Your search keyword '"Castaño, Fernando [0000-0002-4801-9224]"' showing total 2 results

1. Digital Twin-Based Optimization for Ultraprecision Motion Systems With Backlash and Friction

Author

Rodolfo E. Haber Guerra, Fernando Castaño, Javier Arenas, Alberto Villalonga, Ramón Quiza, Ministerio de Ciencia, Innovación y Universidades (España), European Commission, Haber Guerra, Rodolfo [0000-0002-2881-0166], Quiza, Ramón [0000-0003-1293-6044], Villalonga, Alberto [0000-0002-9268-0175], Castaño, Fernando [0000-0002-4801-9224], Haber Guerra, Rodolfo, Quiza, Ramón, Villalonga, Alberto, and Castaño, Fernando

Subjects

Optimization, 0209 industrial biotechnology, General Computer Science, Computer science, friction, Robótica e Informática Industrial, General Engineering, Process (computing), 02 engineering and technology, 7. Clean energy, Digital twin, Ultraprecision motion system, 020901 industrial engineering & automation, Control theory, Control system, 0202 electrical engineering, electronic engineering, information engineering, Trajectory, 020201 artificial intelligence & image processing, General Materials Science, lcsh:Electrical engineering. Electronics. Nuclear engineering, Backlash, lcsh:TK1-9971, cascade control, Motion system

Abstract

A digital twin-based optimization procedure is presented for an ultraprecision motion system with a flexible shaft connecting the motor to the (elastic) load, which is subject to both backlash and friction. The main contributions of the study are the design of the digital twin and its implementation, assuming a two-mass drive system. The procedure includes the virtual representation of mechanical and electrical components, non-linearities (backlash and friction), and the corresponding control system. A procedure for digital twin-based optimization is also presented, in which the maximum absolute position error is minimized while maintaining accuracy with no significant increase in the control effort. The optimal settings for the controller parameters and for the backlash peak amplitude, the backlash peak time, and the hysteresis amplitude are then determined, in order to guarantee an appropriate dynamic response in the presence of backlash and friction. The surface quality of certain manufactured components, such as hip and knee implants, depends on the smoothness and the accuracy of the real trajectory produced in the cutting process that is strongly influenced by the maximum position error. The simulations and experimental studies are presented using a real platform and two references for trajectory control, and a comparison of four digital twin-based optimization methods. The simulation study and the real-time experiments demonstrate the suitability of the digital twin-based optimization procedure and lay the foundations for the implementation of the proposed method at an industrial level., This work has been completed within the framework of projects DPI2017-86915-C3-1-R “Cognitive inspiration navigation for autonomous driving” and the European Project Grant 826417 “Power2Power: The next-generation silicon-based power solutions in mobility, industry and grid for sustainable decarbonisation in the next decade”.

Published

2019

2. Sensor Reliability in Cyber-Physical Systems Using Internet-of-Things Data: A Review and Case Study

Author

Stanisław Strzelczak, Rodolfo E. Haber, Alberto Villalonga, Joanna Kossakowska, Fernando Castaño, European Commission, Ministerio de Ciencia, Innovación y Universidades (España), Polish National Agency for Academic Exchange, Castaño, Fernando [0000-0002-4801-9224], Villalonga, Alberto [0000-0002-9268-0175], Haber, Rodolfo E. [0000-0002-2881-0166], Kossakowska, Joanna [0000-0002-4519-6225], Castaño, Fernando, Villalonga, Alberto, Haber, Rodolfo E., and Kossakowska, Joanna

Subjects

reinforcement learning, European level, Computer science, Science, Robótica e Informática Industrial, Automotive industry, Reliability assessment, 02 engineering and technology, cyber-physical systems, LiDAR sensor, 7. Clean energy, Obstacle recognition, lidar sensor, Reinforcement learning, 0202 electrical engineering, electronic engineering, information engineering, internet-of-things, Reliability (statistics), artificial intelligence-based modelling, Artificial Intelligence-based modelling, Cyber-Physical Systems, business.industry, driving assistance, Cyber-physical system, 020206 networking & telecommunications, Lidar, Internet-of-Things, obstacle recognition, Key (cryptography), Systems engineering, General Earth and Planetary Sciences, 020201 artificial intelligence & image processing, Driving assistance, Internet of Things, business, reliability assessment

Abstract

Nowadays, reliability of sensors is one of the most important challenges for widespread application of Internet-of-things data in key emerging fields such as the automotive and manufacturing sectors. This paper presents a brief review of the main research and innovation actions at the European level, as well as some on-going research related to sensor reliability in cyber-physical systems (CPS). The research reported in this paper is also focused on the design of a procedure for evaluating the reliability of Internet-of-Things sensors in a cyber-physical system. The results of a case study of sensor reliability assessment in an autonomous driving scenario for the automotive sector are also shown. A co-simulation framework is designed in order to enable real-time interaction between virtual and real sensors. The case study consists of an IoT LiDAR-based collaborative map in order to assess the CPS-based co-simulation framework. Specifically, the sensor chosen is the Ibeo Lux 4-layer LiDAR sensor with IoT added capabilities. The modeling library for predicting error with machine learning methods is implemented at a local level, and a self-learning-procedure for decision-making based on Q-learning runs at a global level. The study supporting the experimental evaluation of the co-simulation framework is presented using simulated and real data. The results demonstrate the effectiveness of the proposed method for increasing sensor reliability in cyber-physical systems using Internet-of-Things data., This work was partially supported by the project Power2Power: Providing next-generation silicon-based power solutions in transport and machinery for significant decarbonisation in the next decade, funded by the Electronic Component Systems for European Leadership (ECSEL-JU) Joint Undertaking and the Ministry of Science, Innovation and Universities (MICINN), under grant agreement No 826417. In addition, this work was also funded by the Spanish Ministry of Science, Innovation and Universities through the project COGDRIVE (DPI2017-86915-C3-1-R). Preparation of this publication was also partially co-financed by the Polish National Agency for Academic Exchange (NAWA) through the project: “Industry 4.0 in Production and Aeronautical Engineering (IPAE)”.

Published

2019