IEC 61850 in Cyber Secure Environments - New Comprehensive Seminar

Due to my family situation (nursing my beloved wife from 2017 to 2022) I had to slow down my training activities. This year I was asked by several senior experts if it would be possible to resume the training.

As a result of discussions with friends of mine, we updated our previous course program and offer a brand new 5-day comprehensive public seminar for Automation, Protection, Monitoring, Engineering, Configuration (SCL), SCADA, Smart Grids, RTU, Gateways, … cyber physical security in electrical systems of any industrial plant … it is available for you and your people.

The reason for the update: We want to do more than teaching the theory of IEC 6850 and demonstrate single IEDs … we want to let our practice talk for your practice. The new training will start in March 2026. Taking the experience with many crucial applications of IEC 61850 into account we offer a new program for a 5-day course conducted by four (4) real experts.

09.-13. March 2026, Karlsruhe (Germany)
21.-25. September 2026, Karlsruhe (Germany)

Click HERE for more details on dates, location, and registration information.

IEC 61850-7-410 ED3 CDC - Hydroelectric Power Plants Available for Public Commenting

Please note that last Friday IEC TC 57 has published the following Committee Draft for Vote (CDV) (57/2750/CDV) for comments by National Committees AND for public commenting by anybody before April 04, 2025:

IEC 61850-7-410 ED3: Communication networks and systems for power utility automation - Part 7-410: Basic communication structure - Hydroelectric power plants - Communication for monitoring and control 

To comment on the CDV please click HERE. If you have not yet an account you can register ... if you have an account, go on. (IEC reports: Please use Google Chrome or Microsoft Edge).

IEC Public Commenting is a chance to let your voice be heard before the final vote.

This draft is a major step forward to get an international standard for hydroelectric power plants, steam and gas turbines.

Huge KIT Energy Lab 2.0 - Relies on IEC 61850

The KIT (Karlsruher Institut für Technologie) in my hometown Karlsruhe/Germany is deeply involved in several projects related to the Energiewende. One of the crucial components is the "Energy Lab 2.0".

In "A Concept for the Control, Monitoring and Visualization Center in Energy Lab 2.0" the authors Clemens Düpmeier, Veit Hagenmeyer, Ralf Mikut, and Karl-Uwe Stucky present an interesting concept.

Click HERE for a 16 page presentation presented in November 2015.

The research focuses on the APPLICATION of Control, Monitoring, and Visualization of various aspects of energy systems (gas, electricity, heat) - not just electrical systems.

IEC 61850 is THE solution for the process instrumentation - share process information in a standardized way.

These people have understood that the focus is on applications rather than on protocols ...
The 14 Layer Cake I had after a nice dinner in Jakarta shows that the automation of the energy systems of the future is more than "just another protocol" ... applications based on standard protocols are the crucial aspects:



Hm, the cake was very delicious.

New Work Proposal for Extending the System Configuration Language (SCL) for HMIs

IEC TC 57 has published (57/1767/NP) a proposal for extending the System Configuration Language (SCL) to provide high-level direction in terms of how best to bind the HMI graphical objects with the IEC 61850 data objects/attributes using the configuration description language defined in IEC 61850-6. It builds upon the existing System Configuration Language (SCL) defined in IEC 61850-6, in addition to possibly incorporating other non-IEC namespaces such as the W3C's Scalable Vector Graphics (SVG) namespace.

Communication networks and systems for power utility automation - Part 6xx: Configuration description language for communication in power utility automation systems related to Human Machine Interfaces (proposed IEC 61850-6xx)

This work will definitely helping to simplify the graphical representation of DataTypeTemplates in IEC 61850-6 (SCL).


A SCL DataTypeTemplate for a temperature measurement "STMP_0" could be bound to a graphical representation.

The depicted LNType has five related DataObjects. The temperature curve could be shown at an HMI as implemented in the client (HMI) interface of the VHPready demo. The VHPready demo could be downloaded. Click HERE for the access.
The client application of the demo is programmed in C#. A graphical template could be programmed ... if you need it. We could offer such a template if you are interested.

Could You Measure a Change in Air Flow caused by a Wind Turbine in a distance of 100 km?

Assume an air flow of x m**3 per second. What happens at your position if a big wind turbine is starting to rotate in a distance of 100 km? Do you expect that you could measure that the air flow is reduced due to the wind turbine that removes energy from the air flow? It may be possible if the turbine would be located in a huge tube. So far so good.
Another question: Could you believe "that a short-circuit at Lawrence Berkeley lab one day was observed by a micro-PMU [Phasor Measurement Units] in Los Angeles, 550 kilometers away, as a 0.002 percent dip in voltage"? It is more likely that one can measure a 0.002 percent dip in 550 km distance than a change in air flow 100 km away caused by a wind turbine.
With a network of many micro-PMUs it may be possible to figure out that somebody is switching on a computer. If you install enough micro-PMUs you may get there.
With a good power quality meter and pattern recognition I could figure out when my wife switches on the Toaster or Microwave.

Each of load (in our home or in the neighborhood) has a specific finger print. So that I could see the patterns and learn what they mean - after some training.

Some people made this observation "We're watching the volts and the amps and we’re not even inside the substation. We’re five miles away. We came up with this idea: What if we were to tell the substation operator that this substation switch is opening and closing? If they were the ones opening and closing it, that’s great. But if not, that’s a pretty good sign that there’s a cyber attack at least being experimented with.”

This is a true story (I guess).

Click HERE for a news report from IEEE Spectrum.

More Big Data to come. Be aware in your home that a power quality meter connected to the copper wire some 20 to 50 m away may be watching you. What about privacy? Is it a good thing to know (almost) everything?
"For in much wisdom is much grief; and he that increaseth knowledge increaseth sorrow." (Kohelet 1:18)

Stromnetz Berlin - Goes Digital with various approaches

The distribution operator "Stromnetz Berlin" with some 2.4 Million customers and 350.000 house service connections operates the following networks and applies various communication solutions:

110 kV Network: 
- 80 Substations with 600 switch gears
- all switch gears remote controllable
- communication infrastructure: fiber optic

10 kV Network:
- 10,700 Distribution stations with 23,000 switch gears
- 10 per cent of switchgears remote controllable
- expandable to 100 per cent
- communication infrastructure: land line, TETRA Radio

0,4 kV Network:
- 15,000 cable distributor boxes
- 96,000 feeders
- 1 per cent of switch gears remote controllable
- expandable to 100 per cent
- communication infrastructure: pager (e*nergy - based on e*message)

The protocols used are likely quite different - I guess.
Click HERE to download a presentation from "Stromnetz Berlin" [German only]
Click HERE for the presentation material (14 slide presentations) of a recent conference [German only]

Are you prepared for the Solar Eclipse 2015 on March 20?

Why raise such a question on this blog that is about standards like IEC 60870-5-104 and IEC 61850 …? These are two good questions. Let’s discuss them briefly.

The Solar Eclipse 2015 and its impact on the power transmission system is discussed these days. The crucial issue is the minute-to-minute power gradient that may exceed between minus 400 MW/minute and plus 700 MW/minute; the highest gradient occurs when the PV in-feed returns at the end of the phase. This gradient may be managed by the TSO or not – who knows. We know it at lunch time on March 20, 2015.

There are many recommendations on the web, how to get prepared: having water, food, … for up to 10 days or so … I hope we will not need these.

@Question 2:

There is a need for the TSOs (just four in Germany!) to relay on good measurements from all-over in the grid and secure control possibilities to manage power plant in-feeds and substations. I guess they have good communication systems they can trust. These systems have been developed over many decades. They are tested and run reliably. Still. But what happens in future where we will have hundreds or millions of technical systems (embedded controllers …) that contribute to the system view and management?? Is this an issue at all?

Yes, it is a crucial issue. Let me discuss the following real-life incident reported last week:

A gateway in a virtual power plant provides the measured load on the network connection point of a CHP (combined heat and power) system. Normally the CHP feeds power into the network. But all in a sudden the VPP/TSO received a signal telling them a jump of the load from 0 MW to 600 MW!! Should the control center responsible for that part of the grid act or not? Hm. If this would be a real jump then it would have to react.

(Un)Fortunately the 600 MW jump was just a jump in the Value communicated!! It was caused by an error in the gateway (RTU kind of device). Was this value plausible? No. Because the CHP could just feed-in – not draw that much power from the grid.

With IEC 61850 in place we could easily expose the limits of power production and load. The logical node MMXU could be used for the limits in which a value is valid:

Data Object TotW of class MV (measured value) - Total active power (total P)

could provide the actual value, quality, range and the limits in the details provided through the MV CDC:

instMag.f	AnalogueValue coded as floating point
q	Quality
range	ENUMERATED normal|high|low|high-high|low-low (out of range would change quality value)
rangeC	RangeConfig: hhLim hLim lLim llLim min max

min: the min (minimum) attribute shall represent the minimum process measurement for which values of i or f are considered within process limits. If the value is lower, q shall be set accordingly (validity = questionable, detailQual = outOfRange).

max: the max (maximum) attribute shall represent the maximum process measurement for which values of i or f are considered within process limits. If the value is higher, q shall be set accordingly (validity = questionable, detailQual = outOfRange).

In our case, the TotW for the CHP generator may be limited between 0 W (min) and 35 kW (max). A value of “minus 600” MW would have to be flagged as questionable and outOfRange !! Negative values and values higher than 35 kW would be flagged out of range!

The receiver (a control center) could check the limits of the values (either by reading the range configuration online by a service or getting it from the corresponding SCL file). It could figure out that the range is 0-35 kW. Even if the gateway (RTU) would send “minus 600” MW (load) … the CC could understand that this is a bad value – recommended not to use.

The meta-data of the measured value serve as a means to help interpreting the plausibility of a value communicated.

IEC 61850 models add very useful information to help (a bit) keeping the power flowing. There are many other physical issues to take into account … but information and information exchange plays a crucial role!

Monitoring the Battery of the Boeing Dreamliner 787 would have helped to prevent damages

I guess you remember the trouble Boeing was faced with when the huge battery packs in the Dreamliner 787 some two years ago. The Auxiliary Power Unit Battery Fire was likely caused by several severe “cell internal short circuiting and the potential for thermal runaway of one or more battery cells, fire, explosion, and flammable electrolyte release”.

More precise Condition Monitoring would have helped to prevent such incidents – and would have shown very early that the design of the battery system was quite fragile.

One of the findings (page 91 of the released incident report) is:

“More accurate cell temperature measurements and enhanced temperature and voltage monitoring and recording could help ensure that excessive cell temperatures resulting from localized or other sources of heating could be detected and addressed in a timely manner to minimize cell damage.”

Click HERE for the complete official NTSB report.

Monitoring batteries is very crucial the more our life depends on these systems – in airplanes, in substations, power stations, mobile systems, communication infrastructure … It is not sufficient to have a battery – the batteries must be maintained, tested from time to time, and monitored continuously.

Two groups (I am aware of) have defined Battery Monitoring information models:

1. IEC 61850-90-9 (Use of IEC 61850 for Electrical Storage Systems)

Excerpt of the battery system (without further discussion):

2. IETF EMAN (Energy Management)

Definition of Managed Objects for Battery Monitoring / draft-ietf-eman-battery-mib-13

Click HERE for the EMAN draft for Battery Monitoring.

Battery monitoring could safe life!

New Models for Condition Monitoring: IEC 61850-90-3

IEC TC 57 just published a very comprehensive document (draft technical report, 57/1522/DTR) of 150 pages that suggests a lot of new models:

IEC 61850-90-3 TR:
Communication networks and systems for power utility automation –
Part 90-3: Using IEC 61850 for condition monitoring diagnosis and analysis

The CMD (Condition Monitoring Diagnosis) which diagnoses power grid health status has been one of the major issues to improve the reliability of the power system by preventing a potential failure in advance. Since too many different information modeling, information exchange, and configuration techniques for CMD in various forms from many vendors are currently used, they need to be standardized in TC57.

The new document contains a lot of new Logical Nodes and Data Objects like for:

• GIS (Gas Insulated Switchgear)
• Transformer
• Load Tap Changer (LTC)
• Under Ground Cable (UGC)
• Transmission Line (TL)
• Auxiliary Power System

Example of an extension of the very common Model for a tank (KTNK):

LevMaxSet - Maximum level reached setting
LevHlfSet - Half level reached setting
LevMinSet - Minimum level reached setting

LevMax - Maximum level reached
LevHlf - Half level reached
LevMin - Minimum level reached

Voting terminates on 2015-01-16

More to come.

IEC 61850 in Hydro Power Plants

I have been asked recently about the application of IEC 61850 in Hydro Power Plants. Yes, there is growing interest to apply IEC 61850 conformant monitoring and control systems in the hydro domain.

A nice presentation from (Ingeteam Power Technology S.A.) with the title

HYDROELECTRIC POWER PLANTS AUTOMATION USING IEC 61850:
EXPERIENCES AND IMPROVEMENTS FOR THE USER
presented in April 2014

closes with the statement that “IEC 61850 is a valid solution for hydro power plant automation … More than 10 IEC 61850 hydro projects mainly in Spain.”

Click HERE for a nice presentation [pdf, 0.5 MB]

The use of IEC 61850 for conventional power plants is also growing. I have conducted several training courses in 2014 for engineers working in the power plant business.

Be sure: More to come.

Just published: Draft 61850-90-17 – Using IEC 61850 to transmit power quality data

IEC TC 57 has just published the 52 page Draft IEC Technical Report 61850-90-17 – Using IEC 61850 to transmit power quality data (57/1488/DC).

The document is available for comments until 2014-10-10.

Contact your TC 57 National Committee for a copy.

Phenomena considered in the draft are related to:

• Power frequency
• Magnitude of the supply voltage
• Flicker
• Supply voltage dips and swells.
• Voltage interruptions
• Transient voltages
• Supply voltage unbalance
• Voltage harmonics
• Voltage interharmonics
• Mains signalling voltage on the supply voltage
• Rapid Voltage Changes (RVC)
• Underdeviation and overdeviation
• Magnitude of current
• Current recording
• Harmonic currents
• Interharmonic currents
• Current unbalance
• Frequency deviation
• Supply voltage variations
• Voltage unbalance
• Harmonic voltage
• Interharmonic voltage
• Voltage fluctuation and flicker
• Mains signalling and voltages

This draft is intended to increase the interoperability between power quality monitoring systems and any application that needs the corresponding information for operation or post mortem analysis.

Brief EPRI Report on Standards of DistribuTech 2014

EPRI has published a Brief Report of DistribuTECH 2014.

It seems that a hot topic was “DATA” … data from everywhere of everything! Sure there is a need to share the pool of “Big Data”. I have heard about a SCADA project that receives Terra Bytes of “big Data” from a huge wind power park trough IEC 61400-25. This seems to be “Big Data” and “little information” … good for hardware manufacturers.

The EPRI Brief reports from the DistribuTech 2014:

“This was also another good year for standards. The vendor community has heard loud and clear that standards are a preference of electric utilities and the vendors have done a good job of promoting where they are using standards including DNP3, IEC 61850, IEC 61968/61970 (the CIM), MultiSpeak, and more. One relatively new standard that had a strong presence was OpenADR (Open Automatic Demand Response).”

Click HERE for the complete report.

I hope that they are looking at useful information rather than bunches of Data – that just may tell the receiver: nothing has changed, nothing has changed, nothing has changed, … stop here and make it smarter:

This is one aspect of the philosophy of IEC 61850 – which needs to be understood by more people … it will take some time to understand this.

How do you know which IEC 61850 Information Models are published or underway for publication?

Information models in IEC 61850 are growing very fast. Many groups have understood that one of the benefits of IEC 61850 is this: Information Models for real world information (measurements, status, configuration, limits, control, …).

One crucial question is this: Where can you get an overview and introduction in the many models already published or those models underway? There are several groups extending the models for several applications inside and outside electrical substations.

The easiest way is to ask somebody that has a good overview and long-term experience with IEC 61850 …

One of the crucial extensions is defined in the draft IEC 61850-90-3. During a training course I was asked last week if IEC 61850 defines something for overhead line monitoring – he did not have a chance to easily figure out that there is one document under preparation … sure you usually don’t know it or don’t find some documentation.

The following figure gives a brief overview about the various aspects of line monitoring:

Want to learn more on the 300+ Logical Node classes defined so far? Please contact NettedAutomation … or attend the next training course in Frankfurt/Germany on 16-18 October 2013.

You have the chance to learn the basics AND the most crucial definitions of the standards and how they could be used. See you there.

The aging infrastructure and aging work force requires more sensors to make sure that the power is flowing reliably in the future! Almost every day you can read stories about breaking infrastructure.

Merging Unit and Monitoring IED with IEC 61850 Server and I/Os

The Merging Unit MU320 offered by Reason combines the Sampled Value exchange with “conventional” Inputs and Outputs using GOOSE and Client/Server communication. This device seems to be a very convenient way to combine both worlds: real-time and general SCADA applications:

• 9-2LE compliant
• Up to 16 analog inputs, 12 binary inputs and 16 outputs
• Support for Protection and Measurement (metering) profiles simultaneously
• MMS monitoring and control
• Binary inputs and outputs via GOOSE messages
• Synchronization via Ethernet using PTP (IEEE1588)
• Parameter setting using standard data model and SCL language

Click HERE for a more detailed description.

Optical Fibre for Temperature Measurement in Power Systems

Optical fibres are known to be used in power systems because they withstand the rough conditions in high voltage environments – as such they are used in Substations for carrying messages, e.g., according to IEC 61850.

There is another very interesting use case of optical fibres in power systems: in generation, transport, distribution, and loads. One of the crucial measurements that can be applied to more efficiently use of electric power is measuring temperatures. But you may state that installing a lot of temperature sensors could be quite expensive!

With the application of optical fibre for measuring temperatures it seems to be a very promising approach to reduce the amount of power needed for many critical process like in huge data centers, high voltage lines and cables, transformers, switch gears, to name a few.

According to alquist (a UK based company specializing on measurement systems using fibres) there are many advantages of fibre as a temperature sensor:

• Simultaneously measures temperature and position over long distances
• Low cost – the sensor is made from standard 50/125 optical fibre zip cord - very cost effective
• Immune to shock/vibration and electromagnetic interference
• No electronics, wireless, batteries or moving parts in monitoring zone. Totally passive, minimal maintenance.
• Inherent high reliability (fibre has a design life of 30+ years)
• High temperature range -200°c to +500°c
• Extremely small for access in legacy areas with restricted space
• Easily installed in without any downtime or interruption of service

There are an incredible number of applications for fibre optics beyond their use as a simple communications links.

Download a very useful presentation given by Andrew Jones (alquist) [pdf, 2.8 MB]

The availability of myriads of “measurement signals” from various processes allows to more efficiently use energy, i.e., to reduce the amount of energy we need to consume to service our needs for modern life.

What ever will be measured in energy supply systems could be modeled and communicated with IEC 61850 – The Communication Standard for power system automation. One crucial focus of IEC 61850 is on measurements!

Use of IEC 61850 for Electrical Systems Monitoring and Control in the Oil and Gas Industry

Laurent Guise and Patrick Montignies both from Schneider Electric Industries (Grenoble, France) have discussed the use of IEC 61850 for Electrical System Monitoring and Control Systems in the Oil and Gas Industry. The results can be found in a nice paper some years ago.

“Crucial industrial sites such as for Oil and Gas plants are requesting more and more monitoring and control of their electrical installation to increase the electricity availability of their process while optimizing the cost of operation.

While willing to implement an Electrical Monitoring and Control System (EMCS), users face the issue of choosing the right communication technology.

By the way an emerging technology – IEC 61850 – appears on the market. This technology promises real interoperability, while offering unprecedented capabilities for reducing the wiring and increasing the installation agility. Are all these promises a reality? What would be the most pragmatic way for taking the maximum benefits of this new technology while minimizing the risk? The object of this paper is to make a point of technology maturity, to identify the real benefits, but also some potential drawbacks.”

In the conclusion the authors state: “Is there a value to choose IEC 61850 for EMCS application? … there are definitely a lot of reasons for considering positively the usage of IEC 61850.”

Access the complete paper on IEC 61850 for Electrical System Monitoring and Control [pdf]

Today, a few years after the paper was published, we can state that the situation has been improved since then. Especially the availability of mature products for monitoring and control of any kind of processes and equipment installed in the many electrical systems make it easy these days to implement IEC 61850 in short time to market – and for a reasonable price.

To build a Gateway between IEC 61850 and any typically used RTU protocol is as easy as riding a bike.

Condition Monitoring of Assets with IEC 61850

Asset Management using IEC 61850 is one of the important areas of future power delivery systems. Transformer monitoring in the Distribution Network is one of the crucial solutions to keep the power flowing. IEC 61850 and IEC 61400-25 have a lot of logical nodes and data objects.
The presentation of a paper by Karlheinz Schwarz at the Distributech 2010 was attended by some 40 experts. Good questions were discussed at the end of the presentation. The paper has an attachment with the names of all 283 published Logical Nodes of all standards of the series IEC 61850 and IEC 61400-25.

Click HERE for the paper [PDF, 670 KB]
Click HERE for the presentation slides [PDF, 300 KB]

Recently another paper on the same subject was presented by Rod Hughes and Christoph Brunner.

More to come soon.

Introduction to IEC 61850 – two Papers available for download

Karlheinz Schwarz (SCC) has presented two papers on IEC 61850 in Macau (2008). The papers can now be downloaded for free:

The first document gives an overview about the common aspects of the new international standard series IEC 61850 and how it is applied and extended to meet the requirements for al-most the whole electrical energy supply chain. It discusses the reduction of total life cycle cost of power utility automation systems using standard compliant devices, communication and tools.

IEC 61850 beyond Substations – The Standard for the whole Energy Supply System [pdf, 174 KB]

The second document gives an overview about the application of the new international standard series IEC 61850 and IEC 61400-25 for condition monitoring of primary equipment and monitoring of any process information. It discusses the basic monitoring concepts of IEC 61850 using the many information models (status information and measurements) and communication services for reporting, logging, GOOSE, sampled values, and recording

Advanced Condition Monitoring of Primary Equipment with the Standard Series IEC 61850 AND IEC 61400-25 [pdf, 432 KB]

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Two MW Wind-to-Gas converter build for E.ON in Germany

Storage of energy is one of the basic building blocks for the future power delivery system. The option of converting electric power into gas is one of the most discussed and promising storage options these days. In February I have discussed this briefly:

Wind and Solar Gas – A Challenging Storage Option

A 2 MW utility scale converter project at E.ON in North Eastern Germany has been announced by Hydrogenics the other day. Up to 30 MWh of energy can be converted from wind power into gas in 24 hours – the gas will be injected into the regional natural gas pipeline, making the natural gas pipeline network a storage system for surplus electrical power generated from renewable resources. Great idea.

Read the complete news report “Hydrogenics wins order from E.ON for 'Power-to-Gas' energy storage project in Germany”

Standards like IEC 61850 and IEC 61400-25 (Wind Turbines) are ready to support the monitoring and control of wind turbines, and many other applications.

IEC 61850 ready for VHP-Ready (Virtual Heat and Power Ready)

Vattenfall Europe New Energy GmbH and Vattenfall Europe Wärme AG seem to be ahead of many other utilities in implementing “virtual Power Plants”. They have set a standard on how to use renewable energy in a virtual power plant. The information exchange is realized with two IEC TC 57 standards: IEC 60870-5-104 (Fernwirktechnik) and IEC 61850-7-420 (DER).

Vattenfall is one of the leaders of the implementation of virtual power plants. The concept is called: VHP READY – Virtual Heat & Power Ready.

Their objective is by end of 2012 to provide their services to 150.000 housing units (with some 500 CHP or heat pumps) communicating with a Vattenfall control center. By 2013 they expect some 1,000 CHP or heat pumps providing heat and electric power to some 200.000 housing with an electric capacity of 200 MW.

The requirements document lists a total number of signals of 40:

• 8 binary status signals,
• 17 measurements and calculated values,
• 5 metered values, and
• 10 control points.

Requirements document referring to IEC 60870-5-104 and IEC 61850 can be downloaded [German, pdf, 23 pages, 360 KB]

VHP READY – Virtual Heat & Power Ready

Vattenfall virtuelles Kraftwerk

Several other projects are under way in Germany to implement a similar approach. In one project there is already a plan to define (and possibly standardize) a specific profile (subset) of IEC 61850-7-420. Such a profile would represent the above some 40 signals – a very simple set of models that could easily be implemented in an IEC 61850 IED like the Beck IPC IEC 61850 com.tom:

More information on Beck IPC IEC 61850 com.tom.

Basic component for IEC 61850: the IPC@CIP

Download the discussion about benefits using Beck’s ready-to-go solutions with IEC 61850 [pdf, 2.3 MB, 18 pages]