We present examples of application of the CIMNE model to a number of academic, scientific and industry activities of CIMNE .

We present examples of application of the CIMNE model to a number of academic, scientific and industry activities of CIMNE .

The International Center for Numerical Methods in Engineering (CIMNE) was created in 1987. Its mission is the development and dissemination of original research in the field of numerical methods in engineering (NME), the education of researchers and engineers and the transfer of its research outputs to industry.

The International Center for Numerical Methods in Engineering (CIMNE) was created in 1987. Its mission is the development and dissemination of original research in the field of numerical methods in engineering (NME), the education of researchers and engineers and the transfer of its research outputs to industry.

NME is the discipline that provides the scientific basis for the computer analysis of all engineered systems. Researchers on NME require outstanding skills on mathematical modelling, engineering concepts, numerical algorithms and programming.

NME is the discipline that provides the scientific basis for the computer analysis of all engineered systems. Researchers on NME require outstanding skills on mathematical modelling, engineering concepts, numerical algorithms and programming.

CIMNE is a leader as an international Center of Excellence in the field of NME through five main action vectors:

CIMNE is a leader as an international Center of Excellence in the field of NME through five main action vectors:

Numerical methods for complex coupled problems such as fluid-soil-structure interaction, aero-acoustics, electromagnetics, magneto-hydrodynamics and atmospheric/thermal flows.

Numerical methods for complex coupled problems such as fluid-soil-structure interaction, aero-acoustics, electromagnetics, magneto-hydrodynamics and atmospheric/thermal flows.

Numerical methods for incompressible and compressible flows. Applications to internal and external flows, free-surface flows, multifluids, flow in porous media, aerodynamics and acoustics.

Numerical methods for incompressible and compressible flows. Applications to internal and external flows, free-surface flows, multifluids, flow in porous media, aerodynamics and acoustics.

FEM and particle methods for dry, saturated and partially saturated soils and rocks. Applications to geotechnical engineering: foundations, underground structures, tunnels, dams and slopes.

FEM and particle methods for dry, saturated and partially saturated soils and rocks. Applications to geotechnical engineering: foundations, underground structures, tunnels, dams and slopes.

Mathematical models and algorithms for error estimation, mesh adaption and quality of the numerical solution. Reduced order models for (quasi) real time solution of complex engineering systems.

Mathematical models and algorithms for error estimation, mesh adaption and quality of the numerical solution. Reduced order models for (quasi) real time solution of complex engineering systems.

Methods for multiscale analysis of materials & structures. Applications to the design of new functional materials.

Methods for multiscale analysis of materials & structures. Applications to the design of new functional materials.

FEM and particle-based procedures for linear and nonlinear analysis of solids and structures. Applications to most engineering fields.

FEM and particle-based procedures for linear and nonlinear analysis of solids and structures. Applications to most engineering fields.

Robust optimization procedures for shape and material design and process optimization in civil, mechanical, aerospace and naval engineering.

Robust optimization procedures for shape and material design and process optimization in civil, mechanical, aerospace and naval engineering.

Methods for mesh generation and visualization of huge sets of numerical results in parallel computers using data mining and cloud storage techniques. Integration of decision support systems in engineering.

Methods for mesh generation and visualization of huge sets of numerical results in parallel computers using data mining and cloud storage techniques. Integration of decision support systems in engineering.

ENVIRONMENT. Coordinator: A. Barbat

ENVIRONMENT. Coordinator: A. Barbat

Holistic risk prediction & risk management of constructions and landscape under natural, technological and man-made hazards. Methods for fresh water production. Energy management & reduction for buildings and individual users.

Holistic risk prediction & risk management of constructions and landscape under natural, technological and man-made hazards. Methods for fresh water production. Energy management & reduction for buildings and individual users.

Urban mobility, traffic models, port logistics and maritime transport, transport

Urban mobility, traffic models, port logistics and maritime transport, transport

infrastructure management, resilience of transport networks to hazards.

infrastructure management, resilience of transport networks to hazards.

Researchers at CIMNE carry out their activity within research and technical development (RTD). Groups managed by a Group Leader. The research activities are coordinated by one or more Principal Investigators (PIs). It is common that researchers from different RTD Groups contribute to a same RL.

Researchers at CIMNE carry out their activity within research and technical development (RTD). Groups managed by a Group Leader. The research activities are coordinated by one or more Principal Investigators (PIs). It is common that researchers from different RTD Groups contribute to a same RL.

For a better visibility of the research, RTD Groups are gathered in RTD Areas that target fields such as civil & mechanical engineering, transport, energy & environment and computational and information technologies.

For a better visibility of the research, RTD Groups are gathered in RTD Areas that target fields such as civil & mechanical engineering, transport, energy & environment and computational and information technologies.

The priorities of CIMNE for research excellence target the development of new NM and software codes in order to help engineers to better predict, design and optimize systems affecting our lives, including our environment, our security and safety, and the products we use and export.

The priorities of CIMNE for research excellence target the development of new NM and software codes in order to help engineers to better predict, design and optimize systems affecting our lives, including our environment, our security and safety, and the products we use and export.

More specifically, the research activities in CIMNE are addressed to solving the following challenging practical problems:

More specifically, the research activities in CIMNE are addressed to solving the following challenging practical problems:

The solution of the engineering problems addressed at CIMNE can only be attempted with enough confidence from an interdisciplinary perspective, i.e. accounting for all the complexities and couplings introduced by the different physical fields involved.

The solution of the engineering problems addressed at CIMNE can only be attempted with enough confidence from an interdisciplinary perspective, i.e. accounting for all the complexities and couplings introduced by the different physical fields involved.

Consistently with these broad goals, research progress at CIMNE requires the synergic work of interdisciplinary teams with the necessary critical mass. With the depth of these intellectual developments and their wide range of applications, the numerical methods and codes developed at CIMNE have emerged as powerful tools for solving a wide range of engineering problems and have helped to making of CIMNE a worldwide reference in the computational engineering field.

Consistently with these broad goals, research progress at CIMNE requires the synergic work of interdisciplinary teams with the necessary critical mass. With the depth of these intellectual developments and their wide range of applications, the numerical methods and codes developed at CIMNE have emerged as powerful tools for solving a wide range of engineering problems and have helped to making of CIMNE a worldwide reference in the computational engineering field.

Each node in the tetrahedron is connected to the other three by lines that represent information pipelines (possibly internet). The intensity of the flow along the lines that interconnect two nodes would vary depending on the requirements for solving the problem.

Each node in the tetrahedron is connected to the other three by lines that represent information pipelines (possibly internet). The intensity of the flow along the lines that interconnect two nodes would vary depending on the requirements for solving the problem.

Research at CIMNE has lead to a number of software codes and integrated systems that are useful for solving specific problems in a wide range of engineering áreas. Annex 3 lists the main software codes and other products developed at CIMNE.

Research at CIMNE has lead to a number of software codes and integrated systems that are useful for solving specific problems in a wide range of engineering áreas. Annex 3 lists the main software codes and other products developed at CIMNE.

CIMNE researchers publish in the best journals listed in the prestigious Journal Citation Reports (JCR) in the fields of civil and structural engineering, geotechnical engineering, engineering geology, computational mechanics and computational mathematics, among others.

CIMNE researchers publish in the best journals listed in the prestigious Journal Citation Reports (JCR) in the fields of civil and structural engineering, geotechnical engineering, engineering geology, computational mechanics and computational mathematics, among others.

CIMNE scientists are chief editors or associated editors of 6 international JCR journals and members of the editorial board of 15 JCR journals.

CIMNE scientists are chief editors or associated editors of 6 international JCR journals and members of the editorial board of 15 JCR journals.

CIMNE publishes two journals listed in the JCR.

CIMNE publishes two journals listed in the JCR.

- ARCHIVES OF COMPUTATIONAL METHODS IN ENGINEERING, a quarterly journal edited by M. Kleiber (Polish Academy of Sciences) and E. Oñate (CIMNE). ACME has been published by CIMNE since 1994 and by Springer since 2007. Impact Factor (2016): IF= 5.061, 5-Year IF: 5.710. ACME is nowadays the leading journal in the NME field. It is ranked 1 of 101 in category “Mathematics, Interdisciplinary Applications”, 2 of 85 in category “Engineering Multidisciplinary”, and 5 of 104 in category “Computer Science, Interdisciplinary Applications” (Source: JCR)

- ARCHIVES OF COMPUTATIONAL METHODS IN ENGINEERING, a quarterly journal edited by M. Kleiber (Polish Academy of Sciences) and E. Oñate (CIMNE). ACME has been published by CIMNE since 1994 and by Springer since 2007. Impact Factor (2016): IF= 5.061, 5-Year IF: 5.710. ACME is nowadays the leading journal in the NME field. It is ranked 1 of 101 in category “Mathematics, Interdisciplinary Applications”, 2 of 85 in category “Engineering Multidisciplinary”, and 5 of 104 in category “Computer Science, Interdisciplinary Applications” (Source: JCR)

SCIPEDIA fosters the publication and dissemination of documents in Open Access format under the Creative Commons BY-NC-SA license. Scipedia creates and manages journals and collections of publications of individuals and groups (eg. a single author, a group of academics, a university department or a research center, etc).

SCIPEDIA fosters the publication and dissemination of documents in Open Access format under the Creative Commons BY-NC-SA license. Scipedia creates and manages journals and collections of publications of individuals and groups (eg. a single author, a group of academics, a university department or a research center, etc).

CIMNE scientists have supervised a total of 160 PhDs and some 720 MSc students.

CIMNE scientists have supervised a total of 160 PhDs and some 720 MSc students.

- A. Gens (Université de Grenoble - Joseph Fourier, FRANCE),

- A. Gens (Université de Grenoble - Joseph Fourier, FRANCE),

- A. Barbat (Technical University "Gh. Asachi" of Iasi, ROMANIA; Technical University of Cluj-Napoca, ROMANIA).

- A. Barbat (Technical University "Gh. Asachi" of Iasi, ROMANIA; Technical University of Cluj-Napoca, ROMANIA).

In 2005 CIMNE started its international expansion and since then has created CIMNE Latin-America (Non-profit Foundation in Santa Fe, Argentina) and CIMNE USA (Non-profit Corporation in Washington DC, USA).

In 2005 CIMNE started its international expansion and since then has created CIMNE Latin-America (Non-profit Foundation in Santa Fe, Argentina) and CIMNE USA (Non-profit Corporation in Washington DC, USA).

CIMNE has close links with several prestigeous universities and RTD organizations worldwide (see Annex 4).

CIMNE has close links with several prestigeous universities and RTD organizations worldwide (see Annex 4).

CIMNE is the permanent Secretariat of the following scientific organizations:

CIMNE is the permanent Secretariat of the following scientific organizations:

The CIMNE conferences are excellent occasions for disseminating CIMNE research outputs, as well as for acquiring new knowledge and for creating opportunities for participating in new RTD projects and networking with international researchers and industry.

The CIMNE conferences are excellent occasions for disseminating CIMNE research outputs, as well as for acquiring new knowledge and for creating opportunities for participating in new RTD projects and networking with international researchers and industry.

We following table summarises the 52 international scientific conferences organized by CIMNE in the period 2012-2016, showing the place/region where the event was held:

We following table summarises the 52 international scientific conferences organized by CIMNE in the period 2012-2016, showing the place/region where the event was held:

We list below a selection of the 52 international scientific conferences organized by CIMNE in 2012-2016. The participation of relevant CIMNE researchers as co-chairs of the conferences is highlighted.

We list below a selection of the 52 international scientific conferences organized by CIMNE in 2012-2016. The participation of relevant CIMNE researchers as co-chairs of the conferences is highlighted.

In recent years, CIMNE has put effort in the dissemination ot its different activities via social networks to reach a broader audience.

In recent years, CIMNE has put effort in the dissemination ot its different activities via social networks to reach a broader audience.

CIMNE has implemented an (almost) self-sustainable financial model with limited annual public funding from the Government. This has been possible by its active policy for obtaining income from RTD projects funded by public and private international and national organizations and industry, revenues from the CIMNE spin-off companies and an efficient management structure.

CIMNE has implemented an (almost) self-sustainable financial model with limited annual public funding from the Government. This has been possible by its active policy for obtaining income from RTD projects funded by public and private international and national organizations and industry, revenues from the CIMNE spin-off companies and an efficient management structure.

Figures 4 and 5 below show the evolution of CIMNE income and the percentage of public funding received since 1987. Note that CIMNE has received just some 5% average annual public funding in the period 1987-2017.

Figures 4 and 5 below show the evolution of CIMNE income and the percentage of public funding received since 1987. Note that CIMNE has received just some 5% average annual public funding in the period 1987-2017.

Figure 6 show the source of CIMNE income in the period 2010-2016. Income originates from contracts with industry, European and international RTD competitive RTD projects, National competitive RTD projetcs, conferencves and courses, grant from the Catalonian Govermment (Generalitat de Catalunya), financial revenues and others (sells of CIMNE companies, technology licenses, etc).

Figure 6 show the source of CIMNE income in the period 2010-2016. Income originates from contracts with industry, European and international RTD competitive RTD projects, National competitive RTD projetcs, conferencves and courses, grant from the Catalonian Govermment (Generalitat de Catalunya), financial revenues and others (sells of CIMNE companies, technology licenses, etc).

When people talks about research, development and technology transfer to society (RTD in short) and commercial industrial activities, it is quite usual to mix up objectives, resources and responsibilities. There is a growing opinion, spread by some public administrators and the media, that research groups at universities and RTD centers must be "profitable". In few words, many persons would wish that research is funded with competitive funds or even loans (either public or private) and that the outcomes of the research get fast into the market, so that the profits from marketing products will allow research groups to be financially self-sustaining.

When people talks about research, development and technology transfer to society (RTD in short) and commercial industrial activities, it is quite usual to mix up objectives, resources and responsibilities. There is a growing opinion, spread by some public administrators and the media, that research groups at universities and RTD centers must be "profitable". In few words, many persons would wish that research is funded with competitive funds or even loans (either public or private) and that the outcomes of the research get fast into the market, so that the profits from marketing products will allow research groups to be financially self-sustaining.

It is also usually argued that companies should increase their research activity and invest more resources in finding new discoveries. The humoristic limit of this situation is pretending that companies will produce Nobel laureates and that a research group would be among the 10 first positions in the ranking of economic organizations in a country. Certainly, both these situations are not impossible, although they are highly improbable. The opposite case is, unfortunately, more frequent, i.e. that researchers compelled by their needs to guarantee the financial survival of their groups, abandon or considerably reduce their fundamental research activities, and that companies, confusing what is a Technical Department with an Innovation Department, consider themselves self-sufficient in terms of their capacity for innovating and underestimate or ignore the contact with the RTD world in research centers and universities.

It is also usually argued that companies should increase their research activity and invest more resources in finding new discoveries. The humoristic limit of this situation is pretending that companies will produce Nobel laureates and that a research group would be among the 10 first positions in the ranking of economic organizations in a country. Certainly, both these situations are not impossible, although they are highly improbable. The opposite case is, unfortunately, more frequent, i.e. that researchers compelled by their needs to guarantee the financial survival of their groups, abandon or considerably reduce their fundamental research activities, and that companies, confusing what is a Technical Department with an Innovation Department, consider themselves self-sufficient in terms of their capacity for innovating and underestimate or ignore the contact with the RTD world in research centers and universities.

Ideas (and I basically refer here to scientific advances) usually originate in university environments, where many professionals have the mission of thinking, studying, investigating and eventually discovering new areas of knowledge. The idea (the new discovery) would be equivalent to a seed, in the sense that even being very important (essential) it is far from becoming a fruit.

Ideas (and I basically refer here to scientific advances) usually originate in university environments, where many professionals have the mission of thinking, studying, investigating and eventually discovering new areas of knowledge. The idea (the new discovery) would be equivalent to a seed, in the sense that even being very important (essential) it is far from becoming a fruit.

Once a product has reached the market, it would enter into the fourth quadrant of the Cycle of Ideas (Figure 7). There the objective is commercial success. In order to reach that, the company should establish the necessary alliances around the world. The Cycle finalizes with the return of a part of the profits from marketing the product to the place from where the idea originated (the University).

Once a product has reached the market, it would enter into the fourth quadrant of the Cycle of Ideas (Figure 7). There the objective is commercial success. In order to reach that, the company should establish the necessary alliances around the world. The Cycle finalizes with the return of a part of the profits from marketing the product to the place from where the idea originated (the University).

These concepts are in fact very simple. However, it is typically very difficult to put them into practice. What are the difficulties?

These concepts are in fact very simple. However, it is typically very difficult to put them into practice. What are the difficulties?

If the above concepts are accepted, then we can guess better the difficulty and/or convenience of implementing one or other policy for stimulating RTD work at universities, research centers and companies. It is non credible that a university or a research center can profit from the exploitation of the outcomes of an idea in the short/mid term. Consequently, the policy of some Government agencies of providing reimbursable loans instead of grants for funding research in universities and research centers, has a high probability of failure, in the sense that they will not be able to return the loans on time. A more interesting (and feasible) approach will be that parts of the grants are linked to the success in the research, validated in the form of contrastable results. On the other hand, the policy for funding innovation work in companies should include the modality of non-returnable loans for happy-ending histories in the achievement of an innovative product.

If the above concepts are accepted, then we can guess better the difficulty and/or convenience of implementing one or other policy for stimulating RTD work at universities, research centers and companies. It is non credible that a university or a research center can profit from the exploitation of the outcomes of an idea in the short/mid term. Consequently, the policy of some Government agencies of providing reimbursable loans instead of grants for funding research in universities and research centers, has a high probability of failure, in the sense that they will not be able to return the loans on time. A more interesting (and feasible) approach will be that parts of the grants are linked to the success in the research, validated in the form of contrastable results. On the other hand, the policy for funding innovation work in companies should include the modality of non-returnable loans for happy-ending histories in the achievement of an innovative product.

The right policy should put the emphasis in successful ending of the RTD activity, and not in the RTD work in itself, as it is the usual case. The target will be always the same, helping that an idea becomes something useful for society and profitable.

The right policy should put the emphasis in successful ending of the RTD activity, and not in the RTD work in itself, as it is the usual case. The target will be always the same, helping that an idea becomes something useful for society and profitable.

CIMNE has actively promoted the creation of spin-off companies, some of them totally or partially owned by CIMNE. These companies play an important role in the industrialization and exploitation of CIMNE technology.

CIMNE has actively promoted the creation of spin-off companies, some of them totally or partially owned by CIMNE. These companies play an important role in the industrialization and exploitation of CIMNE technology.

We list below the lsit of CIMNE spin-off companies.

We list below the lsit of CIMNE spin-off companies.

Most of these companies listed below were created by initiative of CIMNE or CIMNE Tecnologia SA. In some particular cases (Compass, Quantech and BuildAir) the company existed prior to 2011 and the participation of CIMNE as a shareholder took place after 2012.

Most of these companies listed below were created by initiative of CIMNE or CIMNE Tecnologia SA. In some particular cases (Compass, Quantech and BuildAir) the company existed prior to 2011 and the participation of CIMNE as a shareholder took place after 2012.

CIMNE and the Technical University of Catalonia (UPC) offer students of all nationalities the opportunity to accessing high education courses and degrees at Bachelor, MSc and PhD levels in most areas of computational engineering and applied sciences. Bachelor and MSc courses are taught mainly at UPC or in partner universities of the Catalonian university network for specialities not covered by UPC. MSc and PhD students are supervised by CIMNE and UPC academic experts in the different fields.

CIMNE and the Technical University of Catalonia (UPC) offer students of all nationalities the opportunity to accessing high education courses and degrees at Bachelor, MSc and PhD levels in most areas of computational engineering and applied sciences. Bachelor and MSc courses are taught mainly at UPC or in partner universities of the Catalonian university network for specialities not covered by UPC. MSc and PhD students are supervised by CIMNE and UPC academic experts in the different fields.

CIMNE and UPC offer graduate students of all nationalities the opportunity to perform doctorate studies and research work aiming to obtaining a Ph.D. degree at UPC in a wide range of topics in engineering and applied sciences. Doctorate students are supervised by CIMNE and UPC specialists in the different fields. Opportunity exists for “sandwich” type of doctorate degrees allowing students to develop part of their doctorate at UPC and CIMNE premises and the other part at their home university under the joint supervision of academic staff from UPC/CIMNE and the home university from where the student originates.

CIMNE and UPC offer graduate students of all nationalities the opportunity to perform doctorate studies and research work aiming to obtaining a Ph.D. degree at UPC in a wide range of topics in engineering and applied sciences. Doctorate students are supervised by CIMNE and UPC specialists in the different fields. Opportunity exists for “sandwich” type of doctorate degrees allowing students to develop part of their doctorate at UPC and CIMNE premises and the other part at their home university under the joint supervision of academic staff from UPC/CIMNE and the home university from where the student originates.

CIMNE offers a partnership to companies and organizations worldwide for joint exploitation of products and services on computational engineering, in the broad sense.

CIMNE offers a partnership to companies and organizations worldwide for joint exploitation of products and services on computational engineering, in the broad sense.

The network of CIMNE Joint Labs incorporates 30 members in universities of Spain and 9 Latin-American countries. This network is the best gateway for launching new RTD projects, education activities and technology transfer initiatives in cooperation with a team of experts on computational engineering and related fields.

The network of CIMNE Joint Labs incorporates 30 members in universities of Spain and 9 Latin-American countries. This network is the best gateway for launching new RTD projects, education activities and technology transfer initiatives in cooperation with a team of experts on computational engineering and related fields.

CIMNE offers computational services in many areas of engineering and applied sciences to companies and organizations in cooperation and partnership with the members of the CIMNE academic and industrial network.

CIMNE offers computational services in many areas of engineering and applied sciences to companies and organizations in cooperation and partnership with the members of the CIMNE academic and industrial network.

The figure below lists the RTD Areas and RTD Groups at CIMNE.

The figure below lists the RTD Areas and RTD Groups at CIMNE.

RTD activity: Development of numerical methods (NM) for solving incompressible and compressible flow problems, thermal and reactive flows, free surface flows and fluid-structure interaction problems. Applications in civil, mechanical, aerospace, naval and bio-medical engineering.

RTD activity: Development of numerical methods (NM) for solving incompressible and compressible flow problems, thermal and reactive flows, free surface flows and fluid-structure interaction problems. Applications in civil, mechanical, aerospace, naval and bio-medical engineering.

RTD activity: Development of NM for geotechnical and geological problems. Applications in civil, mining, geomechanics and environmental engineering.

RTD activity: Development of NM for geotechnical and geological problems. Applications in civil, mining, geomechanics and environmental engineering.

RTD activity: Development of NM for analysis and optimal design of industrial metal forming processes. Applications to sheet stamping, welding, casting, forging, rolling, machining, blanking and additive manufacturing (3D printing) processes.

RTD activity: Development of NM for analysis and optimal design of industrial metal forming processes. Applications to sheet stamping, welding, casting, forging, rolling, machining, blanking and additive manufacturing (3D printing) processes.

RTD activity: Development of NM for analysis and design of structures. Computational material design. Applications in civil, mechanical, aerospace, naval and bio-medical engineering.

RTD activity: Development of NM for analysis and design of structures. Computational material design. Applications in civil, mechanical, aerospace, naval and bio-medical engineering.

RTD activity: Development of NM, data mining procedures, empowering techniques and integrated systems for improving the energy efficiency in buildings and communities. Applications to the optimal design and operation of energy consumption of buildings and individual users.

RTD activity: Development of NM, data mining procedures, empowering techniques and integrated systems for improving the energy efficiency in buildings and communities. Applications to the optimal design and operation of energy consumption of buildings and individual users.

RTD activity: New NM for holistic risk assessment of constructions and infrastructure to natural, technological and man-made hazards. Applications to evaluation of risk and resilience of constructions under earthquakes, floods, tsunamis, fires. air pollution and explosions.

RTD activity: New NM for holistic risk assessment of constructions and infrastructure to natural, technological and man-made hazards. Applications to evaluation of risk and resilience of constructions under earthquakes, floods, tsunamis, fires. air pollution and explosions.

RTD activity: Development of NM, Big Data, IoT and ICT procedures and tools for solving relevant problems in engineering, Applications to the development of integrated decision support systems in civil, mechanical, aerospace, marine and food engineering.

RTD activity: Development of NM, Big Data, IoT and ICT procedures and tools for solving relevant problems in engineering, Applications to the development of integrated decision support systems in civil, mechanical, aerospace, marine and food engineering.

RTD activity: Development of NM for solving large scale engineering in applied sciences and engineering using high performance computing technologies. Applications in civil, mechanical, aerospace, marine, industrial forming processes and bio-medical engineering.

RTD activity: Development of NM for solving large scale engineering in applied sciences and engineering using high performance computing technologies. Applications in civil, mechanical, aerospace, marine, industrial forming processes and bio-medical engineering.

RTD activity: Development and integration of mesh generation and graphic visualization procedures and tools for supporting the computational solution of problems in engineering and applied sciences. Applications in civil, mechanical, aerospace, marine and bio-medical engineering.

RTD activity: Development and integration of mesh generation and graphic visualization procedures and tools for supporting the computational solution of problems in engineering and applied sciences. Applications in civil, mechanical, aerospace, marine and bio-medical engineering.

RTD activity: Development of NM for solving incompressible and compressible flow problems, fluid-structure interaction and optimization problems. Applications to the analysis and optimal design of aircrafts. Analysis and design of inflatable hangars for maintenance of airplanes. Optimal design of ground operations and logistics in aeronautics.

RTD activity: Development of NM for solving incompressible and compressible flow problems, fluid-structure interaction and optimization problems. Applications to the analysis and optimal design of aircrafts. Analysis and design of inflatable hangars for maintenance of airplanes. Optimal design of ground operations and logistics in aeronautics.

RTD activity: Development of NM for modelling and analysis of the mobility of traffic and goods in urban areas and highways. Applications to the analysis and optimal design of land and maritime transport networks, port logistics, transport infrastructure management and study of resilience of transport networks to hazards.

RTD activity: Development of NM for modelling and analysis of the mobility of traffic and goods in urban areas and highways. Applications to the analysis and optimal design of land and maritime transport networks, port logistics, transport infrastructure management and study of resilience of transport networks to hazards.

RTD activity: Development of NM for incompressible flows, fluid-structure interaction and optimization problems. Applications to analysis and optimal design of ships and marine structures (including energy generation structures) with standard and new materials.

RTD activity: Development of NM for incompressible flows, fluid-structure interaction and optimization problems. Applications to analysis and optimal design of ships and marine structures (including energy generation structures) with standard and new materials.

Five CIMNE scientists have been awarded 10 ERC projects (amounting some 12.2 M€ funding): 3 Advanced Grants, 2 Starting Grants, and 5 Proof of Concept (PoC) grants. Two of the PoCs were awarded at the end of July 2016.

Five CIMNE scientists have been awarded 10 ERC projects (amounting some 12.2 M€ funding): 3 Advanced Grants, 2 Starting Grants, and 5 Proof of Concept (PoC) grants. Two of the PoCs were awarded at the end of July 2016.

We give below details of the 10 ERC projects above mentioned.

We give below details of the 10 ERC projects above mentioned.

In SAFECON we developed new particle-based methods and the finite element method for estimating the dynamics of free surface multiscale heterogeneous flows and their interaction with constructions.

In SAFECON we developed new particle-based methods and the finite element method for estimating the dynamics of free surface multiscale heterogeneous flows and their interaction with constructions.

In REALTIME we developed new particle methods, time integration schemes allowing large time steps, reduction methods, GPUs and parallel processing techniques for the quasi-real time analysis of multi-fluid engineering problems.

In REALTIME we developed new particle methods, time integration schemes allowing large time steps, reduction methods, GPUs and parallel processing techniques for the quasi-real time analysis of multi-fluid engineering problems.

The project aims to developing new Computational Materials Design techniques integrating: 1) computational multiscale material modeling, 2) new high performance reduced-order-modeling techniques, and 3) new computational strategies for optimal design of the meso/micro structure and topology of engineering materials.

The project aims to developing new Computational Materials Design techniques integrating: 1) computational multiscale material modeling, 2) new high performance reduced-order-modeling techniques, and 3) new computational strategies for optimal design of the meso/micro structure and topology of engineering materials.

The project developed stabilized finite element methods and multi-scale decompositions for solving the physical processes in nuclear fusion technology. This requires new NM for fluid mechanics, electromagnetics, thermal radiation and neutronics and efficient coupling techniques for solving this complex multiphysics problem.

The project developed stabilized finite element methods and multi-scale decompositions for solving the physical processes in nuclear fusion technology. This requires new NM for fluid mechanics, electromagnetics, thermal radiation and neutronics and efficient coupling techniques for solving this complex multiphysics problem.

The project developed new NM for advancing in three topics in nano- and biomolecular mechanics: (1) Mechanics of carbon nanotubes at engineering scales, (2) Mechanics of fluid membranes in eukaryotic cells and bio-inspired technologies and (3) Local-to-global conformational space exploration and free energy calculations for biomolecules.

The project developed new NM for advancing in three topics in nano- and biomolecular mechanics: (1) Mechanics of carbon nanotubes at engineering scales, (2) Mechanics of fluid membranes in eukaryotic cells and bio-inspired technologies and (3) Local-to-global conformational space exploration and free energy calculations for biomolecules.

FLOODSAFE has moved the SAFECON Adv. Grant technology towards the initial steps of an innovation process leading to a new software for study of particulate mudflows and their interaction with constructions and landscape with the aim of ensuring the safety of civil infrastructures and the environment during floods.

FLOODSAFE has moved the SAFECON Adv. Grant technology towards the initial steps of an innovation process leading to a new software for study of particulate mudflows and their interaction with constructions and landscape with the aim of ensuring the safety of civil infrastructures and the environment during floods.

The objective of FEXFEM (from the COMFUS Adv. Grant) is to develop a Scientific Computing Library for Frontier Simulations at Extreme Scales. The goal is to provide high-quality open source software combining discretization and numerical linear algebra for extreme scale solvers with reduced synchronization and inter-processor communications.

The objective of FEXFEM (from the COMFUS Adv. Grant) is to develop a Scientific Computing Library for Frontier Simulations at Extreme Scales. The goal is to provide high-quality open source software combining discretization and numerical linear algebra for extreme scale solvers with reduced synchronization and inter-processor communications.

The PoC will explore the industrial applicability and potential commercialization of the codes developed in the SAFECON Adv Grant project for the study of the navigation of a ship in an iced-sea and the determination of the ice drag of the vessel and the ice-induced resistance on the vessel hull.

The PoC will explore the industrial applicability and potential commercialization of the codes developed in the SAFECON Adv Grant project for the study of the navigation of a ship in an iced-sea and the determination of the ice drag of the vessel and the ice-induced resistance on the vessel hull.

Since 1987 CIMNE has ben awarded 255 projects funded by the European Commission (EC). Out of these 24 are FP7 projects, 14 are H2020 projects and 13 belong to other EC project categories. CIMNE has received funding from the EC that amounts to some 50 M€. CIMNE has been the coordinator of 44 EC projects.

Since 1987 CIMNE has ben awarded 255 projects funded by the European Commission (EC). Out of these 24 are FP7 projects, 14 are H2020 projects and 13 belong to other EC project categories. CIMNE has received funding from the EC that amounts to some 50 M€. CIMNE has been the coordinator of 44 EC projects.

We list below some of the main CIMNE projects funded by the EC in the last five years in terms of both scientific and economical relevance:

We list below some of the main CIMNE projects funded by the EC in the last five years in terms of both scientific and economical relevance:

This is a selection of the 14 H2020 projects awarded to CIMNE in the period:

This is a selection of the 14 H2020 projects awarded to CIMNE in the period:

CIMNE was awarded 13 projects funded by other EC programmes in the period including CIP, TEN-T, MED, ERASMUS and RFCS programmes. The most relevant ones are:

CIMNE was awarded 13 projects funded by other EC programmes in the period including CIP, TEN-T, MED, ERASMUS and RFCS programmes. The most relevant ones are:

CIMNE has been awarded several grants for RTD projects by international organizations such as the Office of Naval Research (ONR, US), the Naval Research Laboratory (NRL, US), Weatherford Inc. (US), Altair Inc. (US), the World Bank (WB) and the Inter-American Dev. Bank (BID), among others.

CIMNE has been awarded several grants for RTD projects by international organizations such as the Office of Naval Research (ONR, US), the Naval Research Laboratory (NRL, US), Weatherford Inc. (US), Altair Inc. (US), the World Bank (WB) and the Inter-American Dev. Bank (BID), among others.

These are the most relevant grants awarded to CIMNE in the last five years:

These are the most relevant grants awarded to CIMNE in the last five years:

In the last 30 years CIMNE has established a solid network of international scientific partners worldwide. We describe below the key international research partners of CIMNE.

In the last 30 years CIMNE has established a solid network of international scientific partners worldwide. We describe below the key international research partners of CIMNE.

PIs: Profs. Roger Owen and George Peric

PIs: Profs. Roger Owen and George Peric

PI: Prof. R. Jardine

PI: Prof. R. Jardine

PI: Prof. Mike Bradley

PI: Prof. Mike Bradley

PI: Prof. Peter Wriggers

PI: Prof. Peter Wriggers

PI: Prof. Kai-Uwe Bletzinger

PI: Prof. Kai-Uwe Bletzinger

PI: Prof. Dr. André Stork

PI: Prof. Dr. André Stork

PI: Prof. Manolis Papadrakakis

PI: Prof. Manolis Papadrakakis

PI: Profs Carmelo Majorana and Roberto Scotta

PI: Profs Carmelo Majorana and Roberto Scotta

PI: Prof Bernardo Schrefler

PI: Prof Bernardo Schrefler

PIs: Profs Pierre Ladeveze and Olivier Allix

PIs: Profs Pierre Ladeveze and Olivier Allix