342 research outputs found
Design and analysis of a novel long-distance double tendon-sheath transmission device for breast intervention robots under MRI field
Cancer represents a major threat to human health. Magnetic resonance imaging (MRI) provides superior performance to other imaging-based examination methods in the detection of tumors and offers distinct advantages in biopsy and seed implantation. However, because of the MRI environment, the material requirements for actuating devices for the medical robots used in MRI are incredibly demanding. This paper describes a novel double tendon-sheath transmission device for use in MRI applications. LeBus grooves are used in the original transmission wheels, thus enabling the system to realize long-distance and large-stroke transmission with improved accuracy. The friction model of the transmission system and the transmission characteristics model of the novel tendon-sheath structure are then established. To address the problem that tension sensors cannot be installed in large-stroke transmission systems, a three-point force measurement method is used to measure and set an appropriate preload in the novel tendon-sheath transmission system. Additionally, experiments are conducted to verify the accuracy of the theoretical model and multiple groups of tests are performed to explore the transmission characteristics. Finally, the novel tendon-sheath transmission system is compensated to improve its accuracy and the experimental results acquired after compensation show that the system satisfies the design requirements
Asymptotic behavior of solutions to the Yamabe equation with an asymptotically flat metric
We prove that any positive solution of the Yamabe equation on an
asymptotically flat -dimensional manifold of flatness order at least
and must converge at infinity either to a fundamental
solution of the Laplace operator on the Euclidean space or to a radial Fowler
solution defined on the entire Euclidean space. The flatness order
is the minimal flatness order required to define ADM mass in
general relativity; the dimension is the dividing dimension of the
validity of compactness of solutions to the Yamabe problem. We also prove such
alternatives for bounded solutions when .
We prove these results by establishing appropriate asymptotic behavior near
an isolated singularity of solutions to the Yamabe equation when the metric has
a flatness order of at least at the singularity and ,
also when and the solution grows no faster than the fundamental solution
of the flat metric Laplacian at the singularity. These results extend earlier
results of L. Caffarelli, B. Gidas and J. Spruck, also of N. Korevaar, R.
Mazzeo, F. Pacard and R. Schoen, when the metric is conformally flat, and work
of C.C. Chen and C. S. Lin when the scalar curvature is a non-constant function
with appropriate flatness at the singular point, also work of F. Marques when
the metric is not necessarily conformally flat but smooth, and the dimension of
the manifold is three, four, or five, as well as recent similar results by the
second and third authors in dimension six.Comment: 51 page
3DCFS : Fast and robust joint 3D semantic-instance segmentation via coupled feature selection
We propose a novel fast and robust 3D point clouds segmentation framework via coupled feature selection, named 3DCFS, that jointly performs semantic and instance segmentation. Inspired by the human scene perception process, we design a novel coupled feature selection module, named CFSM, that adaptively selects and fuses the reciprocal semantic and instance features from two tasks in a coupled manner. To further boost the performance of the instance segmentation task in our 3DCFS, we investigate a loss function that helps the model learn to balance the magnitudes of the output embedding dimensions during training, which makes calculating the Euclidean distance more reliable and enhances the generalizability of the model. Extensive experiments demonstrate that our 3DCFS outperforms state-of-the-art methods on benchmark datasets in terms of accuracy, speed and computational cost
Neuromorphic Online Learning for Spatiotemporal Patterns with a Forward-only Timeline
Spiking neural networks (SNNs) are bio-plausible computing models with high
energy efficiency. The temporal dynamics of neurons and synapses enable them to
detect temporal patterns and generate sequences. While Backpropagation Through
Time (BPTT) is traditionally used to train SNNs, it is not suitable for online
learning of embedded applications due to its high computation and memory cost
as well as extended latency. Previous works have proposed online learning
algorithms, but they often utilize highly simplified spiking neuron models
without synaptic dynamics and reset feedback, resulting in subpar performance.
In this work, we present Spatiotemporal Online Learning for Synaptic Adaptation
(SOLSA), specifically designed for online learning of SNNs composed of Leaky
Integrate and Fire (LIF) neurons with exponentially decayed synapses and soft
reset. The algorithm not only learns the synaptic weight but also adapts the
temporal filters associated to the synapses. Compared to the BPTT algorithm,
SOLSA has much lower memory requirement and achieves a more balanced temporal
workload distribution. Moreover, SOLSA incorporates enhancement techniques such
as scheduled weight update, early stop training and adaptive synapse filter,
which speed up the convergence and enhance the learning performance. When
compared to other non-BPTT based SNN learning, SOLSA demonstrates an average
learning accuracy improvement of 14.2%. Furthermore, compared to BPTT, SOLSA
achieves a 5% higher average learning accuracy with a 72% reduction in memory
cost.Comment: 9 pages,8 figure
Multi-Robot Object Transport Motion Planning with a Deformable Sheet
Using a deformable sheet to handle objects is convenient and found in many
practical applications. For object manipulation through a deformable sheet that
is held by multiple mobile robots, it is a challenging task to model the
object-sheet interactions. We present a computational model and algorithm to
capture the object position on the deformable sheet with changing robotic team
formations. A virtual variable cables model (VVCM) is proposed to simplify the
modeling of the robot-sheet-object system. With the VVCM, we further present a
motion planner for the robotic team to transport the object in a
three-dimensional (3D) cluttered environment. Simulation and experimental
results with different robot team sizes show the effectiveness and versatility
of the proposed VVCM. We also compare and demonstrate the planning results to
avoid the obstacle in 3D space with the other benchmark planner.Comment: 8 pages, 10 figures, accepted by RAL&CASE 2022 in June 24, 202
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