At this year’s NTMS conference in Paris, France, Fabian Knirsch presented the work of Andreas Unterweger, Fabian Knirsch, Dominik Engel and Christoph Leixnering about “Lessons Learned from Implementing a Privacy-Preserving Smart Contract in Ethereum”.

The authors present a real-world use case allowing customers in a diverse market to find optimum (cheap) energy tariffs. The privacy-preserving matching between customer forecasts and utility provider templates is implemented as a smart contract in the public Ethereum blockchain.

In this paper, we are the first to implement such a privacy-preserving protocol from the energy domain as a smart contract in Ethereum. We elaborate on and present our implementation as well as our practical findings, including more or less subtle traps and pitfalls.

We are pleased to announce that our study on “Exploring the impact of network tariffs on household electricity expenditures using load profiles and socio-economic characteristics” has been published in Nature Energy.

Price structures in the electricity sector are currently in flux as a result of digital technology advancements that provide the power grid with distributed energy. To ensure a sustainable and economical use of alternative energy, it is necessary to understand the impact that price variation has on end-consumer consumption behaviour.

Cornelia Ferner and Dominik Engel from the CSE, together with experts from the Energieinstitut Linz studied consumer behaviour by evaluating the impact of different price structures on consumption patterns, using smart meter electric power consumption data from 765 Austrian households. Applying data analytic methods, the researchers showed that the consumption behaviour of households with lower income was more affected by daily price fluctuations. Another contributing factor is that lower income households do not have the resources to purchase programmable energy saving appliances and thereby reduce their peak electricity demand.

• V. Azarova, D. Engel, C. Ferner, A. Kollmann, and J. Reichl, “Exploring the impact of network tariffs on household electricity expenditures using load profiles and socio-economic characteristics,” Nature Energy, vol. 3, p. 317–325, 2018.
  [Bibtex]

  @article{Azarova18a,
  Abstract = {Growing self-generation and storage are expected to cause significant changes in residential electricity utilization patterns. Commonly applied volumetric network tariffs may induce imbalance between different groups of households and their respective contribution to recovering the operating costs of the grid. Understanding consumer behaviour and appliance usage together with socio-economic factors can help regulatory authorities to adapt network tariffs to new circumstances in a fair way. Here, we assess the effects of 11 network tariff scenarios on household budgets using real load profiles from 765 households. Thus we explore the possibly disruptive impact of applying peak-load-based tariffs on the budgets of households when they have been mainly charged for consumed volumes before. Our analysis estimates the change in household network expenditure for different combinations of energy, peak and fixed charges, and can help to design tariffs that recover the costs needed for the sustainable operation of the grid.},
  Author = {Azarova, Valeriya and Engel, Dominik and Ferner, Cornelia and Kollmann, Andrea and Reichl, Johannes},
  Doi = {10.1038/s41560-018-0105-4},
  Isbn = {2058-7546},
  Journal = {Nature Energy},
  Title = {Exploring the impact of network tariffs on household electricity expenditures using load profiles and socio-economic characteristics},
  Url = {https://doi.org/10.1038/s41560-018-0105-4},
  pdf = {http://rdcu.be/ISbU},
  Year = {2018},
  volume = {3},
  pages = {317--325},
  }

Victor, Erwan, Titouan, Nicolas and Jeroen are incoming students from Germany, France and Belgium (in picture with supervisor Norbert Egger).

They support research at the DSSE Domain Specific Systems Engineering group until June. In the project FREDOSAR, they develop a smart home app that can transfer confidential data from the web app to the smart home system.

We are very grateful for their help!

Our researcher Christian Neureiter participated in a face-to-face meeting of the “IEC Systems Committee for Smart Cities” from January 31st until February 2nd in Germany (Dortmund).

The Committee’s scope is to foster the development of standards in the field of electrotechnology to help with the integration, interoperability and effectiveness of city systems.

Christian contributed some of our ideas from the field of Smart Grid engineering to the ongoing discussion in Working Group 3. This Working Group focuses on the development of a Smart City Reference Architecure model.

We are very proud to be a part of this community!

For detailed information see Christians presentation: “The SGAM Toolbox – Possible Adoption for SCRAM”.

The planned Smart Meter rollout at a large scale has raised privacy concerns. In order to protect the customer’s privacy, researchers of the Center are exploring the security of user data.

Günther Eibl, Sebastian Burkhart and Dominik Engel investigated holiday detection based on energy consumption data. Their paper named “Unsupervised Holiday Detection from Low-Resolution Smart Metering Data” was presented recently at the 4th International Conference on Information Systems Security and Privacy in Madeira by Günther Eibl.

The explored dataset is the first realistic (in terms of number of households and measurement duration) smart meter dataset that is analyzed using occurrence or holiday detection methods. Some exemplary households were presented in order to discuss issues like background appliances, daydependent background signal characteristics or the existence of unplausible values. Using a reformulation of the holiday detection problem as a classification problem a new, dedicated holiday detection method is presented.

This work sets the starting point for holiday detection and raises a number of technical issues for future work: modeling and removal of background appliances, choice of thresholds, feature selection, proper modeling and smoothing of the day-dependent night distributions, inclusion of other predictive variables like day of the week and of course evaluation for labelled datasets. Considering the privacy perspective it would be interesting to investigate possible privacy consequences apart from the detection of secondary residences.

For further details, please see:

• G. Eibl, S. Burkhart, and D. Engel, “Unsupervised Holiday Detection from Low-Resolution Smart Metering Data,” in Proceedings of the 4th International Conference on Information Systems Security and Privacy, ICISSP 2018, 2018, p. 477–486.
  [Bibtex]

  @inproceedings{Eibl18a,
  abstract = {The planned Smart Meter rollout at a large scale has raised privacy concern. In this work for the first time holiday detection from smart metering data is presented. Although holiday detection may seem easier than occupancy detection, it is shown that occupancy detection methods must at least be adapted when used for holiday detection. A new, unsupervised method for holiday detection that applies classification algorithms on a suitable re-formulation of the problem is presented. Several algorithms were applied to a big, realistic smart metering dataset that – compared to existing datasets for occupancy detection – is unique in terms of number of households (869) and measurement duration ({\textgreater}1 year) and has a realistic low time resolution of 15 minutes. This allows for more realistic checks of seemingly plausible but unconfirmed assumptions. This work is merely a first starting point for further research in this area with more research questions raised than answered. While the results of the algorithms look plausible in a visual analysis, testing for data with ground truth is most importantly needed.},
  author = {Eibl, G{\"{u}}nther and Burkhart, Sebastian and Engel, Dominik},
  booktitle = {Proceedings of the 4th International Conference on Information Systems Security and Privacy, ICISSP 2018},
  doi = {10.5220/0006719704770486},
  keywords = {Privacy,Smart Grids,Smart Metering,privacy},
  pages = {477--486},
  publisher = {SciTePress},
  title = {{Unsupervised Holiday Detection from Low-Resolution Smart Metering Data}},
  year = {2018},
  pdf = {http://www.en-trust.at/papers/Eibl18a.pdf},
  }

We are happy to welcome Clemens Brunner to our team. Clemens will support us in our projects using blockchain technology in the energy domain.

Blockchain technology might be a key factor in digitization of energy systems. Therefore, Salzburg AG and Verbund AG are testing practical application areas for blockchains in several pilot projects.

An application is tested in a rental flow project in Köstendorf near Salzburg. Mathias Lackner together with Fabian Knirsch, Andreas Unterweger and Dominik Engel are developing a proof of concept for the distribution of rental flow using a private blockchain.

“Blockchain as a tool for transactions can significantly support the integration of distributed power generators for grid operators. As blockchains are transparent and virtually counterfeit-proof, this technology can play a significant role in energy trading”, Engel says.
This pilot project involves the transfer of electricity subscription rights from individual residents in multi-party buildings were electricity is produced by photovoltaic systems. Blockchain mining is done using a small blockchain calculator directly at the apartment owner respectively the tenant, who can then use blockchain to transfer his share of the generated pv power to other residents if, for example, he needs less electricity during his vacation.

“It’s about increasing self-consumption as part of a rental flow solution,” Salzburg AG CEO Leonhard Schitter explains. In addition to the Center, Grid Singularity GmbH also provides software to this project. Commissioning is planned for the first quarter of 2018 and the results will be evaluated by the end of 2018.
(APA/KarA)

What are the future topics in research? How does the day-to-day work of a researcher look like? Judith Schwarzer recently answered these and other questions asked by curious elementary school pupils at the ‘fti…remixed Speed Dating Event’.

Can houses be made smart power users?
„Yes“, said Judith Schwarzer on this question and explained the technology using a smart home model. For example, electricity can be produced in a house with a solar collector on the roof. At the same time, there are numerous devices that consume electricity, like washing machines, dishwashers or electric cookers, and increasingly more electric cars in the future. Therefore, it is important to find a balance between when the solar collectors reach peak production and when to sensibly charge or use power consumption-heavy devices.
“A smart home makes such decisions supported by information technology. The data that is used for this includes not only the in-house status but also includes information about the surrounding power grid and the amount of available power”, Schwarzer explains. To efficiently use the energy, especially those generated by renewable energy sources, smart grids are required. They can coordinate the production and consumption of electricity as well as possible.

Network specialist and research expert for demand response management
Judith Schwarzer studied physics at the TU Darmstadt and physical education at the German Sport University Cologne. She has been working as an assistant professor and researcher at the ITS degree program of the FH Salzburg for several years. The expert for demand response management at the Center for Secure Energy Informatics specializes in the field of teaching in particular on wireless network technologies.

Picture by: PlanSinn Planung & Kommunikation GmbH

IT security experts of the Salzburg University of Applied Sciences conduct research for a safe access to Salzburg’s Old Town

The access to the old part of Salzburg has been regulated for some time by retractable bollards that are operated by vehicle drivers with access authorization via a manual remote control.
To enable an automated access to the Old Town, which provides higher safety from unauthorized entry, Siemens AG Salzburg commissioned the Center for Secure Energy Informatics at the Information Technology & Systems Management degree program to evaluate possible solutions.

The “Poller Project” was prepared by master student Florian Ramspott and researchers from the center, Michael Fischinger, Norbert Egger and Christian Neureiter; the showcase was presented now.
In the approach of the IT security experts, the vehicle sends data to the bollard system via Bluetooth, the bollard system reads the signal accordingly and authenticates the vehicle. Using demonstrators, Ramspott, Fischinger and Egger showed which data and signals are protected to prevent possible manipulation of the bollards. The system is based on a special software architecture (FREDOSAR), which was developed by the experts of the center for projects in the IOT context. The solution for the safe entry of Salzburg’s Old Town lies in encrypted data transmission with state-of-the-art security levels.

Wolfgang Schneider, Branch Manager of Siemens Salzburg, was pleased that “the project on bollard safety is another successful example of the benefits of research at the Center for Secure Energy Informatics”.

Christian Promper, alumnus of the master course Information Technology & Systems Management, was awarded with the “AK Wissenschaftspreis 2017” for his thesis titled “Anomaly Detection in Smart Grids with Imbalanced Data Methods” supervised by Dominik Engel.
This year’s research question of the Salzburg Chamber of Labor was how to improve the working and living conditions of workers in terms of distributive justice.

Detection of anomalies in Smart Grids
In his thesis, Christian Promper dealt with anomaly detection in Smart Grids. The detection of anomalies plays an important role for the trouble-free future energy supply with Smart Grids.
“Currently there is little experience in smart grid anomaly detection. Since anomalies are rare, the use of common detection methods causes poor detection of anomalies, because the imbalance results in significantly more data items being attributed to common behaviour rather than anomalies within smart grids,” says Promper.
As part of his work, he therefore examined various methods to improve the detection rate for rare irregularities in data sets. In a first step Promper examined various ways to account for imbalanced data in general. In addition, Promper created a three-layer smart grid architecture with intrusion detection systems using imbalanced data methods at each level. This proposed approach outperformed common methods.