The document discusses the Industrial Internet Consortium (IIC), an open membership organization with 214 member companies from 26 countries. The IIC aims to accelerate growth of the Industrial Internet by coordinating initiatives for connecting objects, people and processes using open standards. Key areas of focus for the IIC include its Technology Working Group, Security Working Group, and testbeds for driving innovation. Two testbeds highlighted are the International Future Industrial Internet for connecting industries via mobile networks, and a Communication and Control for Microgrid Applications testbed.
6. The Industrial Internet
November 20, 2015 6
Industrial Internet:
An internet of things, machines, computers
and people…
enabling intelligent industrial operations…
using advanced data analytics for
transformational business outcomes.
7. There are key differences between the Industrial Internet
and Consumer IoT
November 20, 2015 7
8. Barriers to Progress:
Adoption is Hampered in a Disconnected Environment
8November 20, 2015
Connectivity
Standards
Technology
Research Academia
Systems
Integration
Security
Government
Big Data Industries
The Industrial Internet:
A $32 trillion opportunity
9. The IIC: Things are coming together
November 20, 2015 9
Things are coming together. TM
Standards
Research Academia Systems Integration
Security
Government
Big Data IndustriesConnectivity
Technology
10. Industrial Internet Consortium
Mission
To accelerate growth of the Industrial Internet by coordinating ecosystem
initiatives to connect and integrate objects with people, processes and data
using common architectures, interoperability and open standards that lead
to transformational business outcomes.
Launched in March 2014 by five founding members:
10
The IIC is an open, neutral “sandbox” where industry, academia and
government meet to collaborate, innovate and enable.
214 Member Organizations
Spanning 26 Countries
11. The IIC is not a standards organization.
It evaluates and organizes existing standards to:
• Advocate for open standard technologies
• Influence the global standards development
The Technology Working Group is currently:
• Evaluating existing standards
• Identifying requirements for the Industrial
Internet
The IIC and Standards Organizations
November 20, 2015 11
IIC Formal Liaisons
12. The IIC has three primary areas of activity:
Community Engagement, Technology & Security, and Testbeds
12November 20, 2015
13. What is the Biggest Challenge Facing the Industrial Internet?
6%
3%
14%
77%
0 10 20 30 40 50 60 70 80 90
Other
Connectivity Issues
Security
Interoperability
Source: IoT Nexus 13
Business Models,
Public Awareness,
Energy Consumption
November 20, 2015
}
IIC Technology Working Group
IIC Security Working Group
IIC Testbeds Working Group
IIC Marketing and Technology Working Groups
14. Focus on Testbeds to drive innovation that benefits cities
November 20, 2015 14
15. IIC Testbed: International Future Industrial Internet (INFINITE)
Collaborators
• IIC Members: EMC Corporation and Cork Institute of Technology
• Other Participants: Vodafone, Irish Government Networks, Asavie, and Cork Internet Exchange
Market Segment
• Multiple industries and sectors
Goal
• Provide a state-of-the-art cloud and analytics platform for IoT services which will provide the technologies,
processes and best practices that will enable reliable, trusted solutions for hyper-connected industries
Features and Commercial Benefits
• Ideal for mission-critical systems
• Completely virtual domains that are able to be connected via mobile networks
• A solution that allows multiple virtual domains to securely run via physical network
November 20, 2015 15
16. IIC Testbed: International Future Industrial Internet (INFINITE)
Control/Management Plane
D A T A C E N T R E
Private VRFs or
VLANs
GGSN M2M Partition
Local Core
Data
Analytics
Ingest VMs Analytic VMsRTIHTTP
metadata
GGSN
Presentation &
User Interfaces
Managed
Services
Framework
MOBILE
NETWORKS
First Use Case: Bluelight
Bluelight will allow ambulances to securely connect to a hospital's system
and relay information while in route, so hospital staff are prepared to take
over the care of the patient once the ambulance arrives.
17. IIC Testbed: Communication and Control for Microgrid Applications
17
Neighborhood Microgrid
Solar
Field Network
Wind
Local load
control
Collaborators
• IIC Members: Real-Time Innovations (RTI), National Instruments,
Cisco
• External: CPS Energy (San Antonio), Southern California Edison,
Duke Energy / SGIP
Market Segment
• Smart grid, especially integrating solar, wind, storage, and EVs
Goal
• Prove the viability of a real-time, secure databus and distributed
control architecture in a real-world power system
Features & Commercial Benefits
• Enable efficient integration of solar, wind, & EVs into the grid
• Create a dynamic, open marketplace for smart grid vendors
• Break the standards blockage holding back the industry
18. SmartGrid Application Use Cases
18
Grid Optimization
•Reduce control requirement from
operators
•Increase asset utilization
Island
•Function as independent grid
Storm Resiliency
•Maximize storage
•Limit non-critical loads
•Auto-island with outage
Re-Sync to Grid
•Transition from independent grid to
component of main grid
• Phase 1 – Proof of Concept at National Instruments Lab
• Phase 2 – Simulated Microgrid at Southern Cal Edison
• Phase 3 – Real-World Microgrid at CPS Energy
19. The Future
19November 20, 2015 19
How will we save lives
through better patient care?
How will we reduce
passenger fatalities?
How will we reduce waste of
natural resources?
Things are coming together.TM
How will cities become
safer?
20. 20
Things are coming together.TM
Community. Collaboration. Convergence.
www.iiconsortium.org
Editor's Notes
Accurate as of October 28, 2015
Accurate as of October 28, 2015
Accurate as of October 28, 2015
Accurate as of October 28, 2015
Communication happens through one-off conversations between differing organizations, which hinders collaboration and progress.
The Industrial Internet Consortium brings together diverse organizations in a collaborative environment, facilitating conversations and innovative solutions
SPEAKER NOTES:
Deliver best practices, reference architectures, case studies, and standards requirements to ease deployment of connected technologies;
The IIC will identify requirements for open interoperability standards and define common architectures to connect smart devices, machines, people, processes and data.
Coordinate the development of common architectures and platforms in order to reduce duplication of effort;
Identification and location of sensor devices, Data exchange between sensor devices
Control and integration of collections of heterogeneous devices;
Data extraction and storage and Data and predictive analytics
Utilize existing and create new industry use cases and test beds for real-world applications;
Influence the global standards development process for Internet and industrial systems;
Facilitate open forums to share and exchange real-world ideas, practices, lessons, and insights;
Build confidence around new and innovative approaches to security.
A recent survey asked hundreds of professionals in the IoT space to identify the biggest challenge currently facing the Internet of Things. These are the results.
The IIC is actively addressing each of these challenges through working group activities.
Data Source: http://www.iot-nexus.com/interoperability/docs/power_players_in_the_internet_of_things.pdf
a company could use the platform to develop IoT solutions to be used in a hospital’s emergency department. The solutions might involve sensors in ambulances, which could provide real-time data, like precise location and patient vitals, providing the medical team adequate time to prepare and drive efficiencies to further improve the service.
Smart Data can enhance and improve the service provided by emergency service vehicles such as ambulances. Consider the scenario where an emergency service vehicle is dispatched to an incident. The response time is critical. What if the real-time GPS data generated by the emergency service vehicle can be combined with other real-time data from diverse sources such as; current traffic levels for all routes to the incident, location of roadwork’s, diversions and road closures. By combining and analyzing these diverse raw datasets in real-time in order to provide valuable and intelligent route planning and insights for the emergency service vehicle will improve response times leading to better life enhancing outcomes.
Use Case
Blue Light Vehicle Movement Analysis
Brief Description
Capture Emergency Vehicle Movement and Event Information and analyze the data to enable optimization of the service
Information Capture
Capture Main events related to Ambulance Trips
1. Leave Depot for Patient Location
2. Arrive at Patient Location
3. Depart patient Location
4. Arrive at Patient Destination
5. External Traffic Data
6. External Weather Data
Information Analysis
Average/Mean Trip Time Per Day/Hour/Afternoon etc.
Average/Mean Progress Per Minute at Different times of day
Slowest Routes
Fastest Routes
Comparison of Route Time with Traffic Time
Combine with external data to identify trends
Build profile to enable optimal routing /intelligent dispatch