The use of privacy-sensitive data has an enormous potential to help improve society. Examples include new insights that help us with the energy transition or our health. However, you cannot use these data without the permission of citizens or companies, not even if it would benefit them. Fortunately, there is a privacy-friendly way to solve that problem in certain cases: Federated Learning.
How Federated Learning works
WHAT IS FEDERATED LEARNING?
Federated Learning is a decentralised and privacy-friendly form of machine learning. This means that there is no need for a central database to hold all of the sensitive data, so these data cannot be leaked. Instead of bringing the data to the machine learning model, Federated Learning brings the machine learning model to the data.
In this way, the training of the models is broken down into sub-calculations that are performed locally at an organisation. After carrying out the calculations, only the anonymised (intermediate) results are shared with the organisations conducting the research, not the privacy-sensitive data itself.
Federated Learning solves two major problems of data analysis: improved qualitative analyses for society and safeguarding of citizens’ rights in relation to privacy.
These days, analysing large amounts of data is easier than ever before. Computing power is increasing and algorithms are becoming ever more advanced. Although more and more data is available for valuable analyses, there are an increasing number of societal objections to the use of sensitive data.
WHAT CAN ORGANISATIONS GAIN FROM FEDERATED LEARNING?
Federated Learning allows you to harness data without violating privacy. The amount of available data is greater as you can analyse data from multiple databases. In turn, the results of a study are more reliable. This means better predictions and better models, leading to much more informed (policy) decisions.
An example? Take cancer research. With Federated Learning, you can analyse anonymised data on things like successful treatment methods for each type of cancer in different people across all hospitals without violating patient privacy.
WHAT DOES TNO DO IN THE FIELD OF FEDERATED LEARNING AND HOW CAN YOU WORK WITH TNO?
HELPING TO PREVENT DIABETES
No less than 8.5% of the world’s population has diabetes, 90% of which is Type 2. This is particularly distressing as it can often be prevented by different lifestyle choices, for example.
How can machine learning (ML) help? By identifying risk groups and warning them as early as possible, i.e. before Type 2 develops. To do that, the ML model needs to be trained as well as possible on a large number of people with different lifestyles and medical conditions in multiple age groups.
To do this properly, you need many different data sources from healthcare institutions. However, medical data is so well protected under the GDPR that sharing is almost impossible – let alone storing all that sensitive data in a central database to run models on it.
HOW FEDERATED LEARNING CONTRIBUTES
TNO has collaborated with the organisation Lifelines to create a Federated Logistic Regression model to predict the emergence of Type 2 diabetes for people aged between two and eleven. Via Lifelines, data from 167,000 people in the Netherlands were analysed in a privacy-friendly manner.
The data comes from various sources, including data from proteins tested in the lab and surveys of people regarding their lifestyle. This resulted in a Federated Learning model that works almost as well as a globally trained model. The results are promising and justify further research.
PREDICTING A NEIGHBOURHOOD’S ENERGY DEMAND
The energy transition is already a huge topic and will only grow larger in the coming years. An important issue is predicting energy demand in order to match supply and demand.
You have to know how much grid capacity is needed in order to be able to deliver a supply that matches the energy demand, preferably per neighbourhood so that smart supply can be implemented. But requesting your energy consumption is difficult. It can cause privacy issues, like a third party may know when you are not at home.
HOW FEDERATED LEARNING CONTRIBUTES
Together with partners likeStrukton, TNO has been working on a model for predicting a neighbourhood’senergydemand.This is done in a privacy-friendly manner using Federated Learning. This means that the personal data of households do not have to be viewed by researchers or stored at a central location, thereby preventing loss of privacy.
Instead, the energy demand per neighbourhood can now be analysed and predicted in a privacy-friendly manner. On this basis, it can be determined how much capacity is needed. What a result!With the help of FL, the energy demand of a neighbourhood can be predicted without violating the privacy of citizens and with the aim of guaranteeing a stable electricity supply.
GETTING STARTED WITH PRIVACY-FRIENDLY DATA
Wondering how you can join us in using Federated Learning to harness data in a privacy-friendly way? Please get in touch.
How you can harness data in a privacy-friendly way
Envision it: better treatment methods for patients by learning from the successes and failures of doctors and pharmaceutical companies. Detecting money laundering activities by bringing together data from...
Privacy by design: combining data for better government services
The government works with a great deal of data from citizens and businesses. It has a legal duty to carefully secure these data in order to protect everyone’s privacy, but the government is also always...
MPC as a fraud detection and anti-money laundering (AML) tool
Fraud, money laundering and other financial and economic crimes are difficult to combat. Every year, millions of citizens and thousands of businesses in the EU fall victim to fraud. Money laundering is also how...
TNO.nl collects and processes data in accordance with the applicable privacy regulations for an optimal user experience and marketing practices. This data can easily be removed from your temporary profile page at any time. You can also view our privacy statement or cookie statement.