Federico Paredes-Vallés scite author profile

The combination of spiking neural networks and event-based vision sensors holds the potential of highly efficient and high-bandwidth optical flow estimation. This paper presents the first hierarchical spiking architecture in which motion (direction and speed) selectivity emerges in an unsupervised fashion from the raw stimuli generated with an event-based camera. A novel adaptive neuron model and stable spike-timing-dependent plasticity formulation are at the core of this neural network governing its spike-based processing and learning, respectively. After convergence, the neural architecture exhibits the main properties of biological visual motion systems, namely feature extraction and local and global motion perception. Convolutional layers with input synapses characterized by single and multiple transmission delays are employed for feature and local motion perception, respectively; while global motion selectivity emerges in a final fully-connected layer. The proposed solution is validated using synthetic and real event sequences. Along with this paper, we provide the cuSNN library, a framework that enables GPU-accelerated simulations of large-scale spiking neural networks. Source code and samples are available at https://github.com/tudelft/cuSNN. Index Terms-Event-based vision, feature extraction, motion detection, neural nets, neuromorphic computing, unsupervised learning ! • The authors are with the Department of Control and Simulation (Micro Air Vehicle

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Back to Event Basics: Self-Supervised Learning of Image Reconstruction for Event Cameras via Photometric Constancy

Paredes-Vallés

Croon

2021

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Evolved Neuromorphic Control for High Speed Divergence-Based Landings of MAVs

Hagenaars

Paredes-Vallés

Bohté

et al. 2020

IEEE Robot. Autom. Lett.

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Motion Equations and Attitude Control in the Vertical Flight of a VTOL Bi-Rotor UAV

et al. 2019

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This paper gathers the design and implementation of the control system that allows an unmanned Flying-wing to perform a Vertical Take-Off and Landing (VTOL) maneuver using two tilting rotors (Bi-Rotor). Unmanned Aerial Vehicles (UAVs) operating in this configuration are also categorized as Hybrid UAVs due to their ability of having a dual flight envelope: hovering like a multi-rotor and cruising like a traditional fixed-wing, providing the opportunity of facing complex missions in which these two different dynamics are required. This work exhibits the Bi-Rotor nonlinear dynamics, the attitude tracking controller design and also, the results obtained through Hardware-In-the-Loop (HIL) simulation and experimental studies that ensure the controller’s efficiency in hovering operation.

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Self-Supervised Learning of Event-Based Optical Flow with Spiking Neural Networks

Hagenaars¹,

Paredes-Vallés²,

Croon³

2021

Preprint

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