Related papers: Utilizing Synthetic Data in Supervised Learning for Robust 5-DoF Magnetic Marker Localization

Utilizing Synthetic Data in Supervised Learning for Robust 5-DoF Magnetic Marker Localization

URL: http://arxiv.org/abs/2211.07556v2
Date: Mon, 25 Mar 2024 15:11:56 GMT
Title: Utilizing Synthetic Data in Supervised Learning for Robust 5-DoF Magnetic Marker Localization
Authors: Mengfan Wu, Thomas Langerak, Otmar Hilliges, Juan Zarate,
Abstract summary: Tracking passive magnetic markers plays a vital role in advancing healthcare and robotics, offering the potential to significantly improve the precision and efficiency of systems. Traditionally, the tracking of magnetic markers is computationally expensive due to the requirement for iterative optimization procedures. This paper introduces a novel approach that leverages neural networks to bypass these limitations, directly inferring the marker's position and orientation to accurately determine the magnet's 5 DoF.
Score: 24.478974451501113
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Tracking passive magnetic markers plays a vital role in advancing healthcare and robotics, offering the potential to significantly improve the precision and efficiency of systems. This technology is key to developing smarter, more responsive tools and devices, such as enhanced surgical instruments, precise diagnostic tools, and robots with improved environmental interaction capabilities. However, traditionally, the tracking of magnetic markers is computationally expensive due to the requirement for iterative optimization procedures. Moreover, these methods depend on the magnetic dipole model for their optimization function, which can yield imprecise outcomes due to the model's significant inaccuracies when dealing with short distances between non-spherical magnet and sensor.Our paper introduces a novel approach that leverages neural networks to bypass these limitations, directly inferring the marker's position and orientation to accurately determine the magnet's 5 DoF in a single step without initial estimation. Although our method demands an extensive supervised training phase, we mitigate this by introducing a computationally more efficient method to generate synthetic, yet realistic data using Finite Element Methods simulations. The benefits of fast and accurate inference significantly outweigh the offline training preparation. In our evaluation, we use different cylindrical magnets, tracked with a square array of 16 sensors. We perform the sensors' reading and position inference on a portable, neural networks-oriented single-board computer, ensuring a compact setup. We benchmark our prototype against vision-based ground truth data, achieving a mean positional error of 4 mm and an orientation error of 8 degrees within a 0.2x0.2x0.15 m working volume. These results showcase our prototype's ability to balance accuracy and compactness effectively in tracking 5 DoF.

Related papers

Accelerating TinyML Inference on Microcontrollers through Approximate Kernels [3.566060656925169]
In this work, we combine approximate computing and software kernel design to accelerate the inference of approximate CNN models on microcontrollers. Our evaluation on an STM32-Nucleo board and 2 popular CNNs trained on the CIFAR-10 dataset shows that, compared to state-of-the-art exact inference, our solutions can feature on average 21% latency reduction.
arXiv Detail & Related papers (2024-09-25T11:10:33Z)
Machine Learning for ALSFRS-R Score Prediction: Making Sense of the Sensor Data [44.99833362998488]
Amyotrophic Lateral Sclerosis (ALS) is a rapidly progressive neurodegenerative disease that presents individuals with limited treatment options. The present investigation, spearheaded by the iDPP@CLEF 2024 challenge, focuses on utilizing sensor-derived data obtained through an app.
arXiv Detail & Related papers (2024-07-10T19:17:23Z)
Center-Sensitive Kernel Optimization for Efficient On-Device Incremental Learning [88.78080749909665]
Current on-device training methods just focus on efficient training without considering the catastrophic forgetting. This paper proposes a simple but effective edge-friendly incremental learning framework. Our method achieves average accuracy boost of 38.08% with even less memory and approximate computation.
arXiv Detail & Related papers (2024-06-13T05:49:29Z)
Sense Less, Generate More: Pre-training LiDAR Perception with Masked Autoencoders for Ultra-Efficient 3D Sensing [0.6340101348986665]
We propose a disruptively frugal LiDAR perception dataflow that generates rather than senses parts of the environment that are either predictable based on the extensive training of the environment or have limited consequence to the overall prediction accuracy. Our proposed generative pre-training strategy for this purpose, called as radially masked autoencoding (R-MAE), can also be readily implemented in a typical LiDAR system by selectively activating and controlling the laser power for randomly generated angular regions during on-field operations.
arXiv Detail & Related papers (2024-06-12T03:02:54Z)
OptiState: State Estimation of Legged Robots using Gated Networks with Transformer-based Vision and Kalman Filtering [42.817893456964]
State estimation for legged robots is challenging due to their highly dynamic motion and limitations imposed by sensor accuracy. We propose a hybrid solution that combines proprioception and exteroceptive information for estimating the state of the robot's trunk. This framework not only furnishes accurate robot state estimates, but can minimize the nonlinear errors that arise from sensor measurements and model simplifications through learning.
arXiv Detail & Related papers (2024-01-30T03:34:25Z)
Quantized Non-Volatile Nanomagnetic Synapse based Autoencoder for Efficient Unsupervised Network Anomaly Detection [0.07892577704654172]
We show that implementing the autoencoder in edge devices capable of learning in real-time is challenging due to limited hardware, energy, and computational resources. We propose a ferromagnetic racetrack with engineered notches hosting a magnetic domain wall (DW) as the autoencoder synapses. Our DW-based approach demonstrates a remarkable reduction of at least three orders of magnitude in weight updates during training compared to the floating-point approach.
arXiv Detail & Related papers (2023-09-12T02:29:09Z)
Label-free timing analysis of SiPM-based modularized detectors with physics-constrained deep learning [9.234802409391111]
We propose a novel method based on deep learning for timing analysis of modularized detectors. We mathematically demonstrate the existence of the optimal function desired by the method, and give a systematic algorithm for training and calibration of the model.
arXiv Detail & Related papers (2023-04-24T09:16:31Z)
Efficient and Robust LiDAR-Based End-to-End Navigation [132.52661670308606]
We present an efficient and robust LiDAR-based end-to-end navigation framework. We propose Fast-LiDARNet that is based on sparse convolution kernel optimization and hardware-aware model design. We then propose Hybrid Evidential Fusion that directly estimates the uncertainty of the prediction from only a single forward pass.
arXiv Detail & Related papers (2021-05-20T17:52:37Z)
Domain Adaptive Robotic Gesture Recognition with Unsupervised Kinematic-Visual Data Alignment [60.31418655784291]
We propose a novel unsupervised domain adaptation framework which can simultaneously transfer multi-modality knowledge, i.e., both kinematic and visual data, from simulator to real robot. It remedies the domain gap with enhanced transferable features by using temporal cues in videos, and inherent correlations in multi-modal towards recognizing gesture. Results show that our approach recovers the performance with great improvement gains, up to 12.91% in ACC and 20.16% in F1score without using any annotations in real robot.
arXiv Detail & Related papers (2021-03-06T09:10:03Z)
Online Body Schema Adaptation through Cost-Sensitive Active Learning [63.84207660737483]
The work was implemented in a simulation environment, using the 7DoF arm of the iCub robot simulator. A cost-sensitive active learning approach is used to select optimal joint configurations. The results show cost-sensitive active learning has similar accuracy to the standard active learning approach, while reducing in about half the executed movement.
arXiv Detail & Related papers (2021-01-26T16:01:02Z)
Development of Use-specific High Performance Cyber-Nanomaterial Optical Detectors by Effective Choice of Machine Learning Algorithms [14.569246848322983]
We show the best choice of ML algorithm in a cyber-nanomaterial detector is mainly determined by specific use considerations. We show by tracking/modeling the long-term drifts of the detector performance over large (1year) period,it is possible to improve the predictive accuracy with no need for recalibration.
arXiv Detail & Related papers (2019-12-26T02:44:55Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.