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Transcript of Use Case Session
Co-funded by theEuropean
Commission
IoT-EPI OverviewIoT Use Cases and Applications
22 June 2016, Common Worksop, Valencia, Spain
Ovidiu Vermesan UNIFY-IoT
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Integration of Devices Creation of Platforms Interoperable APIs Autonomous Reasoning
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Integration of Devices Creation of Platforms Interoperable APIs Autonomous Reasoning
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Integration of Devices Creation of Platforms Interoperable APIs Autonomous Reasoning
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Integration of Devices Creation of Platforms Interoperable APIs Autonomous Reasoning
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Integration of Devices Creation of Platforms Interoperable APIs Autonomous Reasoning
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Integration of Devices Creation of Platforms Interoperable APIs Autonomous Reasoning
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Integration of Devices Creation of Platforms Interoperable APIs Autonomous Reasoning
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Integration of Devices Creation of Platforms Interoperable APIs Autonomous Reasoning
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Smart Retail
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Smart Retail
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Smart Retail
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Smart CampusSmart Stadium
Smart ResidenceSmart Yachting
Ecological Urban Routing AAL Ecological Urban
RoutingAir Quality Monitoring
Smart Retail
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Smart Retail
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Smart Retail
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Smart Retail
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Smart Retail
Co-funded by theEuropean
Commission
IoT-EPI Project Mapping
Service discovery & communication
Service & Application
Marketplace
Service co-creation & interop
communication Discovery & sharing of resources; platform interworkingService Composition
Platform Interoperability
Device & Data Management & IoT apps Gateway
interworking
Co-funded by theEuropean
Commission
IoT-EPI Project Mapping
Environment/Energy Monitoring
Livestock Monitoring
Port/Vessel Monitoring
Smart Retail, Product
Monitoring
Smart Mobility
Smart Healthcare, QuantifiedSelf
Smart City
Co-funded by theEuropean
Commission
Thank You!
Co-funded by theEuropean
Commission
IoT Use Cases and Applications
Moderators:Jelena Mitic, Siemens AG - BIG IoT
Miguel Llop Chabrera, Valenciaport Foundation - INTER-IoT
IoT-EPI Common Workshop, 22 June, 2016Valencia, Spain
Co-funded by theEuropean
Commission
Agenda Time Topic Format Who?
13.30-13.50 Welcome and introductionOverview Presentation on IoT Use Cases and Applications
IntroductionPresentation
Moderators:Jelena MiticMiguel Llop Chabrera
13.50-15.00 IoT use cases presentations prepared by the IoT-EPI projects
Presentation RIA projects
15.00-15.30 Coffee Break Coffee ALL
15.30-17.00 IoT Use Cases and Applications Guided Discussion
Moderators:Sergios Soursos Srdjan Krco
Co-funded by theEuropean
Commission
IoT Use cases and applications
The connection of intelligent machines, fitted with a growing number of electronic sensors, via the Internet, is known as ‘Internet of Things’. With the IoT, any physical and virtual object can become connected to other objects and to the Internet, creating a fabric of interconnectivity between things and between human and things.ITU and IERC define IoT as a dynamic global network infrastructure with self-configuring capabilities based on standard and interoperable communication protocols where physical and virtual “things” have identities, physical attributes and virtual personalities and use intelligent interfaces. They are seamless integrated into the information network.
Co-funded by theEuropean
Commission
Popular IoT applications and use cases in social networks and Internet
Source: www.iot-analytics.com/10-internet-of-things-applications
Smart home• Smart thermostat• Connected lights• Smart fridge• Smart doorlockWearables• Smart watch• Activity tracker• Smart glassSmart city• Smart parking• Smart waste managementSmart grid• Smart meteringIndustrial Internet• Remote asset controlConnected car• Remote car control
Connected healthSmart retailSmart supply chainSmart farming
Co-funded by theEuropean
Commission
• Smart Food /Water Monitoring• Smart Health• Smart Living• Smart Environment Monitoring• Smart Manufacturing• Smart Energy• Smart Buildings• Smart Transport and Mobility• Smart Industry• Smart City
Co-funded by theEuropean
Commission
Smart Cities
Smart Environment
Smart water
Smart metering
Security and emergencies
Retail
Logistics
Industrial control
Smart agricultura
Smart animal farming
Domotic and home
automation
eHealth
Possible applications for IoT sensors
Source: www.libelium.com/top_50_iot_sensor_applications_ranking
Co-funded by theEuropean
Commission
Smart City
Co-funded by theEuropean
Commission
Smart Mobility
Co-funded by theEuropean
Commission
Smart Energy
Co-funded by theEuropean
Commission
Smart Building
Co-funded by theEuropean
Commission
Smart Health
Co-funded by theEuropean
Commission
IoT interoperabilityInteroperability is the property referring to the ability of systems and organizations to work together. The conceptual realization of IoT is still far form achieving a full deployment of converged IoT services and technology. The widespread of vertically-oriented closed systems, architectures and application areas has generated a fragmentation that needs to be overcomed. Lack of interoperability causes major technological and business issues that slows IoT technology adoption.The overall challenge of achieving interoperability of heterogeneous IoT platforms is to deliver an IoT extended into a web of platforms for connected devices and objects to support scenarios where everything is linked.
Co-funded by theEuropean
Commission
Example: Interoperability among heterogeneous platforms in logistics hubs
Co-funded by theEuropean
Commission
Thank You!
Co-funded by theEuropean
Commission
IoT Use Cases and ApplicationsPart 2
Sergios Soursos, Intracom SA Telecom, Greece – symbIoTeSrdjan Krco, DUNAVNET, Serbia – TagItSmart
IoT-EPI Common Workshop, 22-23 June, 2016Valencia, Spain
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Smart Retail
Co-funded by theEuropean
Commission
Discussion items• Synergies between different use cases from the 7 RIAs?
• considering business models, requirements, specifications
• Prioritization of use cases?• IoT Value roadmap
• Support RIAs to create business value out of use cases
Note: Use Cases vs. Pilots vs. Applications
Co-funded by theEuropean
Commission
Next steps and Common Action Plans
• 7 RIAs will produce soon (?) a first version of UC deliverables• Common description language of UCs?
• standardized approach?
• Use existing platforms?• Plans for common pilots?
• which use cases?• which projects?• which locations?• common end-user communities?
Co-funded by theEuropean
Commission
Notes (I)• Semantic interoperability• Synergies
• Inter-IoT: AGILE gateways, ports, beaconsbIoTope: logistics, vehicle-to-intrastructure and vice-versa BIG-IoT: discoveryTagItSmart: products in containers on trucksVICINITY: trust and privacy (security for trucks, cranes, …)
• AGILE: discussions w/ VICINITY & bIoTope on use of gatewayssocial aspects, data sharing
• What’s the scope and lifetime of the UC work group?• Shared document with (homogeneous) UC descriptions from RIAs• IoT LSPs will join IoT-EPI? How we can benefit/cooperate with them?• Experience from Smart Cities call on common UCs to be used here?
Co-funded by theEuropean
Commission
Notes (II)• Cooperate on development environment, methodologies, tools, etc…
• Models of UCs to be used for evaluation of SW• Synergies wrt demonstrators• We will evaluated with respect to the contributions in IoT-EPI• Common IoT techs used in different RIAs could facilitate collaboration on UCs • Important for communication/dissemination
• Open Calls• Will this common document be useful for them?
• UCs as entry point in IoT-EPI• What are the new services we offer through UCs?
• Need to highlight the interoperability aspects of UCs
Co-funded by theEuropean
Commission
Notes (III)• Identification of barriers
• Interoperability with established players?
• Human –centric features of UCs• Open source aspects• 1-2 UCs to be tried out across different implementations?• Be-IoT could work on provided material for the mapping of different Ucs• Common tools for UC description?
• CityPulse FP7 project with 101 smart city use cases
• Narrow down UC categories, then use common description• Common document could advance to become a book chapter?
• Cluster book
Co-funded by theEuropean
Commission
Thank You!
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Smart Retail
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Smart CampusSmart Stadium
Smart ResidenceSmart Yachting
Ecological Urban Routing AAL Ecological Urban
RoutingAir Quality Monitoring
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Co-funded by theEuropean
Commission
IoT Use Cases Project Mapping
Port Logistics Scanning of FunCodes (Shopping) Localisation in Indoor Spaces Electric Cars Smart Home Automation and Control Traffic m-Health Pharmaceutical Packaging Smart Home Smart Building (HVAC) Smart Energy Energy Efficiency Air Quality Edu Campus Air Quality Smart Parking Space Monitoring Smart Cities Smart Stadium Self-tracking sensors Environmental Monitoring Smart Transport Air Quality
Smart Logistics
Smart Mobility
Smart Health
Smart Buildings
Smart Cities
Smart Energy
Smart Environments
Co-funded by theEuropean
Commission
BIG IoT Use Cases and Applications
Jelena Mitic, Siemens AGIoT EPI Meeting Valencia
Co-funded by theEuropean
Commission
BIG IoT Approach
Jelena Mitic - Siemens AG
Co-funded by theEuropean
Commission
Pilot Region Barcelona
Jelena Mitic - Siemens AG
Co-funded by theEuropean
Commission
Pilot Region Northern Germany
Jelena Mitic - Siemens AG
Co-funded by theEuropean
Commission
Pilot Region Piedmont
Jelena Mitic - Siemens AG
Co-funded by theEuropean
Commission
Use Case Clusters
Use Case Cluster Northern Germany
Barcelona Piedmont
Smart Parking
Smart Traffic Management
Public Transport Optimization
Healthy Bike Navigation
Bike Sharing
Incentive-based Green Route Planning
Multi-modal Route Optimizer
Smart Charging
Jelena Mitic - Siemens AG
Co-funded by theEuropean
Commission
Smart Parking• Navigation to parking spots
based on availability and distance, taking into account the current traffic conditions and parking prices
• Availability of parking spots by using different types of sensors in all 3 pilots
• IoT platforms:• VMZ TIC platform• Bosch Smart City Platform• CSI Smart Data Platform• Worldsensing Smart Traffic Platform Jelena Mitic - Siemens AG
Co-funded by theEuropean
Commission
Smart Traffic Management• Traffic situation and pollution,
based on real time data obtained by different devices (e.g. air quality sensors of smart cars, road-side magnetometers, cameras, WIFI/BT detectors, etc)
• IoT Platforms:• OpenIoT• VMZ TIC Platform• Bosch Smart City Platform• Bosch BEZIRK Platform• Worldsensing Smart Traffic
Platform• Wubby Platform
Jelena Mitic - Siemens AG
Co-funded by theEuropean
Commission
Public Transport Optimization
• Optimization of the usage of public transportation, both in terms of selection and guidance, as well as the the assignment of resources in public transport system
• Wolfsburg public transportation• IoT Platforms:
• Bosch BEZIRK Platform• Bosch Smart City Platform
Jelena Mitic - Siemens AG
Co-funded by theEuropean
Commission
Healthy Bike Navigation & Bike Sharing
• Healthier alternative routes for bikers
• The real-time data coming from low cost air quality stations and traffic conditions as observed by traffic counting sensors
• Two small cities: Varcelli and Biella
• IoT Platforms:• CSI Smart Data Platform• Vodafone IoT Platform• Wubby Platform Jelena Mitic - Siemens AG
Co-funded by theEuropean
Commission
Incentive-based Green Route Planning
• Routing based on environmental conditions (pollution, noise)
• Incentives for the users• IoT Platforms:
• OpenIoT• Bosch BEZIRK Platform• Worldsensing Smart Traffic
Platform• CSI Smart Data Platform• Wubby Platform Jelena Mitic - Siemens AG
Co-funded by theEuropean
Commission
Multi-modal Route Optimizer
• For long distance commuters between Wolfsburg and Berlin• Connection of different data sources for seamless mobility towards a
chosen destination, offering multimodal options and alternative routes in case of disruptions along the preferred route
• Real time data on public and individual transport and availability of e-charging stations on the corridor between larger cities
• IoT Platforms: • Bosch Smart City Platform • VMZ TIC Platform
Jelena Mitic - Siemens AG
Co-funded by theEuropean
Commission
Smart Charging• Routing to the available charging stations• Reservation of charging stations• Supervision of charging stations for enforcement • Charging stations in Berlin, Wolfsburg and in the corridor• IoT Platforms:
• Bosch Smart City Platform, • VMZ TIC Platform
Jelena Mitic - Siemens AG
Thank you for your attention!Questions?
On the Web: http://big-iot.euOn Twitter: @BIG_IoT
Jelena Mitic [email protected]
Co-funded by theEuropean
Commission
Use Cases & ApplicationsILIAS MAGLOGIANNISBIOASSIST S.A., GREECE
IoT-EPI Common Workshop, 22-23 June, 2016Valencia, Spain
Co-funded by theEuropean
Commission
AGILE Consortium – 17 Partners
35%
24%
29%
12% SMEs/Startups
Industry/Large En-terprize
Research
NGO/Community
Co-funded by theEuropean
Commission
AGILE ECOSYSTEMDEVELOPERS/
MAKERSINDUSTRYM2M/IOT
Early Community involvement, Eclipse
project proposal,IoT apps ecosystem,
Maker’s Gateway version
Open calls for Startups + SMEs for use cases &
user adoption,Promotion to
Accelerator programs
Self-tracking Pilot, Crowdfunding campaign
IoT Testbed, IoT apps ecosystem,
3rd party apps (open calls)
Industrial GW -Air Monitoring Pilot,
Smart Retail PilotGW on a UAV – Open
space monitoring
BioAssist
Canonical Ubuntu
STARTUP / ENTREPRENEURS
END USERS
AGILE GATEWAY
Co-funded by theEuropean
Commission
AGILE Gateway – 2 versions
Carrier Module
CPU ModuleStandard COM Express
Rev.2.1
Board Management
Module(BMM)
IntegratedPower supply
N x miniPCIeslots
expansion
GPS module (?)
I/O Expansion Module (CANBus,
I/O expander)
Optional PoE
custom internal
expansion
User I/O
Alternate Power supply
eMMCFlash
SATA DRIVE(Drive bay?)
IntegratedMicroSDCard Slot
Maintenance I/O
Dumb I/O Panel (e.g. for user I/O)
Integrated module
Internal expansion
External expansion
Makers’ Version(based on Raspberry Pi)
Industrial Version
• The modular gateway will be delivered into 2 versions: a) the makers-friendly version for easily and fast prototyping IoT solution and b) the industrial version aimed for M2M and industrial use cases
• An expansion module (shield) will be designed for being plugged on top of the RasbperryPi that will allow to easily plug modules, so as existing RaspberryPi can become AGILE gateway
• In the industrial AGILE gateway every main architectural element is a module that is designed following a commons set of rules that ensures interoperability and expandability. In this vision also the power supply and the enclosure are considered as modules and the device is tailored to specific needs
Co-funded by theEuropean
Commission
Pilot AQuantifiedSelf
• Home / Daily use by non-experts• Auto-configuration support
• Data Security and Privacy• AGILE Security Framework with policy
configuration and enforcement
• Data Sharing• A data sharing framework based on
WebIDs• Import data from 3rd parties
• Data Analysis in the gateway• Identification of trends• Update user’s activity profile
Co-funded by theEuropean
Commission
Pilot BOpen Field & Cattle Monitoring
• AGILE Gateway on UAVs for monitoring open/remote areas and livestock
• Payload and power consumption restrictions
• Integration with the UAV control systems• Online/Offline modes
• 4G connection where available or• Οff-line data storage and processing
Co-funded by theEuropean
Commission
Pilot C Air quality and pollution monitoring
• A pervasive network of AGILE Gateways as monitoring stations
• Use of the industrial version• reduce the cost • reduce the time to market • create business opportunities
• Modular HW Design• Sensing Modules• Networking Modules• Auto-configuration of modules and SW
Co-funded by theEuropean
Commission
Pilot DEnhanced Retail Services
• Transform the future consumer behavior and provide retailers with new opportunities
• Proximity and Location Based Services
• Customized Promotions according to user profiles
• The AGILE Gateway • Coordinates a network of iBeacons• Pushes notifications to the users’
smartphone apps• Improved shopping experience
Co-funded by theEuropean
Commission
Pilot EPort Area Monitoring for Public Safety• Crisis management using the AGILE Gateway on
UAVs• A trigger will be sent to a drone to fly out to the
coordinates of an incident and will be transmitted in real time
• The data will be collected by Sky-Watch drones carrying the AGILE gateway
• Allow the control room to have control over the drone• Data transfer over 4G cellular networks• Streaming data:
• Data from various sensors• Video Streaming
Co-funded by theEuropean
Commission
Testbed Overview: IoT-LAB To be used as pre-pilot in order to decrease debugging phase of the AGILEpilots HW and SW Infrastructure already in place for remote access to 2700+ IoT-devices Online tools for IoT node firmware upload, experiment configuration, experiment results download.
Co-funded by theEuropean
Commission
IoT-LAB @Inria-Saclay
Co-funded by theEuropean
Commission
Summarizing• Modularity and expendability of the AGILE GATEWAY• Auto configuration (plug and play) even for non-expert users• Data analysis on the GATEWAY • Off-line and On-line data exchange with various network interfaces (3G/4G, WiFi,
BLE etc)• Integration with 3rd systems (i.e UAVs control systems)• Handle Data Provenance and Security issues• Create Business Opportunities (i.e reduce HW and SW development costs for
developers and makers)
Co-funded by theEuropean
Commission
TF 02: Platforms InteroperabilityOvidiu Vermesan, UNIFY-IoT, SINTEF, Norway
Steffen Lohmann, Be-IoT, Fraunhofer IAIS, Germany
IoT-EPI Common Workshop, 22-23 June, 2016Valencia, Spain
Co-funded by theEuropean
Commission
TF02: Motivation• IoT ecosystems require interoperability to create seamless integrations
• on different levels: technical, network, syntactic, semantic, enterprise
• IoT landscape is fragmented and lacks interoperability, in terms of:• proliferation of solutions from different OEMs• operating systems and programing languages • versions or times of deployment • types of connectors and connectivity frameworks • communication protocol standards
Co-funded by theEuropean
Commission
Examples of Protocol Layer Stacks
Network/Transport Layer
Physical/Link Layer (MAC/PHY)
CoAPDDS
XTypes, SecurityAPI, QoS, RTPS
MQTTXMPP
IEEE
1888
REST/HTTPSSIP /
SIMPLE
IEC 61968 CIMANSI C12.19/C12.22
DLMS COSEM
IEC 6185
0
IEC 6087
0
MODBUS
DNP
IEEE P1901.2 PHY
IEEE P1901.2 MAC
IEEE 802.11Wi-Fi
IEEE 802.3
Ethernet
IEEE 802.16 WiMax
2G/3G/LTE Mobile
IEEE 802.15.4g (FSK, DSSS, OFDM)
IEEE 802.15.4 MAC (including FHSS)
802.15.4e MAC Enhancements
802.15.4e TSCH
Bluetooth Low
EnergyBACNET DECT NFC
6LoWPAN (RFC 6282) RFC 2464 RFC 5121 RFC 5072
802.1x / EAP-TLS based Access Control
IPv6 / IPv4
TCP / UDP
6Lo6top/6LoWPAN
Application Layer
VLC WPAN
IEEE802.15.7
VLC
Co-funded by theEuropean
Commission
TF02: Objectives• Presentation and discussion of interoperability issues
• Knowledge exchange on existing standards and technologies
• Analysis of the state-of-the art and identification of gaps
• Discussion of challenges (security, scalability, performance, etc.)
• Collaboration between the projects to increase interoperability
Co-funded by theEuropean
Commission
TF02: Retrospective (Meetings)• April 20: Kick-off• May 4: Online
• Sebastian Kaebisch (BIG IoT): W3C Web of Things and BIG IoT
• Raúl García-Castro (VICINITY): IoT-related ontology standardization initiatives (W3C, ETSI, oneM2M)
• May 16: Online• Arkady Zaslavsky (bIoTope): IoT interoperability in NIST, ISO and IEEE SA developments
• Ovidiu Vermesan (UNIFY-IoT): Report on EU-NIST meeting and international cooperations
• June 15: Online• Kary Främing (bIoTope): …
• …
• June 23: F2F Meeting
Co-funded by theEuropean
Commission
TF02: Workshop Agenda
Thursday 23 June 201608:45-09:00 Welcome
09:00-10:30
Welcome and agenda Introduction of participants Presentation of TF objectives, activities, milestones, outcome Interoperability and IoT architectures (including SoA approaches) NIST IoT/CPS developments ISO, IIC and Web of Things feedback, Open Group White Paper SAREF ontology, W3C, ETSI ISO, ITU and IEEE AIOTI approach Project requirements and gap analysis
10:30-11:00 Coffee Break
11:00-12:30
IoT Platforms Interoperability approaches prepared by the EPI-projects(7 Presentations)
Synergies common approaches Panel discussion Identify the challenges and the elements
beyond SoA – IoT platforms that are communicable, operable, and programmable across devices, communication infrastructure, applications, etc. regardless of make, model, manufacturer, or industry.
Outcome and action plan
12:30-13:30 Lunch
Co-funded by theEuropean
Commission
Use Cases in TagItSmartKaisa Vehmas, TagItSmart, VTT Technological Research Centre of Finland,
Finland
IoT-EPI Common Workshop, 22-23 June, 2016Valencia, Spain
Co-funded by theEuropean
Commission
www.tagitsmart.eu
Use cases• The use cases were created by
combining expertise of consortium partners
• The use cases will be demonstrated and evaluated at ecosystem trials either at laboratory-scale, at controlled environment
84
Co-funded by theEuropean
Commission
Use case 1
Digital Product
85
Co-funded by theEuropean
Commission
Use case 2
Lifecycle Management
• The idea of this use case is to implement a system/technology that allows a lifecycle management of every fast-moving consumer good (FMCG), or consumer packaged good (CPG), that motivates and helps companies and citizens recycle their waste items, overcoming and solving current limitations and problems
• Every FMCG will be marked with a SmartTAG during its production and will be associated with the TagItSmart platform to obtain all its functionalities; e.g. consumer engagement, product condition monitor, item-level tracking, recycling, life-cycle management
86
Co-funded by theEuropean
Commission
Use case 3
Brand Protection
87
On an Aspirinbox a TagItSmart! „Proof me if you can!“ QR codeis embedded to the package. By reading the QR code using a common QR code reading software you get information on the product and a link to either downloading a secondary software / plugin or cloud access for the advanced readout: the “Proof me if you can!” originality proof. In the above QR code you just read “0”.
1st ReadoutProof me if you can!
“0”
• Goal: development of a whole security platform for goods
• “Proof me if you can” QR code is embedded to the package
• By reading the QR code you get information about the product and a link to cloud access for the advanced readout: “Proof me if you can“ originality proof
Co-funded by theEuropean
Commission
Use case 3
Brand Protection
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• After having a cloud access, you get instructions how to read the QR code again
• It communicates to your handheld device that the LED light has to be switched on during this read
• While reading the functional QR code again, certain textures with the QR code appear and disapper – new information is released!
After having downloaded the app / plugin / cloud access, you get instructions how to read the QR code again. It communicates to your handheld device that the LED lighthas to be switched on during this read. While reading the functional QR code againand having the LED on illuminating it following a defined procedure, certain textureswithin the QR code appearand dissapear– new information is released! The new information in the above scenario is “01”.
2nd Readout
Proof me if you can!
“0” “01”
“Proof me if you can!” readout with LED ON
LEDON
Co-funded by theEuropean
Commission
Use case 3
Brand Protection
89
• The new information received from the 2nd reading interconnects to manufacturer data that furthermore decides if the data are approved and match to existing products
The new informationreceived from the 2nd readinginterconnects to manufacturerdata (such as date, place of production, batch number…) that furthermore decides if the data are approved and match to existing products.If thereisa „match“in data, the„Proof meif youcan!“app/ plugin / cloudaccessrevealsoriginalityof theproduct – it iswhat it is.
Originality Proof!
Proof me if you can!
“01”
Yes, I am an originalASPIRIN®!
Get well soon!
Co-funded by theEuropean
Commission
Use case 4
Condition dependent
pricing
• Following the conditions of the product by different stakeholders
• Each package of meat is tagged with a temperature sensitive Smart Tag on the production line
• Once the temperature goes above the threshold, the tag reacts and changes its content to indicate this event
• Different information to the stakeholders in the value chain
• E.g. retailer; transport conditions, dynamic pricing
• E.g. Consumer; the origin, time of packaging, discount information and transport conditions and also at home
90
Co-funded by theEuropean
Commission
Use case 5
Home services
• This use case will test different services to the customer all along the life of the equipment at home
Þ comfort and a healthy living at home. • This implies proper 1) maintenance, 2)
repair, 3) replenishment, and 4) monitoring
• Some of the services will leverage access to information related to the product, its environment and its use; and some will provide specialized services (installation, maintenance, repair, etc.)
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Co-funded by theEuropean
Commission
Thank You!
Co-funded by theEuropean
Commission
symbIoTeIoT Use Cases and Applications
Sergios Soursos, symbIoTe, Intracom S.A. Telecom Solutions, Greece
IoT-EPI Common Workshop, 22-23 June, 2016Valencia, Spain
Co-funded by theEuropean
Commission
Presentation Outline
• Objectives• Use Cases in symbIoTe• Outcome
Co-funded by theEuropean
Commission
Objectives• Local cloud and dynamic service
composition (symbIoTe middleware)
• Manage and access functions across any available devices
• Data integration, consolidation and analysis
Co-funded by theEuropean
Commission
Use Cases in symbIoTe1. Smart ResidenceIt will access and manage functions across available devices, from smartphones to automation devices, media players, and personal health to environmental sensors, devices belonging to different subsystems.
2. EduCampusIt will integrate information containing structural data, live sensor data and social collaboration scenarios, to establish an open ecosystem for campus services across various IoT platforms.
3. Smart StadiumIt will enable the “beacon cloud”, an indoor geo-location service aiming at a centralized and effective beacon management by infrastructure providers and create innovative applications.
4. Smart Mobility and Ecological RoutingIt will bring existing city-wide air quality measurement infrastructures with wearable sensors aiming to create ecologically preferable routes for users.
5. Smart YachtingIt will automate the information processes between a boat and the mainland and allow users to identify various land information.
Co-funded by theEuropean
Commission
Use Cases in symbIoTe1. Smart Residence (Ambient Assistant Living – Smart Health)It will access and manage functions across available devices, from smartphones to automation devices, media players, and personal health to environmental sensors, devices belonging to different subsystems.
• Vital signs of a resident are measured and are automatically transmitted to his/hers medical record (e.g., blood pressure)
• Medication reminders are provided based on medication schedule (dosage, time, and where to find the medication)
• Detecting critical situations / calling for help (e.g., resident falls down)
• Measuring gait based on movement
Co-funded by theEuropean
Commission
Use Cases in symbIoTe1. Smart Residence (Energy Saving Scenario)It will access and manage functions across available devices, from smartphones to automation devices, media players, and personal health to environmental sensors, devices belonging to different subsystems.
• The system detects the presence of a person and determines comfort values for the user:
• Lux level and temperature depending on activity • Ambient mood - e.g., aromas, light colours
• The physical systems in the room are activated:• Lights and curtains, fan coils and radiators, motorized windows and fans• Lux and temperature sensors to monitor the environment
Co-funded by theEuropean
Commission
2. EduCampusIt will integrate information containing structural data, live sensor data and social collaboration scenarios, to establish an open ecosystem for campus services across various IoT platforms.
Use Cases in symbIoTe
• Connects services from two campus management systems with different IoT deployments and different semantic understand
• Campus A: Room Information Service• Campus B: Room Reservation Service
• Campus User are not forced to change equipment or application when visiting affiliated campus
• Semantic mapping from information- to reservation-service• Geo-location in remote facilities (BLE tags managed in different
IoT-middleware solutions)
Co-funded by theEuropean
Commission
3. Smart StadiumIt will enable the “beacon cloud”, an indoor geo-location service aiming at a centralized and effective beacon management by infrastructure providers and create innovative applications.
Use Cases in symbIoTe
• Visitor oriented: the stadium application for enhanced experience
• Provide, discover and use location-based (added value) services based on the specific location of the visitor (parking booking, quick stadium access, social networking and broadband services, kindergarten)
• Staff oriented: The stadium application for management• Provide management capabilities for parking, stadium staff, security
personnel, assistants, and tools for analysis of performance
Co-funded by theEuropean
Commission
4. Smart Mobility and Ecological RoutingIt will bring existing city-wide air quality measurement infrastructures with wearable sensors aiming to create ecologically preferable routes for users.
Use Cases in symbIoTe
• Air quality measurements are collected by several IoT platforms (and different types of sensors, some wearables)
• Roads and paths are automatically classified with air quality measurements
• Routing uses air quality as travel cost, returning best route for walkers, joggers and cyclists
• Correlation of environmental data with parking and traffic information
Co-funded by theEuropean
Commission
5. Smart YachtingIt will automate the information processes between a boat and the mainland and allow users to identify various land information.
Use Cases in symbIoTe
• Smart Mooring Services:• Implement open mechanisms for communicating territory information
from the mainland to the boat in the mooring phase• present and maintain enriched and context based information on
multiple visual devices available on board as part of a Smart Residence product (TV screens, smartphones)
• Automated Supply Chain:• Development of automatic mechanisms for identifying faults and
maintenance conditions on board• Implement open mechanisms for communicating requests for upkeep,
supply and refit to the port business process platform, in order to activate the supply value-chain on the territory
Co-funded by theEuropean
Commission
Outcome – Scope of use casesUse Case Focus
Smart Residence Interoperability of collocated deployments within smartspaces
EduCampus IoT platform federation within the cloud domain
Smart Stadium Interoperability of cooperative platforms at theapplication domain
Smart Mobility and Ecological Routing Interoperability of cooperative platforms at theapplication domain; potential for resourcebartering/trading
Smart Yachting Interoperability of cooperative platforms at theapplication domain with time- and safety-criticalrequirements
Co-funded by theEuropean
Commission
Outcome – Planned PilotsUse Case Platforms Involved Evaluation Planned
Smart Residence SymphonyuniversAALTarquinIoTnAssist
- Energy consumption, home comfort, etc. (20 users/Italy)- Health, medicine, etc. (tbd users/Austria)
EduCampus OpenIoT 20 users (Germany) – first evaluationScaled-up evaluation to follow-up
Smart Stadium Beacon management 25 users per city (minimum)Candidate cities – Barcelona, Zagreb, Oslo
Smart Mobility and Ecological Routing OpenIoTCitibrain Mobility BaaSopenUWEDAT
- Ecological urban routing application + air quality (50 users/Austria, 40 users/Croatia)- Ecological urban routing application + parking and traffic sensors (50 users/ Portugal)
Smart Yachting Navigo DigitaleSymphony
5 marine operators 10 port business operators10 captains (Italy)
Co-funded by theEuropean
Commission
Thank You!
Co-funded by theEuropean
Commission
Back-up Slides
Co-funded by theEuropean
Commission
Outcome
• Defined application level use cases in different domains• Smart Residence, (Smart) EduCampus, Smart Stadium, Smart Mobility and
Ecological Routing, Smart Yachting
• Serve as the basis for the system requirements and architecture
Co-funded by theEuropean
Commission
• Demonstrate interoperability across different “Smart Home” IoT solutions, i.e., devices in the same domain
• Generalized abstract model for interconnected objects
• Dynamic configuration of available services
• Provide a natural and homogeneous users’ experience
• Detect user’s presence to appropriate context setting and expect the Residence behavior to change accordingly
1. Smart ResidenceIt will access and manage functions across available devices, from smartphones to automation devices, media players, and personal health to environmental sensors, devices belonging to different subsystems.
Co-funded by theEuropean
Commission
2. EduCampusIt will integrate information containing structural data, live sensor data and social collaboration scenarios, to establish an open ecosystem for campus services across various IoT platforms.
• Research and higher education depends on strong and international networks of universities
• Universities are encouraging their students to participate in exchange programs to gain experience in different cultural and educational backgrounds
• A major asset in the global competition for students, teachers and researchers is the university campus• It shall be full of attractive services, and
• It shall be welcoming for guests• The challenge for this UC is to provide a framework which supports the
interconnection of campus systems from different universities, in order to make facility services interoperable
Co-funded by theEuropean
Commission
2. EduCampusIt will integrate information containing structural data, live sensor data and social collaboration scenarios, to establish an open ecosystem for campus services across various IoT platforms.
• EduCampus is based on SmartCampus installations maintained by KIT and UPMC• EduCampus provides interoperability features as demonstrators within the time
frame of symbIoTe• Beyond the symbIoTe time frame operation is planned to be supported by the
cooperation partners within KIT and UPMC• strategic partnership with KIT for SmartCampus• Incubator project with UPMC for SmartBuilding
Co-funded by theEuropean
Commission
3. Smart StadiumIt will enable the “beacon cloud”, an indoor geo-location service aiming at a centralized and effective beacon management by infrastructure providers and create innovative applications.
• Use Case overview - Challenges• Business challenges
• Need to complement revenues with extra services• Need for a better knowledge of visitors profile• Need to be in full control of everything happening in the stadium• Integrated information on infrastructure and services performance
• Technological challenges• Connectivity (3G, 4G, WIFI, high density of people)• “Push” and “Pull” geo-location technologies• Multi-tenancy
Co-funded by theEuropean
Commission
3. Smart StadiumIt will enable the “beacon cloud”, an indoor geo-location service aiming at a centralized and effective beacon management by infrastructure providers and create innovative applications.
• Use Case overview – Planned innovations• Communications in high-density areas: from broadband communications for
stadium visitors to secure and reliable internal communications for stadium staff• Advanced geo-location services, integrating from location for mobile visitors, to
personnel staff, to trackable devices• Added value services which take advantage from sensor networks (e.g., parking
spaces), indoor geo-location technologies, communications and notifications
Co-funded by theEuropean
Commission
• Background:• Insufficient public transport capacity and pollution in many major European cities.
• Increased commuting on foot and by bicycle bear the potential of relieving both the urban macro-pollution and the exposure of the commuters themselves to pollutant gases.
• Problem:
• Which routes should the commuters take in order to both avoid traffic jams and to minimize their exposure to pollutants?
4. Smart Mobility and Ecological RoutingIt will bring existing city-wide air quality measurement infrastructures with wearable sensors aiming to create ecologically preferable routes for users.
Co-funded by theEuropean
Commission
• Proposed Solution:• In situ pollution measurements by the commuters and via fixed installations of
environmental monitoring stations.
• Development of urban routing algorithms, which as link weights take into account not only the road network graph characteristics themselves, but also simultaneously reflect both the congestion and air pollution levels on the individual road network sections.
• Crowd-sensed air quality monitoring via wearable sensors and mobile devices Smart Routing Algorithms Optimal route for cyclists, pedestrians or even drivers.
4. Smart Mobility and Ecological RoutingIt will bring existing city-wide air quality measurement infrastructures with wearable sensors aiming to create ecologically preferable routes for users.
Co-funded by theEuropean
Commission
• 1_MooringPlaceBooking: the yachtsman contact the port to book the mooring place for his vessel in the desired period. The vessel's identification data are submitted, and the requirements and authorization for the exchange of data needed by the automatic docking procedure are also agreed.
• 2.1_NotifyPortEntrance: If the vessel is not equipped with a positioning and identification system, the yachtsman must communicate to the port, online or offline, his port entrance. The vessel is identified and the arrival notification, along with the vessel identification data, are recorded
• 2.2_ShipPortEntranceDetection: The Ship Detection System detects the vessel at the port entrance, the vessel is identified and the ship identification code provided is recorded on Navigo Digitale.
• 3_ActivateMooringSupport: The mooring support team is alerted in order to help the yachtsman to complete the mooring phase successfully and without problems. The vessel's identification data are also provided.
• 4_StartNavigoConnection: It is checked if the vessel corresponding to the code detected by the Ship Detection System, or otherwise notified, is already connected to the Internet and if Navigo Digitale is also connected to the vessel's board system.
.
5. Smart YachtingIt will automate the information processes between a boat and the mainland and allow users to identify various land information.
Co-funded by theEuropean
Commission
• 5_StartMooringPractice: Navigo Digitale acquires automatically all the needed documents and information from the vessel on board system Symphony and activates the workflow to process the administrative mooring practice.
• 6_ProcessMooringPractice: The workflow needed to process the administrative mooring practice is executed.
• 7_ActivatePortOperator: It is issued an alert to a port operator along with the relevant instructions and information.
• 8_ShipMooringDetection: The Ship Detection System detects the vessel at the mooring place
• 9_ActivateMooringServices: Navigo Digitale acquires automatically, from the vessel on board system Symphony, information regarding the vessel requirements for the activation of the mooring services
.
5. Smart YachtingIt will automate the information processes between a boat and the mainland and allow users to identify various land information.