{"id":202,"date":"2015-06-25T15:55:47","date_gmt":"2015-06-25T15:55:47","guid":{"rendered":"http:\/\/www.campusenergiainteligente.es\/?page_id=202"},"modified":"2021-06-16T08:40:47","modified_gmt":"2021-06-16T08:40:47","slug":"grupos-de-investigacion","status":"publish","type":"page","link":"https:\/\/www.campusenergiainteligente.es\/en\/investigacion-y-transferencia\/grupos-de-investigacion\/","title":{"rendered":"Research Groups"},"content":{"rendered":"

<\/p>\n

URJC EXCELLENCE<\/h2>\n

 <\/p>\n\n\n\n\n\n\n\n\n\n\n\n\n\n
Doctorate Supervisor Contact<\/td>\nURJC EXCELLENCE RESEARCH GROUPS<\/td>\nSCIENTIFIC RESEARCH LINES<\/td>\n<\/tr>\n
Marcos Mart\u00ednez, Esperanza; esperanza.marcos@urjc.es<\/td>\nGroup of Excellence in Service Science, Management and Engineering (GES2ME)<\/td>\nSmart Transport. Servitization. Strategic management of knowledge and innovation. Interaction Management. Advertising and media.<\/td>\n<\/tr>\n
Fajardo Gonz\u00e1lez, Mariano; mariano.fajardo@urjc.es<\/td>\nKing Juan Carlos University Chemical Compounds and Nanostructured Materials in Advanced Applications Group (QUINANOAP)<\/td>\nThe preparation, characterisation, and study of the catalytic properties of new metal complexes and nanostructured materials. The preparation, characterisation, and study of the biological properties of new metal complexes and nanostructured materials. The production of polymer biomaterials via heteroscorpionate complexes of group 2 metals and analogues. The synthesis, characterisation, and optoelectronic applications of new molecular organic materials. The study of the molecular bases of the relationship between diabetes and cancers. The study of metabolic therapeutic targets. Cell death studies. The optic characterisation of organic materials and photoluminescent organometallics and the manufacturing and electro-optical characterisation of nanostructured organic electroluminescent devices. The mathematical modelling of real physical and biological processes; non-linear systems; precise solutions; numerical calculation; soliton equations. Self-healing materials.<\/td>\n<\/tr>\n
Rams Ramos, Joaqu\u00edn; joaquin.rams@urjc.es<\/td>\nThe Materials Science and Engineering group (CIM)<\/td>\nLight alloys for transport. Modification and coating of magnesium alloys for use in the transport industry. Development of Al-SiC composite materials for applications in the automotive sector. PROCESSING AND CHARACTERIZATION OF POLYMER MATRIX COMPOSITES AND MATERIALS NANOCOMPOSITES. Manufacture of epoxy matrix materials nanorreforzados with CNF and CNT. Development of nanoreinforced conductive adhesives. Manufacturing of composite materials with multiscale reinforcement. Application of multifunctional composite materials for applications in structural health monitoring (SHM). Nanostructured epoxy resins based on addition of thermoplastic block copolymers.<\/td>\n<\/tr>\n
Maestre Gil, Fernando; Tom\u00e1s, fernando.maestre@urjc.es<\/td>\nGlobal Change and Ecosystem Impacts (CAMGLO)<\/td>\nClimate change and ecosystem processes. Impacts of global change on biodiversity and forest ecosystems. Biotechnology and Global Change.<\/td>\n<\/tr>\n
Criado Herrero, Regino; regino.criado@urjc.es<\/td>\nComplex Networks in Sciences, Society, and Technology Analysis Group (GARECOM)<\/td>\nStructural analysis and complex modelling and socioeconomic networks. Biological network analysis, modelling, and testing. Data and Security Network Analysis. Smart cities transport network analysis.<\/td>\n<\/tr>\n
Rodr\u00edguez P\u00e9rez, Jes\u00fas; jesus.rodriguez.perez@urjc.es<\/td>\nExperimental and computational mechanics: simulation and analysis (GMEC)<\/td>\nDeformation and mechanical integrity of materials.<\/td>\n<\/tr>\n
Ramos L\u00f3pez, Francisco Javier; javier.ramos@urjc.es<\/td>\nInformation and Communications Technologies (ICT)<\/td>\nICT for Biomedical Engineering. ICT for development. Networking Signal Processing. Aerospace Engineering. The Internet of the future. Distributed Systems. Free software.<\/td>\n<\/tr>\n
Hern\u00e1ndez Tamames, Juan Antonio; juan.tamames@urjc.es<\/td>\nComputer Vision and Image Processing (CVIP)<\/td>\nMathematical methods applied to machine vision. Medical Imaging. Facial analysis in images and video. Information technology biometrics. High Performance Computation and Robotic and home automation optimisation. Remote sensing imaging analysis applied to geology.<\/td>\n<\/tr>\n
Guillermo Calleja Pardo; guillermo.calleja@urjc.es<\/td>\nChemical and Environmental Engineering Group (GIQA)<\/td>\nBiomass and Bioenergy. Production, Characterization and Polymer Recycling. Environmental Management and Technology. Sustainable Energy Technologies for Fossil Fuels. Hydrogen Production and Storage. Water Treatment.<\/td>\n<\/tr>\n
R\u00edos Insua, David; david.rios@urjc.es<\/td>\nURJC Applied Social Research Methods Group (METHAODOS.ORG)<\/td>\nStatistical Methods for Risk Analysis. Analytics, Data Mining, and Big Data. Optimisation Methods and the Decision Sciences. Sociology, Applied communication, and Culture.<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

UAH RESEARCH GROUPS<\/h1>\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n
Research Group Directors contact information<\/td>\nUAH Research Groups<\/td>\nResearch Lines<\/td>\n<\/tr>\n
Fernando Cruz Rold\u00e1n fernando.cruz@uah.es<\/td>\nCOMB: Communications, Multirate Signal Processing and Biomedical Engineering<\/td>\n\n

Among the thematic areas of the CEI, the COMB research group focuses its scientific activity in the design and implementation of several narrow and broadband transmission techniques through the power line, using channel partitioning methods such as multicarrier or single carrier modulations with redundant samples.
\nPower line communications (PLC) have multiple applications and advantages, and are therefore a technology of growing scientific and industrial interest. These technologies allow in-door broadband coverage for buildings taking advantage of the existing electrical wiring, and also allow interconnecting all electronic equipment, which enables remote control. These technologies can also be applied to platforms, such as vehicles, ships or aircraft, reducing wiring and consequently, the weight and cost of manufacture.
\nCOMB research group studies several issues of communications over the power line network for in-door and platforms, considering both narrow and broadband communications, in the context of Smart Grid. Our research focuses on the medium access techniques recommended in standards, such as OFDM, with and without windowing, and Wavelet OFDM, based on a cosine modulated filter banks.
\nAnother innovative research of the group is the proposal of alternative mediuam access techniques, which provide substantial improvements. Among them, the use of discrete trigonometric transforms (DTTs) and filter banks with redundancy. All the above techniques are also applicable to communications between vehicles.
\nOur main research lines include but are not limited to the following:
\n\u2022 Design of transceivers for narrow and broadband power line communications, in-doors and platforms.
\n\u2022 Channel estimation and synchronization techniques for single- and multi-carrier systems.
\n\u2022 Signal Processing in broadband communications.<\/p>\n<\/td>\n<\/tr>\n

Cervera Sarda, Mar\u00eda; Rosarosa.cervera@uah.es<\/td>\nECO-FUTURING: Green City Design Laboratory<\/td>\n\n

The Research Group\u2019s main study area involves analysing cities with respect to environmental impact and proposing alternatives that improve energy efficiency in urban areas.
\nRedefining the city model is one of the major challenges of the 21st century. The energy consumed in today\u2019s urban areas and the effects of harmful emissions produced from both buildings and transportation mean new alternatives are required to strike a balance between the environment and the improvement of citizens’ quality of life. The current way results in the systematic destruction of the environment, and whether we humans will be able to survive without the environment is unknown.
\nA priority target is to review the different urban networks and layouts, and assess their consumption and emissions. The Research Group will also develop sustainability indicator studies, using the results to assess their suitability and to put new proposals forward. The study of urban mobility and infrastructure-related aspects is considered essential, given they are largely responsible for the city\u2019s structure and, as such, whether or not an efficient city is built. This will be concluded with case studies, reviewing cities or urban areas that have implemented or are in the process of implementing new alternative policies to transform the concept of a \u201cbrown city\u201d to a \u201cgreen city\u201d, or an energy consuming city to an energy producing city and an environmental balance.
\nThe group\u2019s main research lines are as follows:
\n\u2022 Urban Sustainability Indicators
\n\u2022 Consolidated City adaptation to the new Sustainability challenges of the 21st Century
\n\u2022 An analysis of the urban fabric in terms of its environmental impact
\n\u2022 The concept of Networks in Urban Morphology
\n\u2022 Case Studies
\n\u2022 Sustainable Urban Infrastructures
\n\u2022 Mobility and Urban Transport<\/p>\n

\u2022 Indicadores de Sostenibilidad Urbana.<\/p>\n

\u2022 Adaptaci\u00f3n de la Ciudad Consolidada a los nuevos retos de Sostenibilidad del Siglo XXI.<\/p>\n

\u2022 An\u00e1lisis de tramas urbanas en relaci\u00f3n con su impacto ambiental.<\/p>\n

\u2022 El concepto de Redes en la Morfolog\u00eda Urbana.<\/p>\n

\u2022 Estudio de Casos.<\/p>\n

\u2022 Infraestructuras Urbanas Sostenibles.<\/p>\n

\u2022 Movilidad y Transporte urbano.<\/p>\n<\/td>\n<\/tr>\n

Salcedo Sanz, Sancho;
\nsancho.salcedo@uah.es<\/td>\n		GHEODE: Modern Heuristic Optimisation Techniques and Communications Network Design<\/td>\nBasic research into the modern heuristic optimisation techniques, essentially evolutionary and heuristic computation techniques. Without ruling out any other possibility, the first line of applications involve optimisation and communications network design issues.<\/td>\n<\/tr>\n
Garc\u00eda Barriocanal, Elena;
\nelena.garciab@uah.es<\/td>\n		Information Engineering Research Unit<\/td>\nHighly productive development and research group, whose main objective is to bring technology closer to both people\u2019s and organisations\u2019 needs, providing custom applications on demand, creating simple and functional solutions, and providing services adaptable to different contexts and preferences.
\nThe group\u2019s main research lines are as follows:
\n\u2022 Automatic learning and knowledge engineering
\n\u2022 Software engineering and Information systems engineering
\n\u2022 Educational technology and knowledge management<\/td>\n<\/tr>\n
Velasco P\u00e9rez, Juan Ram\u00f3n;
\njuanramon.velasco@uah.es<\/td>\n		Telematic Services Engineering<\/td>\n\n

The GIST research group is comprised of three research units:
\nIKACS (Intelligence, Knowledge, Agents and Complex Systems). This unit works in the general field of Applied Artificial Intelligence, undertaking research work and developing complex systems in the optimisation field, essentially in vehicle networks, telematic service personalisation, and knowledge based systems.
\nNETSERV (Networks & Services). This unit researches and implements devices and protocols for campus and metropolitan Advanced Ethernet Networks, layer two routing in wired and wireless networks, service quality and MPLS applications, and modelling to access mobile networks.
\nNESIS (Network Systems and information Security). This unit works on security solutions, which include both data protection with cryptographic tools as well as the monitoring and protection of information technology devices.
\nThe group\u2019s main research lines are as follows:
\n\u2022 Agents and multiagent systems
\n\u2022 Analysis and modelling of mobile networks
\n\u2022 MPLS technology applications
\n\u2022 Network service quality
\n\u2022 Applied artificial intelligence
\n\u2022 Automated negotiation
\n\u2022 Complex systems optimisation
\n\u2022 Markov decision processes. Reinforcement learning
\n\u2022 Vehicle networks
\n\u2022 Mobile scenario security (ad-hoc networks, vehicle networks, Smart Spaces)
\n\u2022 Web Services
\n\u2022 Knowledge based systems
\n\u2022 Security management methodologies and systems, and Security auditing
\n\u2022 Cryptographic solutions for corporate and academic domains
\n\u2022 Wireless, Mesh and vehicle networks<\/p>\n<\/td>\n<\/tr>\n

Mazo Quintas, Manuel R.;
\njesus.urena@uah.es<\/td>\n		GEINTRA: Electronic engineering applied to Smart Spaces and Transport<\/td>\n\n

Audiovisual Sensory Systems:
\n\u2022 The detection, location, monitoring, and identification of objects and persons in smart spaces using audio-visual fusion
\n\u2022 Audio-visual human-machine interaction in smart spaces
\n\u2022 Railway infrastructure security, monitoring, and control
\n\u0095Ultrasound and radiofrequency sensory systems:
\n\u2022 Local positioning systems (LPS) and relative positioning systems
\n\u2022 Advanced sensory systems for mobile robots
\n\u2022 The use of ultrasound in subaquatic environments
\n\u0095Infrared sensory systems
\n\u2022 Sensory systems based on infrared for metrology, localisation, and mobile positioning in smart spaces
\n\u2022 Training systems and image transfer systems via optic fibre
\n\u0095Network control systems or NCS-y network control systems in real time. Application to ITS (Intelligent Transportation Systems):
\n\u2022 Cooperative guiding in ITS. Smart alternative route choice
\n\u2022 Diagnostic systems and failure prevention in railway electric substations
\n\u0095Support systems and products or Human-Machine Interfaces in support applications and personal robotics:
\n\u2022 Localisation and mobility systems in support applications and personal robotics
\n\u0095The design, implementation, and testing of electronic systems for:
\n\u2022 Tools and methodologies for automating SoC design and development
\n\u2022 Scalable architecture with high calculating power based on clusters for parallel processing, using commercial platforms
\n\u2022 Sensory platforms and systems based on FPGAs for image and signal processing
\n\u0095Electronics and communications in smart spaces and transport systems
\n\u2022 Sensor and communications networks for smart spaces
\n\u2022 Auxiliary systems for High Speed Lines
\n\u2022 Track circuits and track safety systems<\/p>\n<\/td>\n<\/tr>\n

Rodr\u00edguez S\u00e1nchez, Francisco Javier;
\nfranciscoj.rodriguez@uah.es<\/td>\n		GEISER: Electronic engineering applied to renewable energy systems<\/td>\n\n

Application of measurement electronics, control, communications, and power to renewable energy systems.
\nThe group\u2019s main research lines are as follows:
\n\u2022 Circuit designs
\n\u2022 Control devices
\n\u2022 Control electrical equipment
\n\u2022 Unconventional energy sources
\n\u2022 Energy generation
\n\u2022 Control engineering<\/p>\n<\/td>\n<\/tr>\n

Sotelo V\u00e1zquez, Miguel A.;
\nmiguel.sotelo@uah.es<\/td>\n		Innovative Sensing and Intelligent Systems<\/td>\nTheir activity is undertaken in the area of latest generation sensors to develop high resolution, three dimensional, sensing systems. Additionally, this line of research is aimed at creating sensory systems for use in energy efficiency improvement within the framework of the smart cities of the future. Analysis and interpretation systems use the data provided from the advanced sensory systems based on machine learning techniques and smart systems. Developing this type of systems, heavily based on collective learning algorithms, is the key aim of this group\u2019s research.<\/td>\n<\/tr>\n
Ch\u00edas Navarro, Pilar;
\npilar.chias@uah.es<\/td>\n		IPAS: Heritage Intervention and Sustainable Architecture<\/td>\n\n

The group\u2019s main research lines are as follows:
\n\u2022 Refitting architecture and the city for the disabled
\n\u2022 The application of perceptive qualitative aspects in urban planning
\n\u2022 Sustainable Architecture. Ecodesign
\n\u2022 Heritage intervention. Intervention techniques
\n\u2022 Foundations intervention
\n\u2022 Cultural Interest Asset Inventory
\n\u2022 Sound and Visual Perception in Architecture and the City Research Laboratory (LIPSVAC)
\n\u2022 Soundscapes
\n\u2022 Geographical Hypermedia Information Systems<\/p>\n<\/td>\n<\/tr>\n

Guti\u00e9rrez Mart\u00ednez, Jos\u00e9 Mar\u00eda;
\njosem.gutierrez@uah.es<\/td>\n		Smart Mobile Platforms<\/td>\nResearch and development into new mobile platforms to improve process efficiency. The group\u2019s approach targets the development of software components and their integration. Advanced data processing using these technologies will enable knowledge management to go further than simply data processing.
\n\u2022 Data transfer devices
\n\u2022 Software Project Management
\n\u2022 Software engineering and Information systems engineering<\/p>\n

\n<\/td>\n<\/tr>\n

Maldonado Basc\u00f3n, Saturnino;
\nsaturnino.maldonado@uah.es<\/td>\n		Multisensory Analysis and Recognition (GRAM)<\/td>\n\n

The group has extensive experience in developing and implementing algorithms for advanced image processing and machine vision. The group has successfully worked with images and video sequences from infra-red cameras, time-of-flight cameras (ToF), gas sensors or liquid sensors. Similarly, they have extensive experience in developing pattern recognition algorithms applied to analysing and classifying signals coming from the aforementioned sensors.
\nSome of the most important applications tackled by this research group include:
\n\u2022 An analysis of road infrastructures through digital image processing, providing a range of solutions to the following problems:
\n\u2022 Traffic sign detection and recognition.
\n\u2022 Vehicle class detection and recognition.
\n\u2022 Asphalt condition analysis.
\n\u2022 Traffic sign retroreflectivity calculation.
\n\u2022 Vehicle number plate recognition.
\n\u2022 Development of smart surveillance video systems, dealing with the following issues:
\n\u2022 Detection and recognition of object types in complex scenes.
\n\u2022 Recognition of journeys and activities in dynamic environments.
\n\u2022 An estimation of the posture of objects in the urban setting.
\n\u2022 Recognition of objects from time-of-flight camera point clouds.<\/p>\n<\/td>\n<\/tr>\n

Bergasa Pascual, Luis M.;
\nluism.bergasa@uah.es<\/td>\n		Service Robotics and Road Safety Technologies<\/td>\n\n

The group\u2019s main objective is to study and research in the fields of Service Robotics and Road Safety. On the one hand, the aim is to develop basic research that can become consolidated science over the years, and as such, create new knowledge in the proposed study areas. On the other, application of consolidated knowledge from the research group\u2019s previous work is considered a priority. Technology Transfer is a basic aim for the group for that precise reason, and in fact, fluid collaboration is currently ongoing with companies in both the Automotive sector and Service Robotics sector. The following specific areas are included:
\n-Smart control applied to robotics
\n-Multisensory perception systems (machine vision and others)
\n-Localisation systems, mapping, and navigation of mobile robots in indoor and outdoor environments
\n-Advanced assisted driving systems
\n-Transport infrastructure monitoring systems
\n-Road infrastructure inspection system
\n-Automatic vehicle driving
\nThe group has developed a range of technologies which include:
\n-Lane departure warnings and ACC using vision and laser
\n-Pedestrian and traffic sign detection and recognition
\n-Blind spot vehicle detection
\n-Drowsiness and distraction detection in both drivers and passengers
\n-Automatic switching between full and dipped beam vehicle lights
\n-Road potholes detection
\n-Automatic vertical and gantry sign inspection on roads
\n-Intersection monitoring and automatic traffic light activation
\n-An autonomous robotic system to help elderly people: autonomous navigation and automatic monitoring
\n-Guidance for blind persons using visual maps and semantic information<\/p>\n<\/td>\n<\/tr>\n

Rodr\u00edguez Moreno, M.; Dolores
\nmdolores@aut.uah.es<\/td>\n		Smart Systems<\/td>\n\n

The group\u2019s main aim is to study and apply smart systems to the field of wireless and self-regulating personal communications. The aim is to fully implement mobile and multi-user mobile communications systems, from their initial design until they are fully operational. The most modern and functional hardware like Bluetooth, Wi-Fi, RFID, etc. will be used to that end. With respect to software, Artificial Intelligence techniques will be used, such as Planning and Scheduling and simulation applications. Some members of the group have completed these types of developments in spatial applications.
\nThe group\u2019s main research lines are as follows:
\n\u2022 Application of artificial intelligence systems to real domains such as: work flow, web, spatial missions or e-Learning
\n\u2022 Final applications of wireless communication technologies
\n\u2022 Implementation of OSI level internal communication architectures
\n\u2022 Integration of smart systems in lower communication levels
\n\u2022 Artificial intelligence: planning, scheduling, monitoring, and replanning
\n\u2022 Automatic reasoning
\n\u2022 Multi-user communication systems and socio-environmental intelligence, the scaling up of current techniques and methodologies to high density environments<\/p>\n<\/td>\n<\/tr>\n

Jarabo Amores, M. Pilar;
\nmpilar.jarabo@uah.es<\/td>\n		High Frequency Technologies (GTAF)<\/td>\nThe High Frequency Technologies Group (GTAF) came into being in September 2006 as part of the University of Alcal\u00e1 (UAH) Signalling and Communications Theory Department, through the collaboration of several professors from the aforementioned department with research lines in the high frequency technologies area.
\nThe GTAF\u2019s research activity falls within the area of communication systems design, radiodetermination and radar:
\n– Acquired signal processing with active and passive radar sensors (conventional, HRR, SAR, and ISAR) in detection, classification, and monitoring tasks.
\n– Electromagnetic field propagation and dispersion.
\n– Microwave circuits design: antennas, transmitters and receivers.
\n– Digital communications system design. Software-defined radio.
\n– Electromagnetic compatibility.<\/p>\n

\n<\/td>\n<\/tr>\n

Azqueta Oyarzun, Diego;
\ndiego.azqueta@uah.es<\/td>\n		Environmental Economy<\/td>\nEnvironmental economy is a sub-discipline that aims to use economic analysis to focus on the adverse environmental effects of production processes and goods and services consumption, and put forward economic tools to prevent and manage environmental impacts. Important concepts to know for the first area include externalities, market failures, property rights (public assets and free access resources), the highest level of environmental degradation, and the total economic value. When it comes to actual problem solving applications, the basic framework to help decision making is through cost-benefit analysis (complemented with economic evaluation techniques specially developed for the environmental economy) and the effects of a set of financial tools (taxes, subsidies, tradable permits, etc.) on economic agent behaviour are also known. Overall, it can be said that the foundations and tools of environmental economy are based around the idea of estimating the impacts of environmental quality changes on wellbeing.
\nThe group\u2019s main research lines are as follows:
\n\u2022 The analysis of public policies with environmental implications
\n\u2022 Environmental and natural resources accounting
\n\u2022 The energy economy
\n\u2022 The water economy
\n\u2022 Economic evaluation of ecosystem services<\/p>\n

\n<\/td>\n<\/tr>\n

Esteve N\u00fa\u00f1ez, Abraham;
\nabraham.esteve@uah.es<\/td>\n		Bioelectrogenesis<\/td>\nThe idea of renewable energy sources could be impacted by a recent and exciting discovery, bioelectrogenesis, a process whereby bacteria can directly transfer electrons to conducting surfaces such as graphite, meaning clean energy can be stored.
\nOur activity is particularly focused on researching and developing bioelectrogenic devices with the aim of understanding bacteria-electrode interaction, but also includes a strong practical component. We strongly believe that investing time to study aspects of this new technology will accelerate its development.
\nThe group\u2019s main research lines are as follows:
\n\u2022 Physiology and Biochemistry of microbial electrogenesis aimed at understanding the exocelular transfer of electrons, to identify electrogenic biomolecules in the bacterial membrane, to optimise bacteria-electrode interaction using nanotechnology, and to study microbial electrogenesis from Systems Biology.
\n\u2022 Environmental microbial electrogenesis aimed at studying microbial electrogenesis in natural environments, to stimulate biorecovery in situ with pollutants, to characterise electrogenic populations in natural environments, to investigate electrogenic bacteria-plant interaction.
\n\u2022 Microbial electrogenesis and bioengineering aimed at developing electrogenic waste water treatments, to develop desalination systems based on microbial electrogenesis, to build devices to store and use bioelectricity, to design electrogenic biosensors<\/p>\n

\n<\/td>\n<\/tr>\n

P\u00e9rez D\u00edaz, Jos\u00e9 Luis;
\npablo.diaz@uah.es<\/td>\n		Mechanical, electric, and thermal technology for energy applications<\/td>\nApplied multidisciplinary research in mechanical, electric, and thermal technologies integrated in energy systems
\nThe group\u2019s main research lines are as follows:
\n\u2022 Electric grid quality
\n\u2022 Energy conversion or unconventional energy sources
\n\u2022 Energy efficiency.
\n\u2022 Rural electrification with renewable energies.
\n\u2022 Photovoltaic installations connected to the grid.
\n\u2022 High and low temperature solar thermal installations.
\n\u2022 Wind generator maintenance.
\n\u2022 Monitoring and vibration dampening in aerospace structures.<\/p>\n

\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

<\/p>","protected":false},"excerpt":{"rendered":"

URJC EXCELLENCE   Doctorate Supervisor Contact URJC EXCELLENCE RESEARCH GROUPS SCIENTIFIC RESEARCH LINES Marcos Mart\u00ednez, Esperanza; esperanza.marcos@urjc.es Group of Excellence in Service Science, Management and Engineering (GES2ME) Smart Transport. Servitization. Strategic management of knowledge and innovation. Interaction Management. Advertising and media. Fajardo Gonz\u00e1lez, Mariano; mariano.fajardo@urjc.es King Juan Carlos University Chemical Compounds and Nanostructured Materials in […]<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":200,"menu_order":1,"comment_status":"open","ping_status":"closed","template":"","meta":{"footnotes":""},"class_list":["post-202","page","type-page","status-publish","hentry"],"yoast_head":"\nResearch Groups - Proyecto CEI \u201cEnerg\u00eda Inteligente\u201d<\/title>\n<meta name=\"robots\" content=\"index, follow, max-snippet:-1, max-image-preview:large, max-video-preview:-1\" \/>\n<link rel=\"canonical\" href=\"https:\/\/www.campusenergiainteligente.es\/investigacion-y-transferencia\/grupos-de-investigacion\/\" \/>\n<meta property=\"og:locale\" content=\"en_US\" \/>\n<meta property=\"og:type\" content=\"article\" \/>\n<meta property=\"og:title\" content=\"[:es]Grupos de Investigaci\u00f3n[:en]Research Groups[:] - Proyecto CEI \u201cEnerg\u00eda Inteligente\u201d\" \/>\n<meta property=\"og:description\" content=\"URJC EXCELLENCE   Doctorate Supervisor Contact URJC EXCELLENCE RESEARCH GROUPS SCIENTIFIC RESEARCH LINES Marcos Mart\u00ednez, Esperanza; esperanza.marcos@urjc.es Group of Excellence in Service Science, Management and Engineering (GES2ME) Smart Transport. Servitization. Strategic management of knowledge and innovation. Interaction Management. Advertising and media. 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