Your search keyword '"Çatal, Ozan"' showing total 4 results

1. FMCW Radar Sensing for Indoor Drones Using Learned Representations

Author

Safa, Ali, Verbelen, Tim, Catal, Ozan, Van de Maele, Toon, Hartmann, Matthias, Dhoedt, Bart, and Bourdoux, André

Subjects

Computer Science - Robotics, Electrical Engineering and Systems Science - Signal Processing

Abstract

Frequency-modulated continuous-wave (FMCW) radar is a promising sensor technology for indoor drones as it provides range, angular as well as Doppler-velocity information about obstacles in the environment. Recently, deep learning approaches have been proposed for processing FMCW data, outperforming traditional detection techniques on range-Doppler or range-azimuth maps. However, these techniques come at a cost; for each novel task a deep neural network architecture has to be trained on high-dimensional input data, stressing both data bandwidth and processing budget. In this paper, we investigate unsupervised learning techniques that generate low-dimensional representations from FMCW radar data, and evaluate to what extent these representations can be reused for multiple downstream tasks. To this end, we introduce a novel dataset of raw radar ADC data recorded from a radar mounted on a flying drone platform in an indoor environment, together with ground truth detection targets. We show with real radar data that, utilizing our learned representations, we match the performance of conventional radar processing techniques and that our model can be trained on different input modalities such as raw ADC samples of only two consecutively transmitted chirps.

Published

2023

2. Towards bio-inspired unsupervised representation learning for indoor aerial navigation

Author

Wang, Ni, Catal, Ozan, Verbelen, Tim, Hartmann, Matthias, and Dhoedt, Bart

Subjects

Computer Science - Robotics, Computer Science - Artificial Intelligence

Abstract

Aerial navigation in GPS-denied, indoor environments, is still an open challenge. Drones can perceive the environment from a richer set of viewpoints, while having more stringent compute and energy constraints than other autonomous platforms. To tackle that problem, this research displays a biologically inspired deep-learning algorithm for simultaneous localization and mapping (SLAM) and its application in a drone navigation system. We propose an unsupervised representation learning method that yields low-dimensional latent state descriptors, that mitigates the sensitivity to perceptual aliasing, and works on power-efficient, embedded hardware. The designed algorithm is evaluated on a dataset collected in an indoor warehouse environment, and initial results show the feasibility for robust indoor aerial navigation.

Published

2021

3. LatentSLAM: unsupervised multi-sensor representation learning for localization and mapping

Author

Çatal, Ozan, Jansen, Wouter, Verbelen, Tim, Dhoedt, Bart, and Steckel, Jan

Subjects

Computer Science - Robotics, Computer Science - Artificial Intelligence

Abstract

Biologically inspired algorithms for simultaneous localization and mapping (SLAM) such as RatSLAM have been shown to yield effective and robust robot navigation in both indoor and outdoor environments. One drawback however is the sensitivity to perceptual aliasing due to the template matching of low-dimensional sensory templates. In this paper, we propose an unsupervised representation learning method that yields low-dimensional latent state descriptors that can be used for RatSLAM. Our method is sensor agnostic and can be applied to any sensor modality, as we illustrate for camera images, radar range-doppler maps and lidar scans. We also show how combining multiple sensors can increase the robustness, by reducing the number of false matches. We evaluate on a dataset captured with a mobile robot navigating in a warehouse-like environment, moving through different aisles with similar appearance, making it hard for the SLAM algorithms to disambiguate locations., Comment: Accepted for publication at IEEE ICRA2021

Published

2021

4. Learning to Catch Piglets in Flight

Author

Çatal, Ozan, De Mol, Lawrence, Verbelen, Tim, and Dhoedt, Bart

Subjects

Computer Science - Robotics, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

Catching objects in-flight is an outstanding challenge in robotics. In this paper, we present a closed-loop control system fusing data from two sensor modalities: an RGB-D camera and a radar. To develop and test our method, we start with an easy to identify object: a stuffed Piglet. We implement and compare two approaches to detect and track the object, and to predict the interception point. A baseline model uses colour filtering for locating the thrown object in the environment, while the interception point is predicted using a least squares regression over the physical ballistic trajectory equations. A deep learning based method uses artificial neural networks for both object detection and interception point prediction. We show that we are able to successfully catch Piglet in 80% of the cases with our deep learning approach., Comment: Fast Neural Perception and Learning for Intelligent Vehicles and Robotics workshop at IROS 2019

Published

2020