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About

About

André Dias was born in Porto, Portugal 1980. He finished is lic. degree in Electrical and Electronic Engineering from ISEP Porto Polytechnic School in 2004. He pursue further studies and obtained his Master in Electronics and Computers Engineering, from IST University of Lisbon in 2008. In 2015 graduated (Phd) in Electronics and Computers Engineering, from IST University of Lisbon.
He currently is a professor at the School of Engineering (ISEP) of the Porto Polytechnic Institute (IPP) and senior researcher at the robotics and autonomous systems group of INESC TEC in Portugal, where he is project member in several international FP7, H2020 projects. He is the main author of several research publications in the domains of perception and mobile robotics applications.

Interest
Topics
Details

Details

  • Name

    André Dias
  • Role

    Senior Researcher
  • Since

    01st October 2011
016
Publications

2024

A Survey of Seafloor Characterization and Mapping Techniques

Authors
Loureiro, G; Dias, A; Almeida, J; Martins, A; Hong, SP; Silva, E;

Publication
REMOTE SENSING

Abstract
The deep seabed is composed of heterogeneous ecosystems, containing diverse habitats for marine life. Consequently, understanding the geological and ecological characteristics of the seabed's features is a key step for many applications. The majority of approaches commonly use optical and acoustic sensors to address these tasks; however, each sensor has limitations associated with the underwater environment. This paper presents a survey of the main techniques and trends related to seabed characterization, highlighting approaches in three tasks: classification, detection, and segmentation. The bibliography is categorized into four approaches: statistics-based, classical machine learning, deep learning, and object-based image analysis. The differences between the techniques are presented, and the main challenges for deep sea research and potential directions of study are outlined.

2024

Oil Spill Mitigation with a Team of Heterogeneous Autonomous Vehicles

Authors
Dias, A; Mucha, A; Santos, T; Oliveira, A; Amaral, G; Ferreira, H; Martins, A; Almeida, J; Silva, E;

Publication
JOURNAL OF MARINE SCIENCE AND ENGINEERING

Abstract
This paper presents the implementation of an innovative solution based on heterogeneous autonomous vehicles to tackle maritime pollution (in particular, oil spills). This solution is based on native microbial consortia with bioremediation capacity, and the adaptation of air and surface autonomous vehicles for in situ release of autochthonous microorganisms (bioaugmentation) and nutrients (biostimulation). By doing so, these systems can be applied as the first line of the response to pollution incidents from several origins that may occur inside ports, around industrial and extraction facilities, or in the open sea during transport activities in a fast, efficient, and low-cost way. The paper describes the work done in the development of a team of autonomous vehicles able to carry as payload, native organisms to naturally degrade oil spills (avoiding the introduction of additional chemical or biological additives), and the development of a multi-robot framework for efficient oil spill mitigation. Field tests have been performed in Portugal and Spain's harbors, with a simulated oil spill, and the coordinate oil spill task between the autonomous surface vehicle (ASV) ROAZ and the unmanned aerial vehicle (UAV) STORK has been validated.

2024

Man-Machine Symbiosis UAV Integration for Military Search and Rescue Operations

Authors
Minhoto, V; Santos, T; Silva, LTE; Rodrigues, P; Arrais, A; Amaral, A; Dias, A; Almeida, J; Cunha, JPS;

Publication
ROBOT 2023: SIXTH IBERIAN ROBOTICS CONFERENCE, VOL 2

Abstract
Over the last few years, Man-Machine collaborative systems have been increasingly present in daily routines. In these systems, one operator usually controls the machine through explicit commands and assesses the information through a graphical user interface. Direct & implicit interaction between the machine and the user does not exist. This work presents a man-machine symbiotic concept & system where such implicit interaction is possible targeting search and rescue scenarios. Based on measuring physiological variables (e.g. body movement or electrocardiogram) through wearable devices, this system is capable of computing the psycho-physiological state of the human and autonomously identify abnormal situations (e.g. fall or stress). This information is injected into the control loop of the machine that can alter its behavior according to it, enabling an implicit man-machine communication mechanism. A proof of concept of this system was tested at the ARTEX (ARmy Technological EXperimentation) exercise organized by the Portuguese Army involving a military agent and a drone. During this event the soldier was equipped with a kit of wearables that could monitor several physiological variables and automatically detect a fall during a mission. This information was continuously sent to the drone that successfully identified this abnormal situation triggering the take-off and a situation awareness fly-by flight pattern, delivering a first-aid kit to the soldier in case he did not recover after a pre-determined time period. The results were very positive, proving the possibility and feasibility of a symbiotic system between humans and machines.

2024

Novel Approach for Offshore Photovoltaic Panels Inspection with VTOL UAV

Authors
Morais, R; Martins, JJ; Lima, P; Dias, A; Martins, A; Almeida, J; Silva, E;

Publication
OCEANS 2024 - SINGAPORE

Abstract
Solar energy will contribute to global economic growth, increasing worldwide photovoltaic (PV) solar energy production. More recently, one of the outstanding energy achievements of the last decade has been the development of floating photovoltaic panels. These panels differ from conventional (terrestrial) panels because they occupy space in a more environmentally friendly way, i.e., aquatic areas. In contrast, land areas are saved for other applications, such as construction or agriculture. Developing autonomous inspection systems using unmanned aerial vehicles (UAVs) represents a significant step forward in solar PV technology. Given the frequently remote and difficult-to-access locations, traditional inspection methods are no longer practical or suitable. Responding to these challenges, an innovative inspection framework was developed to autonomously inspect photovoltaic plants (offshore) with a Vertical Takeoff and Landing (VTOL) UAV. This work explores two different methods of autonomous aerial inspection, each adapted to specific scenarios, thus increasing the adaptability of the inspection process. During the flight, the aerial images are evaluated in real-time for the autonomous detection of the photovoltaic modules and the detection of possible faults. This mechanism is crucial for making decisions and taking immediate corrective action. An offshore simulation environment was developed to validate the implemented system.

2024

UAV Visual and Thermographic Power Line Detection Using Deep Learning

Authors
Santos, T; Cunha, T; Dias, A; Moreira, AP; Almeida, J;

Publication
SENSORS

Abstract
Inspecting and maintaining power lines is essential for ensuring the safety, reliability, and efficiency of electrical infrastructure. This process involves regular assessment to identify hazards such as damaged wires, corrosion, or vegetation encroachment, followed by timely maintenance to prevent accidents and power outages. By conducting routine inspections and maintenance, utilities can comply with regulations, enhance operational efficiency, and extend the lifespan of power lines and equipment. Unmanned Aerial Vehicles (UAVs) can play a relevant role in this process by increasing efficiency through rapid coverage of large areas and access to difficult-to-reach locations, enhanced safety by minimizing risks to personnel in hazardous environments, and cost-effectiveness compared to traditional methods. UAVs equipped with sensors such as visual and thermographic cameras enable the accurate collection of high-resolution data, facilitating early detection of defects and other potential issues. To ensure the safety of the autonomous inspection process, UAVs must be capable of performing onboard processing, particularly for detection of power lines and obstacles. In this paper, we address the development of a deep learning approach with YOLOv8 for power line detection based on visual and thermographic images. The developed solution was validated with a UAV during a power line inspection mission, obtaining mAP@0.5 results of over 90.5% on visible images and over 96.9% on thermographic images.

Supervised
thesis

2023

Sistema de perceção visual com recurso a tecnologia de smartphones

Author
SARA RAQUEL MONTEIRO DA SILVA PEREIRA

Institution
IPP-ISEP

2023

Estudo e Implementação de um Sistema de Inspeção de Grades

Author
JOSÉ MIGUEL PINHO SOARES

Institution
IPP-ISEP

2023

Sistema de inspeção autónomo para centrais fotovoltaicas offshore com VTOL

Author
RICARDO ANDRÉ ANES MORAIS

Institution
IPP-ISEP

2023

Indoors Radar Detection - Performance Analysis and Development of Tracking Algorithms

Author
MARTIM COELHO DE MELO

Institution
IPP-ISEP

2023

Deep Learning LiDAR-based Power Lines Detection for Unmanned Aerial Vehicles

Author
TIAGO FRANCISCO PEREIRA CUNHA

Institution
IPP-ISEP