Les Technologies de l information et de la communication

Les Technologies de l’information

et de la communication

La thématique ICT du 7

ème

PCRDT

Claire FERTE PCN ICT

UBIFRANCE Juin 2010

Particularités de la thématique



Une seule DG, la DG INFSO (Commissaire: Mme Neelie Kroes)



Un programme de travail disponible sur 2 ans



3 appels prévus sur 2 ans et 1 appel ouvert toute l’année



Procédure en une étape et en 2 étapes (FET Open + Appel PME)

Ou en sommes nous?



DERRIERE NOUS

 7 Appels ICT depuis 2007 ( complétés par les FET Open + Appels conjoints Sécurité et Energie + Appels coordonnés Brésil Russie + PPP).

 représentant 5.2 milliards € de financement;

 environ 1165 projets lancés ou en cours de lancement (sur ~ 6300 propositions reçues);

 + 4 appels des entreprises communes ARTEMIS(25) & ENIAC(7+11+10) et 4 appels du Programme Assistance à l’autonomie à domicile(23+30).



EN COURS

 FET Open, les 2ème _{phases des appels ARTEMIS et ENIAC, 2}ème

phase appel Initiative PME contenu numériques et langues

Structure du Programme de travail



Une structure composée d’u

n nombre limité de

défis

qui :

 Répondent aux besoins bien identifiés par l’industrie

 et/ou

 Ciblent des objectifs socio-économiques spécifiques



Un

défi

est défini à travers un nombre limité

d’objectifs

qui

forment la base des appels à propositions.



Un objectif

est défini en termes de :

 Résultats ciblés -en termes de caractéristiques

 Impacts attendus -en termes de compétitivité industrielle, objectifs sociétaux, progrès technologique.

 Indications: budget; régimes de financement; numéro de l’appel

4.Contenu numérique, et langage

Programme de travail 2011-12

Besoin s ind ust riels 2.Systèmes cognitifs, et robotique 1.Infrastructures de réseaux et de services (PPP) 3.Voies alternatives aux composants et systèmes TIC pour une économie faible en émission de carbone TIC pour la santé Bien Vieillir l’inclusion TIC pour l’entreprise et la fabrication Besoins socio-économiques TIC pour l’ apprentissage et l’accès aux Ressources culturelles T echn olo gies fu tu res et émergent es

Actions horizontales de soutien

Les appels à venir

Appels Publication Date limite Budget Instruments

FP7-ICT-2011-8 20/07/11 17/01/12 785.5 CP, NoE, CSA, _ERA-NET+

FP7-2012-NMP-ICT-FoF 20/07/11 01/12/11 60 CP

FP7-2012-NMP-ENV-ENERGY-ICT-EeB 20/07/11 01/12/11 30 STREP

FP7-2012-ICT-GC 20/07/11 01/12/11 30 STREP, CSA

FP7-ICT-2011-9 18/01/12 17/04/12 291 CP, NoE, CSA, _ERA-NET+

FP7-ICT-2011-C FET

Appels à venir



APPEL 8: 12 objectifs appelés sur 5 défis

1.1 Future networks

1.2 Cloud computing; advanced software engineering

1.4 Trustworthy ICT

1.6 Future Internet research and experimentation

3.1 Nanoelectronic components

3.2 Smart components and smart systems integration

3.5 Photonics technologies

4.4 Intelligent information management

6.1 Smart energy grids

6.3 Efficient water resources management

6.7 Cooperative systems for energy efficiency and mobility

8.1 Technology-enhanced learning

Appels à venir



APPEL 8: 4 objectifs des FET PROACTIVE

9.6 Unconventional computation

9.7 Dynamics of multi-level complex systems

9.8 Minimising energy consumption of computing to the limit

9.12 Coordinating communities, identifying new research topics,

fostering networking of national and regional programmes



APPEL 8: 2 actions ciblées

9.14 Science of global systems

11.1 Pre-commercial procurement actions

Appels à venir



APPEL 8: les partenariats publics privés

Factories of the Future 2012

7.1 Smart factories; energy-aware, agile manufacturing and

customisation

7.2 Manufacturing solutions for new ICT products

Energy-efficient Buildings

6.5 ICT for energy-positive neighbourhoods

Green Cars

6-8 ICT for fully electric vehicles

Les Technologies de l’Information et

de la Communication

Le programme de travail 2011-2012

8

ème

Appel

ftp://ftp.cordis.europa.eu/pub/fp7/ict/docs/ict-wp-2011-12_en.pdf

Appel 8



Défi 1: mise en réseau, média et infrastructures de

service



Ce défi couvre les outils et les plates-formes pour le

développement et le déploiement

d’applications pour le nouvel

Internet à travers le lancement d'un

partenariat public-privé

sur

l’Internet du Futur

. Il aborde dans le même temps, les

futurs développements technologiques clés pour la mise en

réseau, les médias numériques et les infrastructures de

services

.

 1.1 Future Networks - Réseaux du futur

 1.2 Cloud Computing, Internet of Services and Advanced Software Engineering - Cloud computing, Internet des services et ingénierie de logiciels avancés

 1.4 Trustworthy ICT - les TIC digne de confiance

 1.6 Future Internet Research and Experimentation (FIRE)

Appel 8

•

Objectif 1 : Future networks

a) Wireless and mobile broadband systems

b) High capacity end-to-end infrastructure technologies (new actors are expected)

c) Novel Internet architectures, management and operation frameworks

d) Flexible, resilient, broadband and integrated satellite communication (not covered by the previous call)

e) Coordination and Support Actions and Networks of Excellence

•

Instruments

: a), b), c), d) : PI, STREP ; e) : REX, CSA

•

Budget

: 160 M€

IP-STREP : 152 M€ (avec un minimum de 50 % PI et 30 % STREP) REX : 6 M€

Goal: Internet architecture designed for

future broadband fixed and mobile access

Replace old Internet protocols New technologies are expected Communication machine to machine

 Cellular and beyond Ad-Hoc Mesh Relay Application Server Operator A Gateway Operator B Public Internet Cooperating Objects/ Sensor Networks Optical Switching Optical Transmission Personal Space Application Server High Speed Broadband Access 

Future networks projects portfolio Call 1 & 5

EX-FI FISI ceFIMS SESERV SPARC REWIND EU-MESH ALPHA EURO-NF NEWCOM++ OMEGA E3 4WARD TRILOGY SENSEI BONE WALTER UCELLS EPIFSANS SMOOTH-IT MOMENT AUTOI CODIV MIMAX MULTI-BASE SENDORA SOCRATES sISI MOBILEWEB2.0 ROCKET DAVINCI PSIRP N-CRAVE SARDANA CHIANTI SFERA EIFFEL ETNA DICONET PHYDAS WHERE WIMAGIC REDESIGN HURRICANE ARAGORN CARMEN FUTON eMobility Networld EUWB C-CAST MOBITHIN

Future Internet Technologies

Radio Access and Spectrum Use Converged and Optical Networks EARTH QoSMOS BeFEMTO ARTIST4G ETICS STRONGEST OASE GEYSERS SAPHYRE COGEU QUASAR FARAMIR SAMURAI C2POWER FREEDOM SACRA LOLA BUNGEE MAINS FIVER ACCORDANCE MONET SAIL UNIVERSELF EXALTED FIGARO ECONET ONE PURSUIT FLAVIA CHANGE ULOOP ONEFIT CHRON MEDIEVAL TREND ACROPOLIS CARE 90 projets

Objective 1.1. Future Networks



The target is the development of Future network infrastructures

that

support

the

convergence

and

interoperability

of

heterogeneous

mobile, wired and wireless broadband network

technologies as enablers of the future Internet.



This includes ubiquitous fast broadband access and ultra high

speed

end-to-end

connectivity,

with

optimised

protocols,

addressing and routing capabilities supporting multiple operation

schemes and provision of open generic services and applications.



Target outcome: Development of

energy-efficient

future network

infrastructures that support the convergence and interoperability of

heterogeneous

mobile, wired and wireless

broadband network

technologies

Network and service infrastructures

 1.1: Future Networks supporting the convergence and interoperability of heterogeneous mobile, wired and wireless broadband network technologies

 novel Internet architectures; network management and operation frameworks, wireless and mobile broadband systems and ultra-high capacity all-optical networks, satcoms

 1.2: Cloud computing, Internet of Services & advanced software engineering

 technologies specific to the networked, distributed dimension of software and the access to services and data

 1.4: Trustworthy ICT

 security in networked service and computing environments; trust, privacy and claims management infrastructures; data policy, governance and socio-economic aspects of trustworthy ICT

 1.6: Future Internet Research and Experimentation (FIRE)

 FIRE Federation

 FIRE Experimentation

Appel 8

•

Objectif 2 : Cloud Computing (

nouveauté

), Internet of

Services and advanced Software Engeneering (

core activity

of the unit

)

a) Cloud Computing b) Internet of Services

c) Advanced software engineering d) Coordination and support actions

•

Instruments

: a), b), c) : PI, STREP ; d) : CSA

•

Budget

: 70 M€

PI- STREP : 68,5 M€ (avec un minimum de 30 % PI et 50 % STREP) CSA : 1,5 M€

What are we looking for?

 Bold, visionary projects

 New research directions

 No repetition of existing projects  Considering controversial aspects

 Taking into account key European values

 Data protection, energy efficiency, …

 Expected industrial impact

 New offerings, new jobs, increased competitiveness  Me too or something different?

 Based on widely-shared research agendas

 Creating consensus where applicable  User involvement

Objective 1.2

contribute to

Cloud computing

Internet of

services

Advanced

software

engineering

Target outcomes Emergence of European interoperable clouds

Platforms for development and deployment of services

Lower barriers to develop and use services through advances in technology and

standardized interfaces

Efficient software applications on parallel architectures

Easier evolution of legacy software

Fast innovation cycles in service industry A strengthened industry in Europe

for software-based services achieve

Expected impact A proposal

Objective 1.2

Support actions

Cloud computing

Management of cloud resources Infrastructure virtualisation Cloud Interoperability Open source implementation

of a software stack for clouds

Internet of

services

Service engineering Integration of real and virtual worlds Scalability, self-management, fault localisation, …

Advanced

software

engineering

Advanced engineering for software

Quality measure and assurance

Tools and methods for community-based and open source software development

Target outcomes

Standardization and collaboration Open source development model

International cooperation on cloud computing

Objective 1.2

Cloud computing

Intelligent and autonomic management of cloud resources, ensuring agile elastic scalability. Scalable data management strategies, addressing the issues of heterogeneity, consistency, availability, privacy and supporting security.

Technologies for infrastructure virtualisation, cross platforms execution as needed for service composition across multiple, heterogeneous environments, autonomous management of hardware and software resources.

Interoperability amongst different clouds, portability, protection of data in cloud environments, control of data distribution and latency.

Seamless support of mobile, context-aware applications.

Energy efficiency and sustainability for software and services on the cloud.

Architectures and technologies supporting integration of

computing and networking environments; implications of Cloud Computing paradigm on networks

Open Source implementations of a software stack for Clouds

Management of cloud resources Infrastructure virtualisation Cloud Interoperability Open source implementation of a software stack for clouds

Objective 1.2

Internet of

services

Service engineering Integration of real and virtual worlds Scalability, self-management, fault localisation, …

Service engineering principles, methods and tools supporting development for the Internet of Services, including languages and tools to

model parallelism.

Services enabled by technologies for seamless

integration of real and virtual worlds, through the convergence with Internet of Things and Internet of Contents.

Massive scalability, self-management,

verification, validation and fault localisation for software-based services.

Methods and tools to manage life cycle of secure and resilient Internet-scale

applications from requirements to run-time and their adaptive evolution over time.

Objective 1.2

Advanced

software

engineering

Advanced engineering for software

Quality measure and assurance

Tools and methods for community-based and open source software development

Advanced engineering for software,

architectures and front ends spanning across all abstraction levels.

Quality measure and assurance techniques

which adapt to changing requirements and contexts, to flexibly deal with the complexity and openness of the Future Internet.

Management of non-functional requirements

typical of Internet-scale applications, like concurrency levels which will be orders of

magnitude larger than in today's applications, huge data stores and guaranteed performance over time.

Tools and methods for community-based and

open source software development,

Appel 8

•

Objectif 4 : Trustworthy ICT

a) Heterogeneous networked, service and computing environments b) Trust, eldentity and Privacy management infrastructures

c) Data policy, governance and socio-economic ecosystems d) Networking and Coordination activities

•

Instruments

: a), b), c) : PI et STREP ; d) : REX, CSA

•

Budget

: 80 M€

PI-STREP : 70 M€ (avec un minimum de 50 % PI et 30 % STREP) REX-CSA : 10 M€

Trust and Security: 58 projects

call 1&5

Networking, Coordination and Support Research roadmaps, metrics and benchmarks,

international cooperation, coordination activities

4 projects 2 projects Network infrastructures 4 projects 7 projects Services infrastructures 4 projects 7 projects 4 projects 4 projects Enabling technologies

Biometrics, trusted computing, cryptography

9 projects

Critical Infrastructure Protection

200 m€ Identity management, privacy, trust 8 projects 5 projects 40M€ 60M€ 48M€ 20M€ 27M€ 5M€

FP7-ICT Call 8: 1.4 Trustworthy ICT

Networking and coordination activities

Data policy, governance and

socio-economic ecosystems

Trust, eIdentity and Privacy

management infrastructures

Heterogeneous networked, service and

computing environments

80 m€ 70 M€ Min. 50% IPs Min. 30% STREPs Max. 10 M€ NoE, CSA

FP7-ICT Call 8: 1.4 Trustworthy ICT

Target outcomes

a) Heterogeneous networked service and computing environments

Trustworthy architectures and protocols Trustworthy Future Internet

Virtualisation and other techniques Metrics and tools for quantitative security Enabling technologies

b) Trust, eID and Privacy management Infrastructures

Trust assurance Privacy infrastructures

Management of ID claims (usability, privacy, control)

c) Data policy, governance and socio-economic ecosystems

Management and governance frameworks for trust and security policies Technology supported socio-economics frameworks

Multi-polar security governance Tools for trust measurement

d) Networking and Coordination Activities

Stimulating and organising interplay technology-law-society-economy Promoting standards, certification, best practices

Coordination national RTD activities

Expected Impact Industrial competitiveness – Trustworthy ICT

Support to users - Confidence, usability and acceptance

Demonstrable improvements – Large scale networks, network attacks and security incidents

Significant contribution (Trustworthy Infrastructures, interoperability and standardization, usability and acceptance

Coordination of research

« We » want …

•

An Influential Trust & Security

Research

community in Europe

•

A competitive Trust & Security

Industry

contributing to trustworthy ICT

•

To support

Policy

Appel 8

•

Objectif 6 : Future Internet Research and Experimentation

(FIRE)

b) FIRE Federation

c) FIRE Experimentation

e) Coordination and Support Actions

•

Instruments :

b) : only 1 PI ; c) : STREP (1 à 1,5 M€ sur 24

mois) ; e) : CSA

•

Budget :

25 M€

PI-STREP : 23 M€ (8 M€ en PI et 15 M€ en STREP) CSA : 2 M€

FIRE Projects – Call2 and Call5

30

OFELIA

Coordination and Support Actions

Experimentally-driven Research MyFire FIREBALL PARADISO 2 CREW Users Users TEFIS Smart Santander BonFIRE

Building the Experimental Facility and stimulating its use

PII

VITAL++ WISEBED

ONELAB2

OPNEX ECODE N4C SMART-NET

PERIMETER CONECT Nanodatacenters SELF-NET

FIREworks PARADISO SCAMPI CONVERGENCE HOBNET NOVI CONECT EULER LAWA SPITFIRE

14 pr

oj

ects,

40

M

€

Cal

l

2

-

2008

17

proj

ects, 50

M

€

-

Ca

ll

5

-2010

IP & STREP Facility Projects Call 2 STREP Projects Call 2 Coordination & support actions Call 2 Coordination & support actions Call 5 IP Facility Projects Call 5 STREP Projects Call 5

Requirements Validation Research Large Scale Experiments FIRE Station

FIRE plans under Work Programme

2011/12



Call 7 (closed in January 2011)

•

Maturing and expanding the FIRE Facility

 Complimentary areas (eg. Social Networks)

 Extending and advancing early prototypes

 IPs, 15M€

•

FIRE Science (Internet Science)

 Multidisciplinary NoE in holistic FI research

 Overcoming fragmentation and integrating life and human sciences

 NoE, 5M€



Negotiations ongoing (3 IPs, 2 Enl.EU , 1 NoE)

20% of the budget is allocated to open calls for all IP Apply to run experimentation on test beds

FIRE plans under Work Programme

2011/12

 Call 8 (1.6-b): FIRE Federation

• Implement a high level federation framework for all FIRE facilities

• Making Federation self-sustainable towards 2015

 Develop credible business models assuming decrease of EU funding • Develop joint FIRE portal

• Set common tools

• Brokering

• User access management

• Measurement and performance analysis

• Openness

• Use of open standards and open source approaches • To additional testbeds and facilities

• Standardization and certification policies

• Use existing research infrastructures (GEANT, NREN) • Cooperation with EU national and international initiatives

FIRE plans under Work Programme

2011/12



Call 8 (1.6-c): FIRE Experimentation

• Experimentally-driven research of Future Internet

• Using existing FIRE facility prototypes (need clear commitment)

• International Cooperation countries at use level is encouraged

• Visionary R&D subjects, e.g.

 holistic network and service architectures

 Applications with social value

 low energy and cost solutions

• Innovative usage of the FIRE facility(-ies), e.g.

 Large group of end-users

 Complex system level testing

 assessment of socio, economic, or environmental impact

 measurements and benchmarking

 STREPs only, Indicative budget: 15 M€

FIRE plans under Work Programme

2011/12



Call 8 (1.6-e): FIRE Coordination and Support

Action

•

International and EU-wide cooperation with related

stakeholders

• Public Private Partnership on Future Internet

• Initiatives in industrial countries / emerging economies

• Standardization

•

Exploiting synergies, developing standards, identifying

socio-economic requirements, analysing impacts, and

creating awareness

FIRE plans under Work Programme

2011/12

Call 8 – FIRE Expected Impact

•

Saving costs on experimentation activities

• More diverse and larger scale testing

• Broad end-user involvement / closer to reality

• Exploitation of results (infrastructures, products, services)

•

Improve EU Competitiveness in Future Internet

• Integrated large scale Experimental Facility

•

Broad and innovative use of Experimental Facility

• FI projects from EU, National and Intern. programmes

•

Better understanding by EU Industry / Academia

• Internet complexity as system of systems

• Changes at providing services and market opportunities

•

Strategic capability to assess Internet evolution

• Broad socio-economic-environmental implications

Appel 8



Défi 3: Chemins alternatifs aux composants et systèmes

 Ce défi se concentre sur plus de miniaturisation et sur l’augmentation de la performance dans les composants électroniques et photoniques, dans les micro/nano systèmes intégrant des fonctionnalités comme la détection, l'action, la communication, dans des voies alternatives pour de nouveaux composants et systèmes tels que l'électronique organique et les systèmes informatiques multi-cœurs, les systèmes embarqués, la surveillance et le contrôle, et des systèmes complexes coopérants.

 3.1 Very advanced nanoelectronic components: design, engineering, technology and manufacturability - Composants nanoélectronique très avancés: conception, ingénierie, technologies et fabrication

 3.2 Smart components and smart systems integration part b) Micro-nano-Bio systems - Composants intelligents et intégration de systèmes intelligents

 3.5 Core and disruptive photonic technologies (a), (c), (d) -Technologies photoniques clés et de rupture

Appel 8

•

Objectif 1 : Very advanced nanoelectronic components:

design, engineering, technology and manufacturability

a) Beyond CMOS technology b) Circuit-technology solutions

c) Nano-manufacturing and Joint Equipment Assessment d) Coordination and Support Actions

•

Instruments :

a) STREP ; b) PI-STREP ; c) PI, STREP ; d)

CSA

•

Budget :

60 M€

IP-STREP : 55 M€ (au moins 1 PI en b) ; au moins 1 PI en c)) CSA : 5 M€



Add elements from More than Moore and Beyond Cemos

What are we looking for?

 New advanced nanoelectronic components

based on “beyond CMOS devices” and their integration with advanced More than Moore elements and with existing and new nano-CMOS to support miniaturised electronic and communication technologies for 2020 and beyond.

 Improved technology, engineering, nano-manufacturing and design solutions for

increased performance, increased systemability, integratability and manufacturability.

 Joint equipment assessment and broker services to facilitate access to world wide market for SMEs and academics.

Obj. 3.1

Budget: 60M€

ITRS-ERD vision of the role of Beyond CMOS and More than Moore elements to form future extended CMOS platforms (2010).

ICT Work Programme 2011-12

Nanoelectronics

Objective 3.1: Very Advanced

Nanoelectronics Components

a) Beyond CMOS technology STREPs

55 M€ b) Circuit-technology

solutions

STREPs and at least 1 IP

c) Nano-manufacturing and Joint Equipment

Assessment

STREPs and at least 1 IP

d) Coordination and Support Actions

CSAs

What do we not want?



We want

very Advanced and Multidisciplinary

Research, but



We do not want



Research on components and technologies that do not

investigate the need to fulfil the criteria of “systemability”,

“integratability” and “manufacturability”, where appropriate.



Research focused on materials



Research focused on the development of equipment

Related Objectives or Programmes

•

NMP

•

FET

•

WP 2011-2012:

Obj. 3.1

•

WP 2011-2012:

Obj. 3.2

(a)

“Future smart

components and smart

systems”

•

ENIAC

Programme

•

CATRENE

Programme

Idea Proof-of-Principle Proof-of-Concept Prototype demonstration

FET

Obj.

3.1

Appel 8

•

Objectif 2 : Smart components and smart systems

integration

b) Micro-Nano Bio Systems (MNBS)

•

Instruments :

PI-STREPS

•

Budget :

39 M€

Micro-Nano Bio Systems projects



41 projects (FP6&FP7) 19 are running

 A. Biomedical

 B. Environment

What are we looking for? Interfacing

technologies and integrated systems

Appel 8

•

Objectif 5 : Core and disruptive photonic technologies

a) Core photonic technologies c) ERANET-Plus action

d) Development of innovative solutions through Pre-Commercial Procurement (PCP) action

•

Instruments :

a) sections 1 à 4 : PI, section 5 : STREP ; c) :

ERANET-plus ; d) : CP-CSA

•

Budget :

92 M€

PI-STREP : 79 M€ (50 % PI et 30 % STREP minimum) Action ERANET-Plus : 10 M€

Photonics and OLAE in FP7:

89 R&D - Budget 300 M€

Safety & Security Manufacturing

Photonics and OLAE

Technologies

Communications

Biophotonics

Flexible electronics

& Smart Textiles Organic

Objective 3.5 “Core and

Disruptive Photonic Technologies

”

a) Core photonic technologies

Application-specific photonic components & subsystems for: 1. Optical data communications

2. Biophotonics for early, fast and reliable medical diagnosis of diseases

3. Imaging & sensing for safety and security 4. Lighting and displays

Cross-cutting technology:

5. Photonics integration platforms

b) Disruptive photonic technologies

c) ERANET-Plus action

d) Pre-Commercial Procurement action

e) Coordination and Support actions

including ERA-NET action

117 M€

Call 8, 2011 IP + STREP Call 7, 2010, STREP IP Call 7, 2010, CSA Call 8, 2011, EN+ Call 8, 2011, CP

a.1 - Optical data communications

i. Communication networks: more transparent, dynamic, energy efficient and faster

– Core networks: Technology for truly cost effective transport at 100 Gb/s per

channel, scalable towards 100 Tb/s systems;

– Access networks: Affordable technology enabling 1-10 Gb/s per client over

more than 100 km

ii. Optical interconnects:

– Cost and energy effective technology for Tb/s optical links in short range

communication

– Applications range from on-board and board-to-board links at smaller scale to

links in data centres and LAN

“Radio-over-fibre” techniques (in access or LAN networks)

Call 8, opens 20 July 2011, closes 17 Jan 2012

 Consortia should include researchers, component manufacturers and suppliers of communication equipment

a.2 - Biophotonics for early, fast and

reliable medical diagnosis

■

Early, fast and reliable diagnosis of diseases

(e.g. cancer, infectious and eye-related diseases)

■

Applications: From point-of-care diagnosis to functional

imaging

■

Typical issues: High sensitivity, selectivity, resolution,

depth of penetration

■

Emphasis on strongly interdisciplinary work involving also

medical/biomedical end-users

■

Technical results should undergo preclinical validation, with

clinical trials being excluded

a.3 - Imaging and sensing for safety

and security

i. CMOS integrated, high-performance mega-pixel image sensors

operating at room temperature and low power. Focus is on:

– Single-photon detection (video-rate readout speed, very high dynamic range)

– Functional integration based on smart pixels (sub-picosecond time resolution, hyper-/multi-spectral resolution, polarisation sensitivity)

ii. Widely tuneable high-performance photonic sources for highly sensitive, selective and reliable detection of hazardous substances

Overarching issues:

■ Design goals: compact and cost-effective devices

■ Technical results should be validated for safety and security applications

Call 8, opens 20 July 2011, closes 17 Jan 2012

 Consortia should include researchers, component manufacturers and suppliers of safety & security imaging/sensing equipment

a.4 – Lighting and Displays

High brightness

LEDs

and

light engines

Focus on:

■

Improved efficacy at high brightness (warm white with efficacy

> 130 lm/W, CRI ≥ 90, consistent colour over 25000 hours)

■

High brightness, high efficiency green components

intensity peak around 540 nm

■

Novel approach to white components (e.g. new phosphors,

monolithic sources, hybrid approaches)

Call 8, opens 20 July 2011, closes 17 Jan 2012

 Consortia should involve LED suppliers and/or manufacturers

 System integration issues may be addressed (to some extent)  Significant system / operating cost reduction potential expected

a.5 – Cross Cutting Technology

Photonics integration platforms

for high volume

manufacturing of photonic integrated circuits ("PICs") that combine active and passive components

■ Address a range of different application fields

■ Address also the relevant design, modelling and simulation tools and

generic manufacturing and packaging technology

■ Present a credible route to industrial manufacturing in Europe ■ The technology must be scalable for increasing PIC complexity

d) Pre-Commercial Procurement (PCP)

PCP action in Photonics

Aim:

To achieve significant quality and/or efficiency

improvements to public sector challenges through

innovative photonics-based solutions

Expected Impact:

accelerate the introduction of advanced

photonic technologies and applications on the European

market

Call 8, opens 20 July 2011, closes 17 Jan 2012, 3 M€

A PCP action supports cooperation between public authorities to

define together the mid-to-long term solution requirements and to procure R&D services, ensuring:

 Benefit and risk sharing between procurers and suppliers  Competition and transparency in the procurement process  Compliance with legal framework without entailing State Aid

Appel 8



Défi 4: technologies pour le contenu numérique et les langages

 Ce défi vise à permettre aux individus et aux petites organisations de créer du contenu de qualité et des services innovants et à permettre aux personnes d’accéder et d’utiliser du contenu en ligne et des services au-delà des frontières de la langue. Il a aussi pour objectif la fiabilité de la récupération et de l’utilisation de ressources numériques au delà des plates-formes et des applications et à développer l’analyse de données (sur des volumes de données extrêmement importantes)

 4.4 Intelligent Information Management - Gestion intelligente de l’information

Appel 8

•

Objectif 4 : Intelligent Information Management

a) Reactive algorithms, infrastructures and methodologies b) Intelligent integrated systems

c) Framework and tools for benchmarking and exploring information management diversity

d) Targeted competition framework speeding up progress towards large scale information management systems of global relevance

e) Community building networks

•

Instruments :

a) STREP ; b) PI-STREP ; c) STREP ; d) SA ;

e) CA

•

Budget :

50 M€

PI-STREP : 43 M€ (au minimum 30 % PI et 50 % STREP) CSA : 7 M€

“Make content and knowledge abundant,

accessible, interactive and usable over time by humans

and machines alike.”



content

must be

made available

and its long term usability,

accessibility and preservation

must be ensured



effective technologies

need to be developed

for intelligent

content creation and management

and for supporting the

capture of knowledge

and its

sharing and reuse

Why do we need Intelligent

Information Management

• Call extends goals of ICT-2009.4.3

• ICT-2009.4.3 resulted in 17 projects (13

contracts signed)

• Some topics covered: logistics, business

intelligence, geospatial, linked open data

Intelligent Information Management SO 4.4

Target outcomes

a) Reactive algorithms, infrastructures and methodologies

for scaling data intensive techniques up to

extremely large

data volumes

and

real time

performance. (Must: Rigorously

tested on extremely large and realistically complex data sets

coming from diverse resources contributed by organisations

with a clear stake in the solution and a

clear path to

deploying it

if effective). /STREP/



the back end view of the problem: scalability matters



IoT makes data streaming important



many open scientific questions: parallelisation,

approximation, online processing, compression , …



maximise platform utilisation

Intelligent Information Management SO 4.4

Target outcomes

b)

Intelligent integrated systems

that

directly support decision making

and situation awareness

by dynamically integrating, correlating, fusing

and analysing

extremely large volumes

of disparate data resources and

streams

. (Must: Evaluated against the concrete requirements of relevant

professionals and communities and tested on appropriately- sized user

groups and extremely large data resources from the respective domains

(e.g.finance, engineering, government, geospace, transport, urban

management)). /IP, STREP/



the front end view of the problem: insight matters



IoT makes data streaming important



many open scientific questions: parallelisation, approximation, online

processing, compression , …



maximise platform utilisation

Intelligent Information Management SO 4.4

Target outcomes

c)

Framework and tools for benchmarking and exploring information

management diversity

and comparing and optimising the performance

of non mainstream data manage-ment architectures and computing

paradigms, novel data structures and algorithms on

extremely large

volumes of data

. /STREP/



allow meaningful comparisons across different solutions



open the field to any technically viable solution



establish rigorous methodology for evaluating performance



study performance evolution trends



identify bottlenecks

Intelligent Information Management SO 4.4

Target outcomes

d)

Targeted competition framework

speeding up progress towards large

scale information management systems of global relevance

. /SA/



put

concrete data problem

center stage



open the field to any technically viable solution



establish rigorous methodology for evaluating performance



study performance evolution trends

Intelligent Information Management SO 4.4

Target outcomes

e)

Community building networks and other initiatives

designed to link

technology suppliers, integrators and leading user organisations. /CA/



know who your community is



know what their needs are



bring cutting edge technology within reach of those who would benefit

Appel 8



Défi 6: TIC pour une économie faible en émission de carbone

 Ce défi se concentre sur le développement des TIC pour réaliser des gains d'efficacité substantiels dans la distribution et l'utilisation des ressources essentielles comme l'énergie et l'eau, ainsi que l'application des TIC à la « décarbonisation » des transports et à la rendre plus sûre. Ces activités incluent la contribution des TIC à des partenariats public-privé sur les bâtiments économes en énergie et sur les voitures vertes: les TIC pour le véhicule tout électrique.

 6.1 Smart energy grids - Gestion intelligente de l’énergie

 6.3 ICT for efficient water resources management - TIC pour une gestion efficace des ressources en eau

 6.7 Cooperative systems for energy efficient and sustainable mobility -

Appel 8

•

Objectif 1 : Smart Energy Grids

a) Strengthening the distribution grid by providing control systems management and decision tools

b) Advancing security and reliability, protection of equipment,fault detection and alert, self-healing

c) Data management infrastructures to control emecticity production and consumption

d) Home energy controlling hubs which collect (near) real-time data on energy consumption

e) Building consensus on industry-driven open standards

•

Instruments :

a), b), c), d) : STREP ; e) : CSA

•

Budget :

30 M€

STREP : 29 M€ CSA : 1 M€

Objective ICT-2011.6.1 Smart Energy Grids

ftp://ftp.cordis.europa.eu/pub/fp7/ict/docs/ict-wp-2011-12_en.pdf



Targeted Outcome: Intelligent systems and integrated

communication infrastructure that can assist in the

management of the

electricity distribution grids

in an

optimized, controlled and secure manner.



Key research challenges to be addressed:

a) Strengthening the distribution grid by providing control

systems, management and decision support tools that

enable the

integration of renewable energy sources

, both

large scale production (e.g. wind and solar farms) and

massively distributed production (e.g. residential and tertiary

buildings).

Objective ICT-2011.6.1 Smart energy Grids

 Key research challenges to be addressed (continuation):

b) Advancing security and reliability, as well as protection of equipment, fault detection and alert, and self-healing through development of the necessary high power electronics.

c) Data management infrastructures to allow electricity production and consumption to be measured, reported and controlled (and eventually credited or billed).

d) Home energy controlling hubs that will collect real-time or near real time data on energy consumption data from smart household appliances and enable intelligent automation.

e) Building consensus on industry-driven open standards to ensure the interoperability of smart grids control and management

systems.

Objective ICT-2011.6.1 Smart Electricity Grids



Projects should focus on one or a combination of the

previous points.



Consortia must be compact with partners each making

substantial contributions.



In all cases, projects shall include an appropriate validation

phase to draw conclusions for future deployment.

Objective ICT-2011.6.1 Smart Electricity Grids



Expected Impact:



Connection and operation of distributed and intermittent

generators of diverse technologies enabled by ICT.



Demand side and demand response management enabled

by innovative decision support systems.



Producers and consumers allowed to play a novel role in

the management of their energy consumption.

Objective ICT-2011.6.1 Smart Electricity Grids

 Expected Impact (continuation):

 Quantifiable and significant reductions of energy consumption in the electricity distribution grid, leading to reduction of the overall environmental impact of electricity grids.

 Enhanced levels of reliability and security of electricity supply.  For e), reinforced collaboration between the European electricity

suppliers and distributors, energy equipment manufacturers of all sizes, and the ICT sector.

Proposals should address the previous points only if applicable

Appel 8

•

Objectif 3 : ICT for efficient water resources management

ICT-enabled solutions for integrated water resources management (IWRM), involving as key building blocks: innovative demand management systems, decision support systems and data management technologies.

•

Instruments :

STREP

•

Budget :

15 M€

Outline

●

Background issues on

water

●

To support

RTD

on ICT tools, systems and

services

for

Efficient

Water

Resources

Management

ICT for Efficient Water Resources

Management

This is not a Southern Europe problem:

• About 3% of electricity consumption is used by water

pumping

• The biggest electricity bill in many municipalities is thr

sewage treatment.

• 20% of water is wasted during distribution because of

leaks

• Re-use of “grey water” for watering gardens and flushing

toilets has reduced per capita water consumption in

Cyprus by up to 40%.

Water Scarcity: EU policy

• Commission Communication “Addressing the challenge of water

scarcity and droughts. July 2007



Building and water efficiency



Leakage reduction in water distribution

networks



Water savings in agriculture



Labelling of equipment

• Follow-up reports and the 2012 policy review

http://ec.europa.eu/environment/water/quantity/scarcity_en.htm

Relation between Energy and Water management

•

Stringent to integrate local water sources back to the network

•

Always top-down vs. bidirectional flow of energy

•

Information collection requires extensive sensor networks

•

Can not use the water network as a communication network

–

Need to use existing telecom infrastructure or deploy a new

one

•

But

once the base infrastructure is in place, many principles of

energy

management

can

apply

(e.g.

demand-side

management…)

Avoid peaks Spread Usage Reduce Consumption Increase usage of local sources 5/11

Resources Challenges

•

Real-time monitoring and control at wide scale

•

Integrated management and decision support

based on data collection and aggregation

•

Empowering user with real time information to

create awareness and stimulate behavioural

change

•

Water smart meters and ICT tools to support leak

detection, automated meter reading through

communication networks

•

Management of multi-sources data and the

organisation of seamless databases

Objective ICT-2011-6.3 ICT for Efficient Water

Resources Management

Budget allocation: 15 M €

Integrate real-time

knowledge

on demand and supply

across water distribution

networks

and water sources.

Partnerships

between ICT

equipment providers, software

companies and water

authorities.

ICT-enabled solutions

for

Integrated Water

Resources Management

(IWRM)

, involving as

key

building blocks:

•

Innovative demand

management systems

,

•

Decision support

systems,

•

Data management

technologies

Objective

Target Outcome

STREPS

Objective ICT-2011-6.3 ICT for Efficient Water

Resources Management

Target Outcome

Target Outcome

SHALL

• Involve robust and proven technologies

•Take an holistic approach

MAY Include • Demand forecasting •Advance metering • Real-time consumption •Combined energy-water SHOULD Cover

•Research and Innovative integration

•Validation in at least 2 real-time operational environments

•Evaluation of anticipated cost/benefits and market prospects

Consortia MUST be compact

Objective ICT-2011.6.3 ICT for Efficient Water Resources Management

Expected Impacts

•

New

partnerships

between

European

water

distributors,

water

management

equipment

suppliers, water authorities and the ICT sector

•

Enhanced supervision of water networks leading to:

–

Better management of supply and flows

–

Quantifiable water consumption reduction

Call 8 PPP

•

Objectif

EEB-ICT-2011.6.5

:

ICT

for

energy-positive

neighbourhoods

Projects supported under this objective shall contribute to the European Energy-Efficient Buildings Initiative by developing management and control systems, and decision-support systems adressing the dynemics of energy supply and demand in neighbourhoods and extended urban/rural communities.

•

Instruments :

STREP

•

Budget :

30 M€

ICT NCP Meeting 13 May 2011

Energy-efficient buildings PPP

Context

•

What:

part of the Recovery Plan, to boost the construction sector.

•

Aims:

Support RTD on new green technologies and materials and

advanced energy efficient systems and services - this, with a view

to radically reducing energy consumption and CO2 emissions by

buildings.

•

Funding

:

– 0.5 B€ for research; Joint & Co-ordinated calls between four

relevant FP7 Themes: ENERGY/ENVIRONMENT/MNP/ICT

ICT NCP Meeting 13 May 2011

Extended

urban/rural areas?

Smart cities?

ICT for energy efficient buildings PPP

The 4 years strategy

Buildings 7 STREPs 5 STREPs

Call 2013

Call 2011

call 2010

Buildings and Surrounding spaces

Call 2012

Neighbourhoods 4/13

ICT NCP Meeting 13 May 2011

Objective EEB-ICT-2011-6.5

ICT for Energy-positive neighbourhoods

Target Outcomes

• Addressing the dynamics of energy supply and demand in

neighbourhoods and extended urban/rural communities



Management and control systems



Decision support systems

• Beyond buildings

• Integration of renewables

• Connection to the electricity grid

Shall

ICT NCP Meeting 13 May 2011

Objective EEB-ICT2011-6.5

ICT for Energy-positive neighbourhoods

Target outcomes

Technical Research

Appropriate business models

How to split incentives

How to engage users

How to commit public authorities

Target Outcomes

Interoperation with other ICT systems alerady

deployed

e.g Traffic management, GIS

SHALL

MAY

ICT NCP Meeting 13 May 2011

Objective EEB-ICT-2011-6.5

ICT for Energy-positive neighbourhoods

Target outcomes

• A substantial validation Phase



Record evidence of benefits



Total cost of operation



Scalability potential



User benefits

• Conosrtia be compact

SHALL

MUST

9/13

ICT NCP Meeting 13 May 2011

Objective EEB-ICT-2011-6.5

ICT for Energy-positive neighbourhoods

Expected Impact

• Contribution to the opening of a market for

ICT-based district/community energy management

systems

• Establishment of a collaboration framework

between the ICT sector, the buildings and

construction sector and the energy sector

• Quantifiable and significant reduction of energy

consumption and CO2 emissions through ICT.

Appel 8

•

Objectif 6.7 : Cooperative Systems for energy efficient and

sustainable mobility

a) Cooperative Systems for low-carbon multi-modal mobility

b) European Wide Service Platform (EWSP) for cooperative system enabled services c) Coordination and support actions

•

Instruments :

a), b) : PI-STREP ; c) CSA

•

Budget :

40 M€

PI-STREP : 37 M€ (au moins 1 PI en a) et 1 PI en b), le reste en STREP) CSA : 3 M€

17 February 2010, Brussels ••• 88

Addressing the Challenges

ICT for Transport - RTD in the 6

th

and the 7

th

FP

2002

2003

2004

2005

2006

2007

2008

2009

2010

2011

2012

2013

Intelligent Vehicles & Mobility Services Moving to Cooperative Systems

Call 1 Call 4 14 projects 80 M€ grant 22 projects 92 M€ grant

Intelligent Vehicles & Mobility Services Cooperative Systems

Safety & Energy Efficiency in Mobility Fully Electrical Vehicle

Mobility of the Future

Low carbon multimodal mobility & freight transport

Cooperative Systems for energy efficient & sustainable mobility Call 4 Call 6 Call 1 Call 2 14 projects 57 M€ grant 12 projects 48 M€ grant 10 projects Budget: 53M€ Budget: 37M€ Call 5 Budget: 20M€ Call 7 Call 8 Budget: 40M€ Budget: 50M€

Contributing to Green Mobility

eCoMove Elvire Ecogem IFM project

Europtima iTetris

Sunset PowerUp SmartV2G

Roadidea + Inco

In-Time

Logistics & Freight

Euridice Logistics4life SmartFreight FREILOT Contributing to Safety 2Wide_sense Adose Have-it Fnir ARTIC InteractIVe Mosarim ATESST2 Minifaros eValue Saferider ActiveTest HeERO

Security & privacy

Evita Oversee Preserve Preciosa Supporting activities iCar Support iCars Network eSafety Challenge SCVP ECOSTAND

Field Operational Test

Drive C2X TeleFOT + inco euroFOT FOT-Net 1+2 FOTsis ITSSv6 Festa Cooperative Systems COMeSafety2 eFrame Rosatte Intersafe2 Nearctis Pre-Drive P3ITS COSMO Co Cities GeoNet Studies

ICT for

Transport

EC funding 213.5 M€ EC funding 41.4 M€ EC funding 65.3 M€ EC funding 49.9 M€ EC funding 12.2 M€ EC funding

24.9 M€ FP7 & CIP Projects

in ICT for Transport

(CIP projects integrated by topics)

EC funding 6 M€ Completed projects Running projects EC funding 13.8 M€

••• 90

Workprogramme 2011-2012

Overview of the calls…

Call 8

Objective 6.7

Cooperative Systems for energy efficient and sustainable mobility

• Cooperative Systems for

low-carbon multi-modal mobility • European Wide Service Platform

(EWSP) for cooperative system enabled services

•Coordination and Support Actions IPs, STREPs: 37M€

CSA: 3M€

Call PPP

Objective 6.8

Green Car: ICT for the Fully Electric Vehicle

•Integration of the FEV in the cooperative transport infrastructure

Workprogramme 2011-2012 – Call 8

Cooperative Systems for energy efficient

and sustainable mobility

•

Cooperative Systems based on vehicle-to-vehicle

(V2V) and vehicle-to-infrastructure (V2I and I2V)

communications are enablers of decarbonised

transport

•

A broad approach is needed where cooperative

systems

 foster a holistic, pro-active approach to urban and

inter-urban traffic monitoring, control and management

 enable the development of traffic management systems

that become proactive predicting traffic flow and volume and taking pre-emptive measures to avoid incidents

••• 91

Call 8

IPs, STREPs: 37M€ CSA: 3M€

Target outcome:

a)

Cooperative Systems

for low-carbon multi-modal mobility



covering cooperative applications and services for

energy efficiency and eco-friendly mobility



Focus should be on road transport but projects can

address all transport modes

b)

European Wide Service Platform

for cooperative system enabled services



aiming at providing to the drivers a large variety of

energy efficiency, mobility, comfort and safety

related services

c)

Coordination and Support Actions

Workprogramme 2011-2012 – Call 8

Cooperative Systems for energy efficient

and sustainable mobility

IP

STREP

CSA IP STREP

Call 8 PPP

•

Objectif GC-ICT-2011.6.8 : ICT for Fully Electric Vehicles

(FEV)

a) Electric Drive and Electronic Components

b) Integration of the FEV in the cooperative transport infrastructure c) Functional Safety and Durability of the FEV

d) Coordination and Support Action « FEV made in Europe »

•

Instruments :

a), b), c) : STREP ; d) : CSA

•

Budget :

30 M€

STREP : 29 M€ CSA : 1 M€

• Package of 5 B€ : 4 B€ EIB loans, 1 B€ research grants • Research Roadmap by ETPs: ERTRAC, EPoSS, SMARTGRID

• Benefits of the fully electric vehicle:

• At least 40% energy saving

• Reduced fossil fuel dependence & environmental impact • Socio-economic impact:

12 million jobs & international competitiveness

• Challenges:

• From 1 combustion engine to 2 or 4 in-wheel electric motors • Energy recovery from braking

• Batteries: cost & business model, driving range, lifetime,

energy management

• Power electronics and safety

• EU-wide standards for chargers/plugs

European Green Car Initiative

ICT focus:

“

Fully Electric Vehicle

and its infrastructure” 2010-2013

ICT FP7 2010 2011 2012 2013 Total 120 500 30 140 40 140 M€ 20 105 30 115

Funding

scheme # received threshold # above # retained / reserve

STREP 12 6 (50%) 6 / 0

CSA 3 1 (33%) 1 / 0

Total 15 7 (47%) 7 / 0

•

SUCCESS RATE: 1:2

(in terms of number of proposals & budget)

•Participations in retained proposals: 66% from industry (18% SMEs)

Closed 3 Nov 09

Budget 20 M€

Results from the first call

ICT-2010-10.3

ICT for the Fully Electric Vehicle

Funding

scheme # received threshold # above # retained / reserve

STREP 17 10 (59%) 8 / 0

•

SUCCESS RATE: 1:2

(in terms of number of proposals & budget)

•Participations in retained proposals: 67% from industry (28% SMEs)

Closed 2 Dec 2010

Budget 30 M€

Results from the second call

ICT-2011-6.8

ICT for Fully Electric Vehicles

Target outcomes:

Objective 6.8:

Green Car: ICT for Fully Electric Vehicles

Call FP7-2012-ICT-GC 30M€ Streps / CSA Call FP7-2011-ICT-GC 30M€ Streps

Electric Drive & Electronic Components

Vehicle Stability Control

Functional Safety & Durability Architecture for Energy,

Communication &

Thermal Management,

Energy / Power Storage Systems Vehicle 2 Grid Interface Integration in cooperative transport Infrastructure

CSA “FEV made in Europe”

Closing 1 Dec 2011

Appel 8



Défi 7: TIC pour l ’entreprise et la fabrication



Le défi 7 intègre les contributions des TIC pour le partenariat

public-privé sur les usines du futur. Il vise à améliorer la base

technologique de la fabrication dans un large éventail de

secteurs en améliorant, non seulement leur efficacité et leur

capacité d'adaptation, mais aussi la viabilité des systèmes de

fabrication ainsi que leur meilleure intégration dans les

processus d'affaires

 7.1 PPP FoF: Smart factories: energy-aware, agile manufacturing and customisati