Your search keyword '"Perez-Peña, Fernando"' showing total 4 results

1. Exploiting the PIR Sensor Analog Behavior as Thermoreceptor: Movement Direction Classification Based on Spiking Neurons.

Author

Guerrero-Rodriguez, Jose-Maria, Cifredo-Chacon, Maria-Angeles, Cobos Sánchez, Clemente, and Perez-Peña, Fernando

Subjects

PYROELECTRIC detectors, SENSOR networks, OPTICAL flow, FRESNEL lenses, OPTIC nerve

Abstract

Pyroelectric infrared sensors (PIR) are widely used as infrared (IR) detectors due to their basic implementation, low cost, low power, and performance. Combined with a Fresnel lens, they can be used as a binary detector in applications of presence and motion control. Furthermore, due to their features, they can be used in autonomous intelligent devices or included in robotics applications or sensor networks. In this work, two neural processing architectures are presented: (1) an analog processing approach to achieve the behavior of a presynaptic neuron from a PIR sensor. An analog circuit similar to the leaky integrate and fire model is implemented to be able to generate spiking rates proportional to the IR stimuli received at a PIR sensor. (2) An embedded postsynaptic neuron where a spiking neural network matrix together with an algorithm based on digital processing techniques is introduced. This structure allows connecting a set of sensors to the post-synaptic circuit emulating an optic nerve. As a case study, the entire neural processing approach presented in this paper is applied to optical flow detection considering a four-PIR array as input. The results validate both the spiking approach for an analog sensor presented and the ability to retrieve the analog information sent as spike trains in a simulated optic nerve. [ABSTRACT FROM AUTHOR]

Published

2023

2. Smart Shoe Insole Based on Polydimethylsiloxane Composite Capacitive Sensors.

Author

Luna-Perejón, Francisco, Salvador-Domínguez, Blas, Perez-Peña, Fernando, Corral, José María Rodríguez, Escobar-Linero, Elena, and Morgado-Estévez, Arturo

Subjects

CAPACITIVE sensors, POLYDIMETHYLSILOXANE, INTELLIGENT sensors, DIELECTRIC properties, SHOES

Abstract

Nowadays, the study of the gait by analyzing the distribution of plantar pressure is a well-established technique. The use of intelligent insoles allows real-time monitoring of the user. Thus, collecting and analyzing information is a more accurate process than consultations in so-called gait laboratories. Most of the previous published studies consider the composition and operation of these insoles based on resistive sensors. However, the use of capacitive sensors could provide better results, in terms of linear behavior under the pressure exerted. This behavior depends on the properties of the dielectric used. In this work, the design and implementation of an intelligent plantar insole composed of capacitive sensors is proposed. The dielectric used is a polydimethylsiloxane (PDMS)-based composition. The sensorized plantar insole developed achieves its purpose as a tool for collecting pressure in different areas of the sole of the foot. The fundamentals and details of the composition, manufacture, and implementation of the insole and the system used to collect data, as well as the data samples, are shown. Finally, a comparison of the behavior of both insoles, resistive and capacitive sensor-equipped, is made. The prototype presented lays the foundation for the development of a tool to support the diagnosis of gait abnormalities. [ABSTRACT FROM AUTHOR]

Published

2023

3. Low-Cost Servomotor Driver for PFM Control.

Author

Aragon-Jurado, David, Morgado-Estevez, Arturo, and Perez-Peña, Fernando

Subjects

PULSE frequency modulation, SERVOMECHANISMS, ROBOTICS, PULSE width modulation, FEEDBACK control systems

Abstract

Servomotors have already been around for some decades and they are extremely popular among roboticists due to their simple control technique, reliability and low-cost. They are usually controlled by using Pulse Width Modulation (PWM) and this paper aims to keep the idea of simplicity and low-cost, while introducing a new control technique: Pulse Frequency Modulation (PFM). The objective of this paper is to focus on our development of a low-cost servomotor controller which will allow the research community to use them with PFM. A low-cost commercial servomotor is used as the base system for the development: a small PCB that fits inside the case and allocates all the electronic components to control the motor has been designed to replace the original. The potentiometer is retained as the feedback sensor and a microcontroller is responsible for controlling the position of the motor. The paper compares the performance of a PWM and a PFM controlled servomotor. The comparison shows that the servomotor with our controller achieves a faster mechanism for switching targets and a lower latency. This controller can be used with neuromorphic systems to remove the conversion from events to PWM. [ABSTRACT FROM AUTHOR]

Published

2018

4. Neuro-Inspired Spike-Based Motion: From Dynamic Vision Sensor to Robot Motor Open-Loop Control through Spike-VITE.

Author

Perez-Peña, Fernando, Morgado-Estevez, Arturo, Linares-Barranco, Alejandro, Jimenez-Fernandez, Angel, Gomez-Rodriguez, Francisco, Jimenez-Moreno, Gabriel, and Lopez-Coronado, Juan

Subjects

*IMAGE sensors, *OPTICAL sensors, *DETECTORS, *ROBOTICS research, *ROBOTS

Abstract

In this paper we present a complete spike-based architecture: from a Dynamic Vision Sensor (retina) to a stereo head robotic platform. The aim of this research is to reproduce intended movements performed by humans taking into account as many features as possible from the biological point of view. This paper fills the gap between current spike silicon sensors and robotic actuators by applying a spike processing strategy to the data flows in real time. The architecture is divided into layers: the retina, visual information processing, the trajectory generator layer which uses a neuroinspired algorithm (SVITE) that can be replicated into as many times as DoF the robot has; and finally the actuation layer to supply the spikes to the robot (using PFM). All the layers do their tasks in a spike-processing mode, and they communicate each other through the neuro-inspired AER protocol. The open-loop controller is implemented on FPGA using AER interfaces developed by RTC Lab. Experimental results reveal the viability of this spike-based controller. Two main advantages are: low hardware resources (2% of a Xilinx Spartan 6) and power requirements (3.4 W) to control a robot with a high number of DoF (up to 100 for a Xilinx Spartan 6). It also evidences the suitable use of AER as a communication protocol between processing and actuation. [ABSTRACT FROM AUTHOR]

Published

2013