Force sensing is important for surgical robotics in order to realize surgical palpation and ensure surgical safety. In this article, we design a compact triaxial force sensor based on fiber Bragg gratings (FBGs). The force sensor is composed of an elastic structure, two supporting disks, and four fibers. To achieve a good balance between the axial resolution and radial resolution, the elastic structure has parallel helical beams and the structure parameters of the sensor are optimized. The mechanical model of the sensor is proposed and the influence of temperature is also considered. The force sensor has the advantages of compact structure, easy assembly, and good scalability. An experimental setup is used to calibrate and evaluate the force sensor. The performance of the force sensor under dynamic force with different frequencies is also evaluated. The resolutions for the axial force and radial force are, respectively, 0.01 and 0.012 N with a range of 0–5 N. In addition, the sensor is fixed on a robot arm to further evaluate its palpation ability. The experimental results show that the sensor can recognize different materials with different stiffnesses and the position of the rigid body in a silica model can also be determined.

A Compact FBG-Based Triaxial Force Sensor With Parallel Helical Beams for Robotic-Assisted Surgery

Deep learning-assisted ultra-accurate smartphone testing of paper-based colorimetric ELISA assays

With the rapid development of new-generation artificial intelligence and Internet of Things technology, mobile robot technology has been widely used in various fields. Among them, the autonomous path-planning technology of mobile robots is one of the cores for realizing their autonomous driving and obstacle avoidance. This study conducts an in-depth discussion on the real-time and dynamic obstacle avoidance capabilities of mobile robot path planning. First, we proposed a preprocessing method for obstacles in the grid map, focusing on the closed processing of the internal space of concave obstacles to ensure the feasibility of the path while effectively reducing the number of grid nodes searched by the A* algorithm, thereby improving path search efficiency. Secondly, in order to achieve static global path planning, this study adopts the A algorithm. However, in practice, algorithm A has problems such as a large number of node traversals, low search efficiency, redundant path nodes, and uneven turning angles. To solve these problems, we optimized the A* algorithm, focusing on optimizing the heuristic function and weight coefficient to reduce the number of node traversals and improve search efficiency. In addition, we use the Bezier curve method to smooth the path and remove redundant nodes, thereby reducing the turning angle. Then, in order to achieve dynamic local path planning, this study adopts the artificial potential field method. However, the artificial potential field method has the problems of unreachable target points and local minima. In order to solve these problems, we optimized the repulsion field so that the target point is at the lowest point of the global energy of the gravitational field and the repulsive field and eliminated the local optimal point. Finally, for the path-planning problem of mobile robots in dynamic environments, this study proposes a hybrid path-planning method based on a combination of the improved A* algorithm and the artificial potential field method. In this study, we not only focus on the efficiency of mobile robot path planning and real-time dynamic obstacle avoidance capabilities but also pay special attention to the symmetry of the final path. By introducing symmetry, we can more intuitively judge whether the path is close to the optimal state. Symmetry is an important criterion for us to evaluate the performance of the final path. 

Simulation of Dynamic Path Planning of Symmetrical Trajectory of Mobile Robots Based on Improved A* and Artificial Potential Field Fusion for Natural Resource Exploration

Surgical robot systems (SRS) represent an innovative cross‐disciplinary research field using robotic technology to assist surgeons in operations. Current bottlenecks in SRS, such as the limited ability to process complex information and make surgical decisions, have not been effectively solved. Artificial intelligence (AI) is a valuable technique for simulating and extending human intelligence. AI offers a new direction and impetus for SRS by enhancing performance in areas such as perception, navigation, surgical planning, and control strategies. This review introduces the developmental history of AI‐aided SRS, summarizes the basic SRS architecture, and analyzes how AI can improve SRS performance. Classical cases of AI‐aided SRS, the impact of evidence in clinical settings, and associated ethical and legal considerations are explored. Finally, the challenges in AI‐aided SRS are discussed, including algorithm development, surgical data science, human–robot coordination, and trust building between humans and robots.

Evolution of Surgical Robot Systems Enhanced by Artificial Intelligence: A Review

/pdf/vlp-landmark-and-slam-assisted-automatic-map-calibration-for-3togmak9.pdf

VLP Landmark and SLAM-Assisted Automatic Map Calibration for Robot Navigation with Semantic Information

Deep learning (DL) has emerged as a powerful image processing technique that learns the features of the data and produces state-of-the-art prediction results. The decade from 2010 to 2020 is a real revival of DL, which has come to a turning point in history. In image classification, many deep learning networks have been proposed by scholars, and each of them has its own strengthness. It is very important and efficient for the researchers and the developers to know the performance of these networks, especially for the beginners, so as to give them a transplant instruction by an objective evaluation index. In this paper, we constructed different data sets from three aspects, texture, shape, and measurement scale to test the performance of nine mainstream image classification networks. Cross-contrast experiments were performed to analyze the sensitivity of factors which influence the stability of image classification networks. Experimental results shown that in the 27 image datasets generated by the three image factors, the classification performance of AlexNet, GoogleNet, VggNet, and DenseNet is better. The perfomance comparison of these networks are showed and discussed in details. Code and pretrained models are available at https://github.com/liqiang12689/image-classification-finall .

/pdf/performance-evaluation-of-deep-learning-classification-3nyuwfov1t.pdf

Performance Evaluation of Deep Learning Classification Network for Image Features

The combination of artificial intelligence technology and medical science has inspired the emergence of medical robots with novel functions that use new materials and have a neoteric appearance. However, the diversity of medical robots causes confusion regarding their classification. In this paper, we review the concepts pertinent to major classification methods and development status of medical robots. We survey the classification methods according to the appearance, function, and application of medical robots. The difficulties surrounding classification methods that arose are discussed, for example, (1) it is difficult to make a simple distinction among existing types of medical robots; (2) classification is important to provide sufficient applicability to the existing and upcoming medical robots; (3) future medical robots may destroy the stability of the classification framework. To solve these problems, we proposed an innovative multilevel classification strategy for medical robots. According to the main classification method, the medical robots were divided into four major categories—surgical, rehabilitation, medical assistant, and hospital service robots—and personalized classifications for each major category were proposed in secondary classifications. The technologies currently available or in development for surgical robots and rehabilitation robots are discussed with great emphasis. The technical preferences of surgical robots in the different departments and the rehabilitation robots in the variant application scenes are perceived, by which the necessity of further classification of the surgical robots and the rehabilitation robots is shown and the secondary classification strategy for surgical robots and rehabilitation robots is provided. Our results show that the distinctive features of surgical robots and rehabilitation robots can be highlighted and that the communication between professionals in the same and other fields can be improved.

Development Status and Multilevel Classification Strategy of Medical Robots

Our paper proposes a method to measure lung parenchyma parameters from pulmonary window computed tomography images based on ResU-Net model including the CT value, the density, the lung volume, and the surface area of the lungs of healthy rats, to help promote the quantitative analysis of lung parenchyma parameters of rats in medical respiratory researches. Through the analysis of the lung parenchyma parameters of the control group and the treatment group, the law of change among the lung parenchyma parameters is given in our paper. After comparing and analyzing the lung parenchyma parameter CT value and the density of the two groups, it is discovered that the lung parenchyma parameter CT value and the density significantly increase in the treatment group which is after continuously inhaling the nebulization of contrast agents. The change of the lung volume with the surface area in both two groups conforms to the law of lung changes during breathing. The relationship between the lung volume and the CT value or the density is analyzed and it is concluded that the lung volume is negatively correlated with the CT value or the density.

Lung parenchyma parameters measure of rats from pulmonary window computed tomography images based on ResU-Net model for medical respiratory researches.

The invention relates to a focus position dynamic detection method and device, electronic equipment and a storage medium, and the method comprises: obtaining a prediction position for a focus in a plurality of groups of lung images, and enabling the plurality of groups of lung images to be lung images obtained at a plurality of moments in a breathing process; respectively extracting first images at the same positions in the plurality of groups of lung images to obtain lung motion sequence images at the same positions; sequentially correcting the prediction positions of the first images according to the sequence of the first images in the lung movement sequence to obtain a dynamic detection position of a focus, wherein the prediction position of the (i+1) th first image is corrected by using the dynamic detection position of the ith first image in the lung movement sequence, and the dynamic detection position of the (i+1) th first image is obtained. The embodiment of the invention can realize dynamic tracking of the focus position in the lung image.

Focus position dynamic detection method and device, electronic equipment and storage medium

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Papers

Performance Evaluation of Deep Learning Classification Network for Image Features

Development Status and Multilevel Classification Strategy of Medical Robots

Lung parenchyma parameters measure of rats from pulmonary window computed tomography images based on ResU-Net model for medical respiratory researches.

Focus position dynamic detection method and device, electronic equipment and storage medium