internet of things and large-scale data analytics
TRANSCRIPT
Internet of Things and Large-scale Data Analytics
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Payam BarnaghiInstitute for Communication Systems (ICS)/5G Innovation Centre University of SurreyGuildford, United Kingdom
The IET Surrey Network, September 2015
2IBM Mainframe 360, source Wikipedia
Apollo 11 Command Module (1965) had 64 kilobytes of memory operated at 0.043MHz.
An iPhone 5s has a CPU running at speeds of up to 1.3GHzand has 512MB to 1GB of memory
Cray-1 (1975) produced 80 million Floating point operations per second (FLOPS)10 years later, Cray-2 produced 1.9G FLOPS
An iPhone 5s produces 76.8 GFLOPS – nearly a thousand times more
Cray-2 used 200-kilowatt power
Source: Nick T., PhoneArena.com, 2014
Computing Power
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−Smaller size−More Powerful−More memory and more storage
−"Moore's law" over the history of computing, the number of transistors in a dense integrated circuit has doubled approximately every two years.
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Sensor devices are becoming widely available
- Programmable devices- Off-the-shelf gadgets/tools
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More “Things” are being connected
Home/daily-life devicesBusiness and Public infrastructureHealth-care…
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People Connecting to Things
Motion sensorMotion sensor
Motion sensor
ECG sensor
Internet
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Things Connecting to Things
- Complex and heterogeneous resources and networks
Example: Radiation Sensor Board (Libelium)
Source: Wireless Sensor Networks to Control Radiation Levels, David Gascón, Marcos Yarza, Libelium, April 2011.
Waspmote
Connected world
10Image courtesy: Wilgengebroed
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Internet of Things (IoT)
− Extending the current Internet and providing connection, communication, and inter-networking between devices and physical objects, or "Things," is a growing trend that is often referred to as the Internet of Things.
− “The technologies and solutions that enable integration of real world data and services into the current information networking technologies are often described under the umbrella term of the Internet of Things (IoT)”
Mobile Technologies
12Image courtesy: Economist
1G
AMPS, NMT, TACS
2G
GSM. GPRS, TDMA IS-136,
CDMA IS-95, PDC
3G
UMTS, CDMA2000,
4G5G
LTE, LTE-A
PeopleThings
Voice
Text
Data
5G technologiesand standards
Connection + Control M2M/IoT
Change in the communication technologies
Mobile Services and Applications
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Image courtesy: Economist
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Things, Devices, Data, and lots of it
image courtesy: Smarter Data - I.03_C by Gwen Vanhee
Cyber-Physical-Social Data
16P. Barnaghi et al., "Digital Technology Adoption in the Smart Built Environment", IET Sector Technical Briefing, The Institution of Engineering and Technology (IET), I. Borthwick (editor), March 2015.
Internet of Things: The story so far
RFID based solutions Wireless Sensor and
Actuator networks, solutions for
communication technologies,
energy efficiency, routing, …
Smart Devices/Web-enabled
Apps/Services, initial products,
vertical applications, early concepts and
demos, …
Motion sensor
Motion sensor
ECG sensor
Physical-Cyber-Social Systems, Linked-data,
semantics,More products, more
heterogeneity, solutions for control and
monitoring, …
Future: Cloud, Big (IoT) Data Analytics, Interoperability, Enhanced Cellular/Wireless
Com. for IoT, Real-world operational use-cases and
Industry and B2B services/applications,
more Standards… P. Barnaghi, A. Sheth, "Internet of Things: the story so far", IEEE IoT Newsletter, September
2014.
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“Each single data item is important.”
“Relying merely on data from sources that are unevenly distributed, without considering background information or social context, can lead to imbalanced interpretations and decisions.”?
Data- Challenges
− Multi-modal and heterogeneous− Noisy and incomplete− Time and location dependent − Dynamic and varies in quality − Crowed sourced data can be unreliable − Requires (near-) real-time analysis− Privacy and security are important issues− Data can be biased- we need to know our data!
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Data Lifecycle
20Source: The IET Technical Report, Digital Technology Adoption in the Smart Built Environment: Challenges and opportunities of data driven systems for building, community and city-scale applications, http://www.theiet.org/sectors/built-environment/resources/digital-technology.cfm
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“The ultimate goal is transforming the raw data to insights and actionable knowledge and/or creating effective representation forms for machines and also human users and creating automation.”
This usually requires data from multiple sources, (near-) real time analytics and visualisation and/or semantic representations.
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“Data will come from various source and from different platforms and various systems.”
This requires an ecosystem of IoT systems with several backend support components (e.g. pub/sub, storage, discovery, and access services). Semantic interoperability is also a key requirement.
Device/Data interoperability
23The slide adapted from the IoT talk given by Jan Holler of Ericsson at IoT Week 2015 in Lisbon.
Search on the Internet/Web in the early days
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Accessing IoT data
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“ The internet/web norm (for now) is often to use an interface to search for the data; the search engines are usually information locators – return the link to the information; IoT data access is more opportunistic and context aware”.
The IoT requires context-aware and opportunistic push mechanism, dynamic device/resource associations and (software-defined) data routing networks.
IoT environments are usually dynamic and (near-) real-time
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Off-line Data analytics
Data analytics in dynamic environments
Image sources: ABC Australia and 2dolphins.com
What type of problems we expect to solve using the IoT and data analytics solutions?
28Source LAT Times, http://documents.latimes.com/la-2013/
A smart City exampleFuture cities: A view from 1998
29Source: http://robertluisrabello.com/denial/traffic-in-la/#gallery[default]/0/
Source: wikipedia
Back to the Future: 2013
Common problems
30Source: thestar.com.my & skyscrappercity.com
Guildford, Surrey
Applications and potentials
− Analysis of thousands of traffic, pollution, weather, congestion, public transport, waste and event sensory data to provide better transport and city management.
− Converting smart meter readings to information that can help prediction and balance of power consumption in a city.
− Monitoring elderly homes, personal and public healthcare applications.
− Event and incident analysis and prediction using (near) real-time data collected by citizen and device sensors.
− Turning social media data (e.g. Tweets) related to city issues into event and sentiment analysis.
− Any many more…
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EU FP7 CityPulse Project
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CityPulse Consortium
Industrial SIE (Austria,
Romania),ERIC
SME AI,
HigherEducation
UNIS, NUIG,UASO, WSU
City BR, AA
Partners:
Duration: 36 months (2014-2017)
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AnalyticsToolbox
Context-awareDecision Support,
Visualisation
Knowledge-based
Stream Processing
Real-TimeMonitoring &
Testing
Accuracy & Trust
Modelling
SemanticIntegration
On Demand Data
Federation
OpenReferenceData Sets
Real-TimeIoT InformationExtraction
IoT StreamProcessing
Federation ofHeterogenousData Streams
Design-Time Run-Time Testing
Exposure APIs
Designing for real world problems
101 Smart City scenarios
37http://www.ict-citypulse.eu/scenarios/
Dr Mirko PresserAlexandra Institute Denmark
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Data Visualisation
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Event Visualisation
CityPulse demo
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Data abstraction
41F. Ganz, P. Barnaghi, F. Carrez, "Information Abstraction for Heterogeneous Real World Internet Data", IEEE Sensors Journal, 2013.
Adaptable and dynamic learning methods
http://kat.ee.surrey.ac.uk/
Correlation analysis
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Analysing social streams
44With
City event extraction from social streams
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Tweets from a city POS Tagging
Hybrid NER+ Event term extraction
Geohashing
Temporal Estimation
Impact Assessment
Event Aggregatio
nOSM
LocationsSCRIBE
ontology
511.org hierarchy
City Event ExtractionCity Event Annotation
P. Anantharam, P. Barnaghi, K. Thirunarayan, A.P. Sheth, "Extracting City Traffic Events from Social Streams", ACM Trans. on Intelligent Systems and Technology, 2015.
Collaboration with Kno.e.sis, Wright State University
Geohashing
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0.6 miles
Max-lat
Min-lat
Min-long
Max-long
0.38 miles
37.7545166015625, -122.40966796875
37.7490234375, -122.40966796875
37.7545166015625, -122.420654296875
37.7490234375, -122.420654296875
437.74933, -122.4106711
Hierarchical spatial structure of geohash for representing locations with variable precision.
Here the location string is 5H34
0 1 2 3 4 5 67 8 9 B C D EF G H I J K L
0 172 3 4
5 6 8 9
0 1 2 3 4
5 6 7
0 1 23 4 5
6 7 8
Social media analysis
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City Infrastructure
Tweets from a city
P. Anantharam, P. Barnaghi, K. Thirunarayan, A. Sheth, "Extracting city events from social streams,“, ACM Transactions on TICS, 2014.
Social media analysis (deep learning – under construction)
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http://iot.ee.surrey.ac.uk/citypulse-social/
Accumulated and connected knowledge?
49Image courtesy: IEEE Spectrum
Users in control or losing control?
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Image source: Julian Walker, Flicker
Data Analytics solutions for IoT data
− Great opportunities and many applications;− Enhanced and (near-) real-time insights;− Supporting more automated decision making and
in-depth analysis of events and occurrences by combining various sources of data;
− Providing more and better information to citizens;− …
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However…
− We need to know our data and its context (density, quality, reliability, …)
− Open Data (there needs to be more real-time data)
− Complementary data − Citizens in control − Transparency and data management issues
(privacy, security, trust, …)− Reliability and dependability of the systems
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In conclusion
− IoT data analytics is different from common big data analytics.
− Data collection in the IoT comes at the cost of bandwidth, network, energy and other resources.
− Data collection, delivery and processing is also depended on multiple layers of the network.
− We need more resource-aware data analytics methods and cross-layer optimisations.
− The solutions should work across different systems and multiple platforms (Ecosystem of systems).
− Data sources are more than physical (sensory) observation.− The IoT requires integration and processing of physical-cyber-
social data.− The extracted insights and information should be converted
to a feedback and/or actionable information. 53
IET sector briefing report
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Available at: http://www.theiet.org/sectors/built-environment/resources/digital-technology.cfm
CityPulse stakeholder report
55http://www.ict-citypulse.eu/page/sites/default/files/citypulse_annual_report.pdf
Other challenges and topics that I didn't talk about
Security
Privacy
Trust, resilience and reliability
Noise and incomplete data
Cloud and distributed computing
Networks, test-beds and mobility
Mobile computing
Applications and use-case scenarios
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