wu, Wanfeng Shang, Tiantian Xu, Hao Ren, and Mingjian Zhu

Subjects
0209 industrial biotechnology, Computer science, Feed forward, Ranging, Control engineering, 02 engineering and technology, Contact force, Compensation (engineering), Dual (category theory), Microsphere, 020901 industrial engineering & automation, Control and Systems Engineering, Microsystem, Electrical and Electronic Engineering, Rotation (mathematics)
Abstract

High flexible and high precise manipulation is one of the most critical technique for complex microsystem’s measurement, manufacture, and assembly. Although recent advances in microrobotics have successfully realized the automatic manipulation and positioning of tiny objects, their flexible manipulation in 3-D free space remains a challenge, such as the wide-angle rotation manipulation of microsize sphere, due to the complicate surface forces. Herein, this article proposed a feedforward model and realized the precise rotation for microsized sphere by two cooperative flexible micropipettes. Firstly, a microrobotic manipulation system with six degrees-of-freedom (DOFs) was developed and integrated with the microscope. Then, a feedforward compensation control strategy involving dual rotation was proposed for the precise manipulation of microsized sphere ( ${\sim }90~\mu \text {m}$ ) based on the analysis of contact forces. As a result, the rotation of the microsized sphere in two different planes was realized and the microsized sphere release procedure was also accomplished after rotation. Compared with existing techniques only allowing limited amplitudes rotation, this article realizes wide-angle rotation manipulation of microsized sphere in 3-D free space. This research opens new prospects for the microsized object accurate manipulation, which is expected to give a long-term impact for complex microsystem’s manufacture and assembly. Note to Practitioners —This article is motivated by the problem of the flexible manipulation of tiny object in 3-D space. The proposed nanorobotic manipulation system, two micropipettes and feedforward compensation model control strategy could realize the precise translational and rotational manipulation of microbeads in 3-D space, which offers obvious advantages of existing techniques. The proposed system and method could be a general solution for precise and flexible micromanipulation. Thus, it could find wide applications ranging from fundamental research to industrial applications, such as biological cell positioning, characterization of a particular micro/nanoregion, microassembly, and manufacturing.

Published
2020

15. Ultrahigh-Precision Rotational Positioning Under a Microscope: Nanorobotic System, Modeling, Control, and Applications

Author

Haojian Lu, Yajing Shen, Wanfeng Shang, and Hui Xie

Subjects
0209 industrial biotechnology, Microscope, Computer science, media_common.quotation_subject, 02 engineering and technology, Repetitive control, 021001 nanoscience & nanotechnology, Computer Science Applications, law.invention, Attitude control, 020901 industrial engineering & automation, Control and Systems Engineering, Control theory, law, Electrical and Electronic Engineering, Fault model, Eccentricity (behavior), 0210 nano-technology, Servo, Interpolation, media_common
Abstract

High-precision positioning is an essential requirement for sample operation at a small scale. At the current stage, although nanometer-scale accuracy has been achieved for the linear positioning, the rotational positioning (attitude control) is still very challenging and rarely addressed. This paper presents a rotatable nanorobotic system with rotational degrees of freedom first. Then, the system error, i.e., nonaxisymmetrical eccentricity error of the mechanism, is investigated dynamically and its fault model is established. After that, a double-loop servo repetitive controller is accordingly designed based on the circle interpolation strategy. The theoretical analysis and experimental results verify that the rotational positioning accuracy can be controlled up to submicrometers stably, which improves at least one order of magnitude than the current static method. Finally, two application cases are given to highlight the significance of this approach, i.e., surface defect detection from $\text{360}^{\circ }$ and in situ twisting characterization of 1-D micro/nanomaterial. This research paves a new avenue for the ultrahigh rotational positioning at microscopy environment, which is expected to generate a long-term impact on the micro/nanofields, such as microscopy imaging, material characterization, and so on.

Published
2018

16. Kinect-Based Vision System of Mine Rescue Robot for Low Illuminous Environment

Author

Wanfeng Shang, Pengkang Wei, Hongwei Ma, Hailong Zang, and Cao Xiangang

Subjects
0209 industrial biotechnology, Engineering, Article Subject, Machine vision, Interface (computing), ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, 02 engineering and technology, GeneralLiterature_MISCELLANEOUS, 020901 industrial engineering & automation, Depth map, lcsh:Technology (General), 0202 electrical engineering, electronic engineering, information engineering, Computer vision, Electrical and Electronic Engineering, Instrumentation, Rescue robot, Artificial neural network, business.industry, Template matching, Control and Systems Engineering, Gesture recognition, lcsh:T1-995, 020201 artificial intelligence & image processing, Artificial intelligence, business, Gesture
Abstract

This paper presents Kinect-based vision system of mine rescue robot working in illuminous underground environment. The somatosensory system of Kinect is used to realize the hand gesture recognition involving static hand gesture and action. AK-curvature based convex detection method is proposed to fit the hand contour with polygon. In addition, the hand action is completed by using the NiTE library with the framework of hand gesture recognition. In addition, the proposed method is compared with BP neural network and template matching. Furthermore, taking advantage of the information of the depth map, the interface of hand gesture recognition is established for human machine interaction of rescue robot. Experimental results verify the effectiveness of Kinect-based vision system as a feasible and alternative technology for HMI of mine rescue robot.

Published
2016

Catalog

Books, media, physical & digital resources
See catalog results