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TILAS doc template
CELTIC PLUS – SMART CONNECTED WORLD
Technology Improvements for Large scale
Smart Cities Deployments (C2012/1-9)
WP6 – Dissemination and Exploitation
D6.3 Exploitation report
D6.4 Dissemination and standardization report
Date of Delivery:
15/11/2015
Responsible:
TST
Contributing Beneficiaries:
TTI, UPEC, Bankoi, CEA, Gemalto, Argela, Webdyn,
Pangaea
Security:
Public
Nature
Report
Version:
1.0
Disclaimer
This document contains material, which is the copyright of TILAS Celtic Plus Project, and may
not be reproduced or copied without permission.
All PARTICIPANTS have agreed to full publication of this document.
The commercial use of any information contained in this document may require a license from
the proprietor of that information.
Neither the PARTICIPANTS nor the CELTIC Initiative warrant that the information contained in
the report is capable of use, or that use of the information is free from risk, and accept no
liability for loss or damage suffered by any person using this information.
CELTIC-PLUS
Deliverable ID: WP1/D1.2a
Document Information
Document ID:
Version Date:
Total Number of
Pages:
Abstract
Keywords
TILAS_D6.3-D6.4.docx
13/08/2014
22
This deliverable is the summary report on dissemination
and standardization activities together with the final and
extended exploitation plans per partner.
Authors
Name
Javier Valiño
Bruno Cendón
Organization
TST
TST
Email
[email protected]
[email protected]
Ichrak Amdouni
Nadjib Ait Saadi
Abdelhamid Mellouk
Burak Gorkemli
Sylvie Mayrargue
Ilan Mahalal
UPEC
UPEC
UPEC
Argela
CEA
Gemalto
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
Approvals
Internal Reviewer 1
Public
Name
Javier Valiño
Organization
TST
Date
15/11/2015
Visa
OK
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EXECUTIVE SUMMARY
Dissemination of scientific and technological advances is an important objective of the
TILAS project. As such, TILAS partners have devoted consistent efforts in maximizing
dissemination of the project results and thus secure a lasting impact in both scientific
and industrial communities with an interest on Internet of Things (IoT).
At the beginning of the project, a dissemination plan was created. In it, the main
dissemination objectives were outlined and several internal tools to manage
information and its distribution were planned. Through the use of such tools, TILAS
dissemination objectives have been fulfilled.
In the scientific context, the Project has generated 13 publications in leading peerreviewed journals and conferences. Moreover, members of the TILAS project team
have participated and chaired technical committees, and given keynote speeches, all
these in the topic of IoT, and directly reporting results from the Project.
Efforts in the industrial community have been directed mainly at the leading standards
bodies.
This deliverable reports in detail on the activities on all these fronts. It is organized in a
number of sections covering standardization (Section 1), publications (Section 2) and
other activities (Section 3).
In addition, as a result of joining D6.3 and D6.4 deliverables, section 5 present the
individual, refined and extended exploitation plans per partner in which each
organization explains the foreseen roadmap to make effective use of the knowledge
gained during TILAS project, with the envisaged and concrete impacts.
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TABLE OF CONTENTS
List of Figures ............................................................................................................... 5
1
2
3
Activities in Standardisation Bodies and Industry Fora ........................................... 6
1.1
ETSI Smart M2M ............................................................................................ 6
1.2
OneM2M partnership project........................................................................... 7
Publications ........................................................................................................... 9
2.1
Journals, Magazines, and Books .................................................................... 9
2.2
Conferences and Workshops .......................................................................... 9
Other Dissemination Activities ............................................................................. 11
3.1
3.1.1
Face-to-Face Meetings .......................................................................... 11
3.1.2
Project File Repository........................................................................... 11
3.1.3
Regular Phone Conferences.................................................................. 12
3.1.4
Mailing Lists ........................................................................................... 12
3.2
4
5
Internal Dissemination .................................................................................. 11
External Dissemination ................................................................................. 12
3.2.1
Project Website ..................................................................................... 12
3.2.2
Booth and Presentations at the CELTIC Event in Monaco/Vienna ......... 13
3.2.3
Presentations at Scientific and Technological Events ............................ 14
3.2.4
Organization of Conferences ................................................................. 14
3.2.5
Journal Special Issues ........................................................................... 15
Exploitation plans................................................................................................. 16
4.1
TST............................................................................................................... 16
4.2
TTI ................................................................................................................ 17
4.3
BANKOI ........................................................................................................ 17
4.4
UPEC ........................................................................................................... 18
4.5
GTO.............................................................................................................. 18
4.6
CEA-LETI ..................................................................................................... 19
4.7
TT ARGELA.................................................................................................. 19
4.8
PNG.............................................................................................................. 20
4.9
Webdyn ........................................................................................................ 21
Conclusions ......................................................................................................... 22
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LIST OF FIGURES
Figure 5-1. Screenshot of Confluence file repository. .................................................. 12
Figure 5-2. TILAS website under http://www.tilas.eu. .................................................. 13
Figure 5-3. TILAS booth at CELTIC Event Vienna. ..................................................... 14
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1 ACTIVITIES IN STANDARDISATION BODIES AND INDUSTRY
FORA
TILAS members have contributed on the following standardisation forums which are
related to the TILAS project.
1.1 ETSI SMART M2M
ETSI Smart M2M and OneM2M (see below) are engaged in standardizing a world-wide
M2M service layer that can guarantee the interoperability between the different lower
layer standards. This M2M service layer provides the needed services like data
transport, security, devices management and device discovery in a harmonized
manner to the application layer. These services are independent from the underlying
communication infrastructure and the deployed standards. In addition to these basic
services, a cross vertical semantic support should be included into the service layer
capabilities (e.g. data models translations).
ETSI Technical Committee M2M Machine to Machine Communications was created in
2007 to develop a horizontal approach to M2M communication that could be
implemented as an overlay to a telecommunication network. The group aimed to
provide a cross vertical end-to-end view of Machine to Machine standardization, and
co-operated closely with ETSI's activities on Next Generation Networks, and also with
the work of the 3GPP standards initiative for mobile communication technologies. Its
Technical Specifications are divided in 3 stages:
1) Stage 1: Definition of the M2M Service Requirements in ETSI TS 102 689.
2) Stage 2: Definition of the M2M Functional Architecture in ETSI TS 102 690.
3) Stage 3: Specification of technical aspects of M2M Communications (mIa,
dIa and mId interfaces) in ETSI TS 102 921.
A first release was published at the end of 2011 and is no longer maintained. The last
deliverables of the second release were just published beginning 2014. Release 2 adds
cross service providers communication, enhancements for lightweight (i.e. constrained)
devices, and security interoperability including smart-card (UICC) based
implementation, optionally with secure channel to trusted device environment, including
OTA remote administration capabilities.
The Stage 3 specification includes a description of RESTful-based procedures in order
to define how M2M Applications in Device, Gateway or Network (DA, GA, NA) and
M2M SCL exchange information with each other. RESTful procedures can then be
mapped on standard IETF protocols such as HTTP or CoAP.
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Several Technical Reports support the main deliverables in several areas such as
Threat Analysis, Interworking with M2M Areas Networks (i.e. deployed MAN/HAN/LAN
technologies) or the support of interoperable semantics.
The security may rely on the Access Network provided mechanisms when trusted, on
secure channel establishment at the M2M Service Layer (e.g. using TLS), or on data
security provided at the object level.
The bootstrapping of security credentials to a multitude of objects across various
environments with potentially different constraints in terms of computing resources is
addressed in M2M release 1 by offering several options suitable for different scenarios.
The integration of existing protocols for Device Management, i.e. OMA DM 1.x
(dominant for mobile networks) and BBF TR 069 (dominant for fixed network) into the
M2M platform is also addressed (cf. ETSI TS 101 404 and ETS TS 101 405).
In ETSI SmartM2M the focus is still on Semantics and Ontologies to support an EU
Smart Appliances label (Smart appliance = any device that produces or consumes
energy). A Specialist Task Force was also created to support the standardization
package of the AIOTI framework targeting large-scale IoT pilot deployments in EU
countries.
1.2 ONEM2M PARTNERSHIP PROJECT
ETSI TC M2M specifications set the ground for international consolidation efforts in
M2M standardization within the "OneM2M" partnership formed by ETSI (Europe), ARIB
and TTC (Japan), ATIS and TIA (USA), TTA (Korea) and CCSA (China), started at the
end of 2012 in an effort to consolidate the horizontal approach to M2M standardization
initiated by ETSI at an international level. The organization of the partnership is quite
similar to 3GPP.
The oneM2M Partnership Project gathers huge attendance and supports heavy activity
with 6 meetings a year and weekly conference calls for its 5 technical working groups:
1.
2.
3.
4.
5.
Requirements,
Architecture,
Protocols,
Security
Management, Abstraction and Semantics.
A special “Partner Type 2” status enables vertical specification organizations such as
industry fora to participate to the effort, though the success in doing so beyond telecom
industry dominated organizations is currently limited. Beyond OMA and BBF which are
not M2M focused, the Continua Health Alliance and the Home Gateway Initiative are
the major oneM2M Type 2 partners. Political issues have not yet enabled this initiative
to receive an ITU endorsement.
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In the publications of release 1 in January 2015 (set of 10 technical specifications), the
focus in 2015 was on defining new Work Items for Release 2 and deriving the high
level requirements corresponding to the new features.
The focus areas for the new release include:
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Establishing oneM2M as a federating platform for existing M2M / IoT protocols,
via the definition of Interworking functionalities with OMA LwM2M, AllJoyn, OIC,
etc.
Enhanced interface between oneM2M Service Layer and 3GPP underlying
networks, following inclusion of Machine-type communication functionalities in
the latest 3GPP release
Support for data semantics and ontologies
On the security side:
o enhancing the authorization mechanisms to address increased
complexity due to migration from centralized industrial M2M predictable
“one to many” deployments to dynamically evolving distributed “many to
many” IoT scenarios. This leverage on the development of the
Authorization Manager that was done in TILAS.
o Development of an interoperable API enabling applications on M2M
Devices to make abstraction of locally supported security technologies
(e.g. presence of a UICC or other embedded Secure Element or TEE or
whatever)
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2 PUBLICATIONS
Publications are crucial in order to disseminate TILAS results to the scientific
community. Moreover, they have a long term impact in the form of new findings. As the
next sections illustrate, several articles have been published or accepted in prestigious
journals and conferences such as IJAHUC, IEEE IoT Journal, IFIP or European
Wireless 2015.
This section lists all publications directly related to TILAS and authored by members of
the TILAS team. The project was duly acknowledged on all publications. Besides the
authors, in each publication it is identified the relationship with the partner institution
and in which work package of TILAS the work was carried out.
2.1 JOURNALS, MAGAZINES, AND BOOKS
The following journal publications (4) have been recently published or have been
accepted for publication in the coming months:
[M. R. Senouci, A. Mellouk, A. Aissani] (UPEC, WP4) [Random Deployment of
Wireless Sensor Networks], accepted for publication in [Inderscience
International Journal of Ad Hoc and Ubiquitous Computing (IJAHUC),
Inderscience Ed., 15(1/2/3), pp. 133-146], 2014.
[M. R. Senouci, A. Mellouk, L. Oukhellou, A. Aissani] (UPEC, WP4) [WSNs
deployment framework based on the theory of belief functions] accepted for
publication in [Computer Networks, Elsevier Ed., Volume 88, 9, pp. 12–26],
2015.
[M. R. Senouci, A. Mellouk, A. Senouci, L. Oukhellou] (UPEC, WP4) [Belief
Functions in Telecommunications and Network Technologies: An Overview]
accepted for publication in [Springer Annals of Telecommunications, Springer
Ed., Vol. 69 (3-4), pp. 135-145], 2014.
[C.Hennebert, J. Dos Santos] (CEA, WP3) [Security Protocols and Privacy
Issues into 6LoWPAN stack: A synthesis] accepted for publication in [IEEE
Internet of Things Journal, Vol. 1, Issue 5, pp. 384-398] October 2014
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2
3
4
2.2 CONFERENCES AND WORKSHOPS
During TILAS project lifetime, there have been 9 contributions presented to, or
accepted for, conferences and workshops. The following list enumerates papers that
have been accepted and/or published. In brackets it is indicated the institution that the
partners belong to, as well as the corresponding Work package in TILAS.
1. [Boutheina Dab, Ilhem Fajjari, Nadjib Aitsaadi and Abdelhamid Mellouk]
(UPEC– WP3) [A Novel Wireless Resource Allocation Algorithm in Hybrid Data
Center Networks] accepted to [12th IEEE International Conference on Mobile
Ad hoc and Sensor Systems - IEEE MASS 2015, Dallas, Texas, USA] [October
19–22, 2015].,
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2. [Oussama Soualah, Ilhem Fajjari, Nadjib Aitsaadi and Abdelhamid Mellouk]
3.
4.
5.
6.
7.
8.
9.
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(UPEC – WP3) [A Batch Approach for a Survivable Virtual Network Embedding
based on Monte-Carlo Tree Search] accepted to [IFIP/IEEE International
Symposium On Integrated Network Management - IM 2015, Ottawa, Canada],
[May 11–15, 2015].
[Mohamed-Haykel Zayani, Nadjib Aitsaadi and Paul Mühlethaler] (UPEC –
WP3) [A New Opportunistic Routing Scheme in Low Duty-Cycle WSNs for
Monitoring Infrequent Events] accepted to [IFIP Wireless Days Conference, Rio
de Janeiro, Brazil], [November 12–14, 2014].
[Oussama Soualah, Ilhem Fajjari, Nadjib Aitsaadi and Abdelhamid Mellouk]
(UPEC, WP3) [A Reliable Virtual Network Embedding Algorithm based on
Game Theory within Cloud's backbone`] accepted to [IEEE International
Conference on Communications - ICC 2014, Sydney, Australia], [June 10–14,
2014].
[M. R. Senouci, A. Mellouk], (UPEC, WP4) [Intrinsic properties of node
placement in sensor networks] accepted to [Symposium on Wireless Sensor
Networks, France], [July 1 – 4], 2013.
[M. R. Senouci, A. Mellouk, L. Djafri, M. Souidi], (UPEC, WP4), [Analytical
Deployment of Wireless Sensor Networks] accepted to [International
Conference on Networks & Systems for Critical Applications, Algeria], [April 2023, 2013].
[Oussama Soualah, Ilhem Fajjari, Nadjib Aitsaadi and Abdelhamid Mellouk]
(UPEC– WP3) [PR-VNE: Preventive Reliable Virtual Network Embedding
Algorithm in Cloud's Network] accepted to [IEEE Global Communications]
[J. Dos Santos, C. Hennebert, C. Lauradoux] (CEA-WP3) [Preserving privacy in
secured ZigBee Wireless Sensor Network][IEEE World Forum on Internet of
Things, Milan, Italy] December 2015.
[L.H.Suraty Filho, B. Denis, M. Maman] (CEA-WP3) [Design and Analysis of
Distributed Mobility Management Schemes for Wireless Sensor Networks]
[European Wireless 2015, Budapest, Hungary] May 2015
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3 OTHER DISSEMINATION ACTIVITIES
This section summarizes other internal and external dissemination activities of TILAS
project that are not yet discussed in preceding section 2.
These are face-to-face meetings, phone conferences, collaboration tools, the project
website, participation at scientific and technological events and other related CELTIC
projects, and additional individual dissemination activities by project partners.
3.1 INTERNAL DISSEMINATION
The following subsections present the internal, i.e. not public dissemination activities
among the project partners.
3.1.1 FACE-TO -FACE MEETINGS
Plenary face to face meetings have been intensively used as platform to present the
key achievements of the ongoing research activities to other project partners. In all
plenary meetings dedicated sessions for single work packages or cross work package
topics were organized. In the following all face-to-face meetings are listed:
1.
2.
3.
4.
5.
6.
7.
Kickoff meeting Santander April 2013
1st Plenary meeting Malta October 2013
2nd Plenary meeting Paris April 2014
3rd Plenary meeting and MTR Paris September 2014
4th Plenary meeting Mallorca March 2015
5th Plenary meeting Istanbul September 2015
6th Plenary meeting and FR Santander December 2015
3.1.2 PROJECT FILE REPOSITORY
For the exchange of each kind of documents including internal dissemination results a
Confluence file repository was used. Also the publications at conferences and
workshops and in journals and magazines are available on this server. Figure 5-1
shows a screenshot of the one particular page handling the deliverable creation
process.
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Figure 5-1. Screenshot of Confluence file repository.
3.1.3 REGULAR PHONE CONFERENCES
As TILAS comprised a relatively small group of partners, phone conferences were
organized at project level and were scheduled at least with 4 week periodicity and
planning also special occurrences depending on the proximity of planned milestones or
deliverable preparation.
These meetings were established as a forum for the exchange of achievements
including internal dissemination results and for technical discussions.
3.1.4 MAILING L ISTS
A further means for internal dissemination and technical discussions was the usage of
mailing lists. For each work package one individual list was available. Moreover, lists
for the General Assembly (including all TILAS contacts) were established.
3.2 EXTERNAL DISSEMINATION
This subsection contains actions of external dissemination which did not fall into
the categories of preceding sections.
3.2.1 PROJECT W EBSITE
The project website (screenshot see Figure 5-2) was a useful dissemination tool for
the entire duration of the project. It was frequently updated with all public documents
of the TILAS project, such as publications and public deliverables.
The original TILAS website (located at www.tilas.eu) has been discontinued due to the
fact that it was managed by PARAGON and they left TILAS project. As TILAS
members were not able to re-gain control over the former website, a new one was
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created on http://tilas-eu.com. This one contains the latest results and info regarding
the project.
Figure 5-2. TILAS website under http://tilas-eu.com.
3.2.2 BOOTH AND PRESENTATIONS AT THE CELTIC EVENT IN MONACO /VIENNA
The TILAS project participated actively in all two CELTIC EVENTs organized during
TILAS lifetime (Viena 2015 and Monaco 2014) A booth was dedicated to the project,
where its main developments were showcased through graphic material (posters,
slides) as well as demonstration platforms showing OTAP dissemination features by
TST and multimedia routing by UPEC. The booth was an outstanding setting for having
technical discussions and feedback from worldwide experts present at the Summit.
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Figure 5-3. TILAS booth at CELTIC Event Vienna.
3.2.3 PRESENTATIONS AT SCIENTIFIC AND TECHNOLOGICAL EVENTS
The dissemination activities conducted by TILAS partners also encompassed the
following presentations in various S&T events, namely,
1. [Ichrak Amdouni, Nadjib AitSaadi, Cédric Adjih, Ahmed Benaissa], (UPEC –
WP6) [International conference CLOUDIFICATION OF THE INTERNET OF
THINGS CIoT 2015], [Paris, France], [10-12/06/2015].
2. [Juan Rico] (TST – WP6) Going beyond monitoring and actuating in large scale
smart cities Going beyond monitoring and actuating in large scale smart cities.
[WIMA Conference Monaco 2014]
3. [Juan Rico] (TST – WP6) Panel Mobile Technologies & Contactless Services
for Smart Cities. [WIMA Conference Monaco 2014]
4. (Pangaea – WP6) Introduce the large-scale IoT concepts of TILAS project
[2014 ICT Creative Developer Conference (IoT, Social WoT, Open Source
HW)]
5. [Philippe Faugeras] (Webdyn-WP6) Smart Grid and data network [Smart Grid
Paris may 2015)
3.2.4 ORGANIZATION OF CONFERENCES
UPEC partner has co-organized with Inria Lille the first international conference on
“cloudification of the Internet of things” (CIoT 2015: http://www.dnac.org/DNAC/iot/).
CIoT is the first international conference focusing on the challenges of Internet of
Things while considering the whole architecture based on Cloud solutions. The main
objective of this conference is to address all the problematic of IoT systems from the
sensors and machines to the end-users attached to the Cloud, topics that the TILAS
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project is addressing. Notice that a part of the TILAS project contributions has been
presented in this conference (Section 3.2.3).
Place of the conference: Paris, France.
Date: June 10-12, 2015.
3.2.5 JOURNAL SPECIAL ISSUES
Following the CIoT 2015 conference, UPEC, with other organizations, has launched a
special issue on the Internet of Things (IoT):
Journal: Springer Annals of telecommunications journal
Special issue: Special issue on Cloudification of the Internet of Things
(https://annalsoftelecommunications.wp.mines-telecom.fr/2015/04/02/call-for-paperscloudification-of-the-internet-of-things/).
This special issue has the particular emphasis on the use of the Cloud as a central
component of IoT architecture and a key infrastructural support for IoT applications.
The main objective of this special issue is to address the entire spectrum of research
issues pertaining to the use of Cloud infrastructures in support of IoT systems from the
sensors and machines to the end-users and application hosted in the Cloud. The
special issue seeks novel research contributions and experience papers tackling the
challenges in these areas, including but not limited to: Architecture and protocols based
on Cloud for IoT, Cloud infrastructure and middleware solutions for IoT, Software
Defined Network (SDN) for IoT, Network Function Virtualization (NFV) for IoT, Green
communication for IoT based on Cloud solutions, Centralized and distributed systems
for IoT in Cloud environment, Routing solution for IoT, etc.
The guest editors of this special issue are:
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Nadjib Aitsaadi, University Paris Est Creteil (UPEC), France (partner of TILAS
project).
Raouf Boutaba, Waterloo University, Canada
Yutaka Takahashi, University of Kyoto, Japan
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4 EXPLOITATION PLANS
This section covers individual exploitation plans envisaged for all TILAS partners
starting at the end of the project.
They have been elaborated thoroughly and having in mind all potential opportunities
arising as a result of TILAS impacts on the IoT world and related to each partner’s
activities inside the project.
4.1 TST
TST will take benefit of the OTAP protocol created for simplifying the way the devices
can be remotely reprogrammed. This proposal is being validated in TILAS project and
will be fully tested in the final demonstrator.
The module for the integration of heterogeneous technologies in a single platform will
be implemented in the new TSmoTe module so as to simplify the bootstrapping of
devices behind the TST gateway.
The level of integration and agreement with third parties achieved on TILAS Santander
deployments opens also a great opportunity for TST in terms of long term
collaborations:
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Santander municipality has shown interest on TST technology already deployed
on the demonstrator. Due to its interoperability with already placed products and
the state of the art technology integrated on the devices, TST foresees new
rounds of deployments using similar nodes on different IoT applications on the
city in collaboration with the local government on its way to enhance Santander
SmartCity.
SmartSantander project and Fi-Ware initiative as a living platform for IoT data
were very excited from the moment TST contacted them proposing this
extension of the nodes placed on the city. The collaboration with
SmartSantander is still open and new collaborations in terms of additions to
their network or replacements can be considered on the future. In addition, FiWare sees TST as a great value partner as the middleware integration is
already on board and visible to the public, so they have requested permission to
present TST hardware platform as a ready-to-use family of devices embedding
Fi-Ware features, announcing them on their web page. This also opens a great
exploitation opportunity to place TST devices enhanced with TILAS proposals
all over the world.
Finally, as additional hardware, firmware and software integrations were made
between TST and TILAS partners, now TST devices are compatible with
Webdyn Gateways, and they are all integrated into Argela’s middleware. In
addition, TTI antennas and enclosures are prepared to act as placeholders for
TST devices. This way, any new IoT opportunities arising to any of the
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aforementioned partners could constitute a potential opportunity to work again
together delivering a complete IoT application.
TST’s strategy on TILAS as an SME has been to exploit and develop on IoT systems
their work on heterogeneous networks, device management and cooperative wireless
architectures.
TILAS allowed TST to enter on the future of IoT keeping the competitiveness of its
services on the mid-term and being on a lead position through innovation for the
introduction of future products. Also, participation into the IoT project has and will foster
ideas for brand new solutions on IoT protocols.
4.2 TTI
Set of embedded antennas designed for TILAS project allow TTI to offer customers
integrated antenna solutions for terminals of all available wireless technologies. Not
only terminals for smart cities (ZigBee, 6LowPan, IEEE 802.15.4), but also terminals for
Bluetooth and all WI-Fi standards communications.
Enclosure of Santander Demonstrator of TILAS project is a customized design to
embed all terminal parts, including antenna, and to obtain a non-visual impact
enclosure, while obtaining watertightness capabilities. This design can be adapted to
almost any terminal, giving TTI the opportunity to offer customers an almost fully
customizable enclosure for outdoor and indoor terminals of any technology.
In the case of Santander Demonstrator, TTI complete TST IoT terminal, having a full
solution for IoT applications, suitable for future customer requirements.
4.3 BANKOI
The development of a lamp actuator using PLC over G3 for the TILAS project, will
allow Bankoi to sell a Street Light control using IPv6 to their clients, and allowing
Bankoi to leave behing proprietary or much more expensive protocols such as
Lonworks to communicate over PLC.
Also being a full device developed entirely in Bankoi will open new lines of business for
their current a future clients that will include
•
•
•
Client product personalization
End to end support
Full installation and configuration
The TILAS project and the work with the rest of the members, specially with Webdyn
has also allow Bankoi to have a more global view of the business and the difficulties
and needs of the IoT implementation in modern cities
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4.4 UPEC
TILAS project is a great project for TILAS with respect to many aspects:
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•
Research: the high level state of the art, theoretic proposals either in routing
protocols or cloud services, multi-disciplinary knowledge through the other
TILAS partners, all allowed the people from UPEC working on the project
(doctors, phd students, researchers) to acquire strong skills in the studied fields,
in addition to the multiple publications in high ranked conferences and journals.
This is very important for academics.
Testbed: the Paris deployment led by UPEC opens a great opportunity for this
university to integrate high level projects and collaborations with future industrial
and academic partners. Regarding the development achieved, the hardware
deployed, the technology used and the application targeted in this testbed,
UPEC will be seen as a great value partner, and can then launch project
proposals citing its contributions in TILAS project. Thus, future theoretical
proposals of UPEC could be evaluated with a real testbed, which is usually
much appreciated by the community. Also, the testbed, being integrated in
another remotely accessible testbed, could be exploited by other people to
validate their proposals on a common hardware and radio technology.
Collaboration: the integration work realised between UPEC and Gemalto in
TILAS project opens a great collaboration opportunity between both partners to
continue working on complete solutions on secure IoT communications,
especially that the evaluation hardware is now available. Another potential
collaboration is to continue working with FIT IoT-LAB people to work on offering
the opportunity for other people to use the Paris demonstrators. Currently, we
are thinking about the best way to highlight this collaboration (may be a web
site) and to display the name of UPEC as a FIT IoT-LAB partner, which will give
UPEC further visibility.
4.5 GTO
The project security results are being disseminated in the OneM2M standardisation
body in a new work item (Dynamic Authorisation) proposed by Gemalto:
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Authorisation management to M2M and IoT devices using delegated
management based on the Oauth protocol.
Dynamic distribution of credentials
The development that were done in TILAS will help Gemalto to enhance its security
and trust service offering in its M2M business line.
Gemalto leverage the TILAS experience by offering IoT application developers a set of
APIs which will shield them from the lower level details and enable them to secure their
applications in a systematic manner.
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4.6 CEA-LETI
CEA-LETI is a research centre whose goal is to help companies to increase their
competitiveness through technological innovation and transfer of its technical knowhow to the industry. Since the past few years the Wireless and Security laboratory of
CEA-LETI has built a strong expertise in Wireless Sensor Networks, focussing on
routing issues, eg energy efficient routing. Another topic that is gaining momentum in
the laboratory is wireless security protocols, eg wireless protocols for secure key
exchanges. In the TILAS project, both topics have been addressed:
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A cross-layer architecture for dense clusterized sensor deployments: this
protocol proposes new efficient schemes for intra and inter cluster
communications, resp. a multi objective context aware criterium for intra cluster
communications, and a scalable power efficient advertisement channel for inter
cluster communications.
A new scheme for securing routing in a constrained wireless network, where
MAC addresses are masked by pseudonyms.
A new bootstrapping protocol for small and remote objects, using implicit
certificates. This latter algorithm is currently under patent process.
A feasibility demonstration that asymmetric cryptographic algorithm based on
elliptic curves can be implemented on off the shelf sensors
As a result, CEA-LETI will have increased its expertise portfolio, and will be able to
answer the demands of its clients with a wider scope of proposals.
4.7 TT ARGELA
Argela is utilizing the Internet of Abstract Things (IoAT) framework of the TILAS
middleware in its “Video Surveillance as a Service (VSaaS)” solution, where
surveillance cameras as well as sensors provide data to surveillance applications
running on cloud. The solution, which provides end-to-end video surveillance
capabilities to both companies and households with minimum investment, is being
developed for Türk Telekom and is branded as BuluTT Göz.
BuluTT Göz architecture is based on "sensorization" of video streams: Images are
interpreted by special plugins (e.g. reading license plate numbers from traffic cameras),
and each interpretation is fed to a universal event processing system. Events can be
abstract sensor readings from IoAT framework, or image interpretations by special
plugins. So that multiple events from different types of sources (sensors, cameras) can
be correlated and interpreted at a higher level.
The steps below describe the typical scenario for the service:
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Customer subscribes to the service online.
According to his needs, the customer can either
o select from a range of available cameras which are offered by Türk
Telekom in monthly payments or
o re-use existing analog/digital cameras with appropriate adapters.
Türk Telekom technicians install the cameras on site and configure them for
use.
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Service is ready for use! Customer can immediately use mobile devices or
PCs to reach the web based interfaces of the service.
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Another use case of Argela’s VSaaS solution is cloud-based traffic safey, which targets
Turkish municipalities. A test system is currently being used in Karaman, which is a
town in south central Turkey, where the following data are collected for the vehicles
passing through the vision of the cameras:
License plates of the vehicles
Models, types and colors of the vehicles
Count of the vehicles
Speed of the vehicles
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4.8 PNG
Exploitation perspective
Pangaea will exploit the TILAS results to the drinking water management by developed
TILAS IoT, cloud and SaaS platform. The SWG (Smart Water Grid) is high-efficiency
next generation water management system in S. Korea. As a specific case, we expand
SWG concept to the building and house to monitor of drinking water. We defined new
terms for this system as Smart Water Micro Grid (SWMG).
SWMG is designed to:
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Distribute wireless nodes and sensor in buildings or houses
Collect water quality sensor data regularly and automatically
Analyse collected sensor data by cloud based analytics tools
Monitor drinking water sensor data and results on the mobile application
TILAS SWMG give better awareness of drinking water to citizens who live in the
building.
Business Goals
Launch new water management systems with Pangaea’s existing water management
solution and expand out market to end users.
Target users
The citizens in the city are main beneficial user for the TILAS SWMG.
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Citizens: The drinking water quality of the building is biggest interest to
citizens. They can see the quality of drinking water using TILAS SWMG
mobile application instantly.
Government organization: Government and municipal organization would like
to give accurate water information to the citizen.
Marketing Strategy
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Marketing objectives: distribute SMWG mobile application that has limited
features by mobile app store. Develop new product line integrating with S.
Korea smart water grids.
Strategic positioning:
 Higher features: Cloud service, visualization, accurate results
 Free of charge service for the citizen
 Integrated with the mojos smart city solution
Business Models
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Sales of Good (B2G, B2B): sell SWMG systems to the government
organization or construction company.
License (B2B): licensing mobile application permission or agreement with
clients
Service model (B2C): distribute mobile application by the App store.
4.9 WEBDYN
Webdyn is a leading independent product development company dedicated exclusively
to the emerging M2M market. In the M2M value chain Webdyn designs, manufactures
and sells data concentrators for the energy market. The main applications of our data
concentrators are smart metering or smart building. The different technical TILAS
topics as security, device management, middleware & cloud services are included in all
major M2M projects in Europe.
Webdyn target is to industrialize, in our off the shelf data concentrators, the different
development initiated in the TILAS project. This add value will give more strength to our
products.
Several field tests were initiated with companies for G3 PLC gateways and data
concentrator:
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PLC G3 backbone for the French army
Smart Metering G3 data concentrators with Iskraemeco (electricity meters
manufacturer) a Slovene company. This demonstrator was presented at the
European Utility Week in November 2015. With this company we are answering
at different calls for tender (Egypt, Austria). The forecast is estimated at 30K
units.
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5 CONCLUSIONS
This report summarized dissemination activities undertaken by the project partners
during the course of the project. A large number of activities took place, the most
significant being standards contributions, publication of 4 journal papers, 9 conference
papers, presentations at various events, and the organization of 1 international
workshops. In addition to that, a large number of complementary activities took place to
strengthen both internal and external dissemination. As a result it is possible to
conclude that the impact of the TILAS Project on scientific and industrial communities
will be strong and long-lasting.
In addition, the consortia believe that the project results, and its extended impact and
visibility, will significantly contribute to the advance of IoT, and in turn represent large
social and economic benefits for the European society.
One important dissemination activity that can be also considered as TILAS output are
all five demonstrators described in D5.3 document. These deployments gather all
incremental knowledge gained through TILAS investigations and they are materialized
on real equipment being placed on European cities. This impact is envisaged to
constitute a way to showcase all TILAS achievements and a way to move forwards and
keep on investigating on further enhancements.
The concrete plans for achieving such impact is also considered on the individual
exploitation plans presented, where partners indicate precise actions and foreseen
opportunities to keep pushing even forward the state of the art and/or placing the
acquired knowledge on the market and on real cities.
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