Paulo Santos

I was born in Oporto, Portugal, in 1958. I was graduatedi n Electrical Engineering in 1981 at Opoto University, and received the MSc degree in Computers and Digital Systems in 1987, the Ph.D. degree in Electrical Engineering in 1994 and the Agregado degree in 2016, all fromOporto University. From 1983 to 1994 I worked as an assistant lecturer in the Electrical Engineering Department of the Oporto University. In 1985 I started a full-time academic career, and presently I am a Lecturer in Electrical Engineering at the same University.

From 1985 to 1989 I developed his research in INESC. I moved d to the Institute for Systems and Robotics- Oporto (ISRP) in 1989 where I stayed until 2018. I have joined the INESC TEC in 2018.

My research interests are Control, Estimation, Dynamical Systems Identification including multi-dimensional systems, with applications ranging from Bimedical Systems to Energy Systems.

I am author and co-author of dozens of papers published in international journals and proceedings of international conferences. I am a member of the the Portuguese Association of Automatic Control (APCA), IEEE CST and of the IEEE CST International Technical Committee on Systems Identification and Adaptive Control, the IEEE CST International Technical Committee on Health and Medical Systems TC and of the IFAC (International Federation on Automatic Control) Technical Committee on Signal Processing.

Domains

Robotics and Autonomous Systems Bioengineering Power and Energy Systems Robotics

Projects

SAFEWATER

Water pollution is a severe worldwide problem that urgently requires development of novel sensing concepts allowing for monitoring contaminants at very low concentrations.The ambitious aim of the SAFE WATER project is to design, implement and validate a new portable optical instrument, for in situ and multiplexing detection and determination of several emerging microcontaminants (EMCs) like estrogens, pharmaceuticals, drugs and new generation pesticides which represent contaminants that have recently joined the European Union (EU) watching list on the monitoring of water quality. The heart and the novelty of such proposed prototype consist in the use of special hollow – core whispering gallery modes (WGM) microcavities – named optical microbubble resonators (OMBRs) for their particular geometry – able to show a high value for their quality factor Q (> 10^7, in air) and, consequently, guarantee high sensitivity and extremely low threshold for the limit of detection LOD (down to pg/L). For the selective recognition of different pollutants, the inner surface of these microresonators will be coated with films of molecularly imprinted polymers (MIPs) or functionalized with specific antibodies. The basic modules of the platform will include (i) a WGM microbubble resonator array integrated on one silicon chip as the optical sensing element capable of multiplexed pollutant determination, (ii) the microfluidic circuit, in which the liquid pollutant sample is initially mixed with the reagents required, and then directed to the integrated chip for optical determination, and (iii) the optoelectronic system for the interrogation of the WGM array and the data acquisition. Finally, these modules will be fully integrated in the prototype, which will be used for the determination of contaminants in water samples.

On chip whispering gallery mode optical microcavities for emerging microcontaminant determination in waters

INTENDU

Integrated Technologies Longterm Deployment of Robotic Underwater platforms

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Publications

Kalman filter for noise reduction of Li-Ion cell discharge current

dos Santos, PL;Perdicoulis, TPA;Salgado, PA;Azevedo, JC;

2023

IFAC PAPERSONLINE

Non-parametric Gaussian process kernel DMD and LS-SVM predictors revisited A unifying approach

dos Santos, PL;Azevedo-Perdicoulis, TP;Salgado, PA;

2023

IFAC PAPERSONLINE

A Dynamic Mode Decomposition Approach With Hankel Blocks to Forecast Multi-Channel Temporal Series

Vasconcelos, E;dos Santos, PL;

2019

IEEE CONTROL SYSTEMS LETTERS

Modelling a gas pipeline as a repetitive process: controllability, observability and stability

Azevedo Perdicoúlis, TP;Jank, G;dos Santos, PJL;

2015

Multidimens. Syst. Signal Process.

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Centres

Robotics and Autonomous Systems

The Centre for Robotics and Autonomous Systems (CRAS) focuses on developing innovative robotic solutions for operation in complex environments. Each day, our researchers strive to map the unknown, creating solutions to explore the oceans’ depths, monitor the environment, or inspect infrastructures. Our goal? To become a global reference in robotics and autonomous systems, combining expertise in multisensory perception and 3D modelling, navigation and control, robotic manipulation and intervention - pushing the boundaries of autonomous robotics and integrating aerial, ground, and underwater robots into our solutions. Focusing on Technology Readiness Levels (TRL) between 5 and 8, CRAS develops prototypes and operational solutions for strategic sectors. Our laboratory infrastructure includes test tanks, prototyping workshops, and a wide range of equipment ready to operate in real-world environments. Our researchers also resort to Mar Profundo, a support vessel for testing and validating innovative maritime technologies - a key asset in bridging theoretical design and field validation. CRAS stands out for a practical approach: we combine advanced research with a strong focus on real-world applications, reducing human risk in hazardous missions, optimising operations and processes, and expanding the frontiers of autonomous robotics.