Discuss Different Protocols Pertaining to Communications and Networking
6 Networking Power Protocols
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Transcript of 6 Networking Power Protocols
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Intro to Data Communication for the Emerging Smart Grid
Lecture 6
Carl Hauser
Washington State University
February 2014
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Power Grid Applications and Protocols Goal: understand the
uses and implementations of data communications in the Grid
Wide variety of requirements and approaches to meeting them
Outline SCADA and DNP3
Communication between control centers: ICCP
PMU communications: C37.118
Substation communications: IEC 61850
Smart metering
Time synchronization
Power Grid Communications 2
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SCADA
Outline SCADA and DNP3
Communication between control centers: ICCP
PMU communications: C37.118
Substation communications: IEC 61850
Smart metering
Time synchronization
SCADA is Supervisory Control and Data Acquisition Control:
• control center establishes set points in field devices
• Often manually done by grid operators
• Open-loop
Data acquisition • Usually: slow polling cycle: 2 to 4
seconds
• Sometimes: report by exception
• Data are recorded in Historian Database at control center
• Extracted for use by Energy Management System and display to operators on Human Machine Interface
Power Grid Communications 3
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DNP3: Distributed Network Protocol (www.dnp.org) www.trianglemicroworks.com/documents/DNP3_Overview.pdf
IEEE 1815 Standard
Originated in 1990
Layered Architecture
Physical/low level link: serial over copper, radio, etc.; ethernet; TCP or UDP
Data Link: 256 byte (max) frames; checksums; addressing; acknowledgements
Pseudo-transport: segmentation
Application
• Master-slave
• App level acknowledgements
User code
Power Grid Communications 4
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DNP3 Networking
Operate over variety of link types Speeds of 2400-
9600 bits/sec were fast
slow serial links
multi-drop links
Concentrated links
Not routable!
Power Grid Communications 5
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DNP3 App Layer
“Database” design Numbered data
object groups
Numbered positions in groups
Poll request: send me the value in group NN at position MM
Power Grid Communications 6
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DNP3 and SCADA Deficiencies for Smart Grid No security (but Secure
DNP3 has been developed)
Bump-in-the-wire security device “patch”
Designed for slow links, polling
Awkward data naming and addressing
“Only the control center cares about data” viewpoint
Measurements timestamped when received, not when made
Power Grid Communications 7
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ICCP
Outline SCADA and DNP3
Communication between control centers: ICCP
PMU communications: C37.118
Substation communications: IEC 61850
Smart metering
Time synchronization
Need: > 3000 business entities
run parts of power grid
• Generators, transmission operators, distribution operators
Grid must operate in synchrony—requires coordinated decisions
How do control centers share information?
Power Grid Communications 8
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ICCP/TASE.2: an Internet Application Protocol
Uses TCP for transport
Challenge: achieve high availability communication
Poll-response architecture (several second cycle time)
Power Grid Communications 9
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“Database” Problem
Bilateral agreements between businesses
what do you call the voltage measurement at a particular bus in a particular substation in your database and what do I call it in mine?
Mapping tables and ICCP Associations
Power Grid Communications 10
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ICCP Limitations in Smart Grid
Latency Primary use case is
polling data from correspondent database (Historian) which itself was polled at multi-second intervals
TCP
Security Largely
implemented by the mapping tables
Use secure transport layer (SSL/TLS)
Key management
Power Grid Communications 11
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PMU Communications
Outline SCADA and DNP3
Communication between control centers: ICCP
PMU communications: C37.118
Substation communications: IEC 61850
Smart metering
Time synchronization
PMU: Phasor Measurement Unit Measure voltage and
current 30-240 times per second
Synchrophasor: take each measurement at a precise time (microsecond accuracy)
This is way more and way better data than SCADA devices provide
Power Grid Communications 12
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PMU Protocol: C37.118
IEEE Standard
Application protocol over UDP or TCP transport
Intended use: convey synchrophasor data from PMU to Phasor Data Concentrator and between PDCs
Power Grid Communications 13
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Whither PMU Communications?
Share PMU data among utilities – Naming issue once again!
Send applications only what they need (only some require even 30 measurements /sec)
NASPInet
Improve latency to applications
PMU -> PDC -> application path imposes latency
GridStat
Power Grid Communications 14
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Beyond PMUs
PMUs exemplify modern sensing High rate
Accurately timestamped
With adequate communication these can support the vision of…
Much more automatic, real-time control of the grid for Better reliability
Greater efficiency
Enable integration of highly-variable generation: solar and wind
Power Grid Communications 15
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Substation Communications: IEC 61850 www.ieee.org/portal/cms_docs_pes/pes/.../T.../05TD0235.pdf
Outline SCADA and DNP3
Communication between control centers: ICCP
PMU communications: C37.118
Substation communications: IEC 61850
Smart metering
Time synchronization
Suite of protocols for substation automation More popular in Europe
and Asia than North America
Tries to cover all the needs for substation automation
Also tackles the database and naming problem
Power Grid Communications 16
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Many use cases in substations
Performance needed varies widely Protective relaying: low data
rate and very low latency (<4ms)
SCADA reporting: low data rate and high latency
PMU reporting: high data rate and moderate latency
Use high-performance networking technology: 100 Mbit/s ethernet and better
Power Grid Communications 17
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A new approach to naming
Isolate the “power” services and object models from the communication protocols
2: Application Layer 18
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Real-time Communication
Power Grid Communications 19
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Smart Metering - AMS
Outline SCADA and DNP3
Communication between control centers: ICCP
PMU communications: C37.118
Substation communications: IEC 61850
Smart metering
Time synchronization
Main goals
Automated meter reading
Demand response
Remote turn-on/off
More-aware consumers
Technical challenges
Hostile environment
Scale
Privacy (from consumer perspective)
Security of data (from utility perspective)
Power Grid Communications 20
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AMS Architecture
Power Grid Communications 21
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HAN – the home area network
Zigbee – 2.4GHz wireless band (like 802.11b/g/n wireless networking, many wireless phones, …)
“Internet of things” (but not IP!)
“Smart Energy Profile” – customization for metering
Cost matters!
Open vs. proprietary?
Energy monitor display
Smart appliances
http://www.engineeringtv.com/video/Texas-Instruments-ZigBee-Smart
Power Grid Communications 22
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NAN – the Neighborhood Network
Proprietary – no need for open?
Proprietary – don’t think that that means secure!
Mesh routing – radio-based pole-top stations (not much use of the power lines themselves to carry data though it has been done)
Power Grid Communications 23
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Time Synchronization
GPS devices are pretty cheap but installation and interfacing isn’t
Idea: use ubiquitous Ethernet to distribute time
Wide-area time synch Network Time Protocol: RFC 5905
25 years experience
10s of milliseconds accuracy
Local-area time sync Precision Time Protocol: IEEE 1588 2002
Microsecond agreement on LANs
Power Grid Communications 24
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Basic idea
Send a message and get a reply from another host – gives round-trip time
Send a message giving your current time and the round trip time
Other host can estimate the offset between clocks
Problems:
Variability in communication and asymmetric communication times (smaller problem in LANs)
Getting to microsecond level requires timestamping and time capture at a low level in the communication stack (close to the link layer) Power Grid Communications 25
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Conclusion
A whirlwind tour: Networking models
IP details at all layers
Power grid communications
Security: Concerns more than solutions
Up next: Computational aspects and distributed systems
(Prof. Bakken)
Security solutions (Prof. Hauser)
Power Grid Communications 26