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World of Science | CADS - Camera-based Avalanche Detection System

Avalanche detection using artificial intelligence

by Anna Siebenbrunner 02/17/2024
Artificial intelligence (AI) has been on everyone's lips since the release of ChatGPT. AI is also increasingly being used in the field of avalanche warning and research. One current example is the CADS (Camera-based Avalanche Detection System) project, in which researchers from the Department of Computer Science at the University of Innsbruck have developed a model for recognising avalanches on webcam images together with Lo.La Peak Solutions GmbH.

The importance of avalanche detection

The avalanche danger level is determined using the EAWS matrix: The parameters of avalanche size, frequency and snowpack stability significantly determine the avalanche danger level. Information about "fresh" avalanches is therefore essential for assessing the avalanche danger and therefore also for compiling the avalanche situation report. In recent years, webcams have become increasingly established as a practical tool for avalanche warning. After all, fresh avalanches are a valuable indicator of generally high avalanche activity. Such avalanches and other valuable information such as type, number and size can be recognised via webcam images.

Until now, however, avalanche warning officers have had to click through the various webcam positions themselves. It therefore makes sense to outsource and automate this comparatively dull and time-consuming task. In future, artificial intelligence will be used to recognise fresh avalanches in almost real time (webcam update interval) and thus support decision-makers in their daily work.

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How an AI learns to recognise avalanches

So how do you teach an AI to detect avalanches? The answer is: data, data, data. An AI can only do what you teach it. In this specific case of use, this means that you have to "show" the model a lot of photos of avalanches. Of course, you also have to show the AI photos that do not show an avalanche, as this is the only way it can learn to differentiate between them. If the training were to be carried out exclusively or predominantly with avalanche photos, the model would have a strong bias, i.e. it would tend to recognise an avalanche even if none could be seen. A total of 4090 photos were used for the CADS project, on which a total of 7228 individual avalanches could be identified. The photos used in the project were largely provided by the Avalanche Warning Service Tyrol and were mainly taken in the German-speaking Alpine region, primarily in Tyrol. Data augmentation techniques were used in the training process, e.g. colour variations and random horizontal reflections, to improve the generalisation of the model.

The avalanche photos used in the research project had to be "labelled" before the actual training could begin. On the one hand, a polygon had to be drawn around the avalanche outline, and on the other hand, a label had to be assigned to the image. This label referred to the type of avalanche, i.e. slab avalanche, sliding snow avalanche or loose snow avalanche. This form of labelling seemed to make the most sense, as the three avalanche types differ in their visual characteristics. For example, the snow slab avalanche is characterised by a striking linear avalanche edge, while gliding snow avalanches reveal the subsurface and loose snow avalanches are characterised by a punctiform avalanche edge and a pear-shaped runout. In this way, the model can be taught not only to detect avalanches in general, but also to differentiate between the individual avalanche types. With the help of these "annotations", training can now begin. Existing deep learning models, such as the object recognition model YOLO (v5), were used to speed up the process.

How well does the model actually work?

Of the labelled photos, a proportion (10%) was retained from the training. This pool of photos was later used to validate the model performance. In the course of validation, the avalanches detected by the model and their bounding boxes were compared with those of the test set. The results of the validation in this "test set" were extremely pleasing: a high detection rate was achieved and the rate of "overlooked" avalanches - so-called false negatives - was kept low. This is important for a possible practical application in the future, as overlooked avalanche events can sometimes have serious consequences if, for example, the rescue chain is not set in motion in time in the event of an avalanche involving people or if safety measures are initiated too late in the case of alpine infrastructure (e.g. road closures). The consequences of false positives, i.e. when an avalanche detection is reported even though no avalanche has occurred, are not as serious. Nevertheless, such false alarms are annoying. So it is all the better that this figure has also been kept low. For the first phase of practical implementation, it seems sensible for the model's decision - "avalanche" or "no avalanche" - to be additionally checked by domain experts. In the event of an incorrect classification, the corresponding photo can be correctly labelled and added to the training data set in order to continuously improve the model quality.

Initial practical tests together with the Avalanche Warning Service Tyrol brought further exciting findings. In the initial phase, for example, the model reported groomed ski slopes as slab avalanches or suspected sliding snow avalanches behind wooden huts and rocky areas. At first glance, there may be a visual similarity - at least for the AI. The problem was quickly solved by adding images containing slopes, huts or rocks to the training data set. Poor visibility - due to fog, for example - clearly also makes it impossible to recognise avalanches.

What does the future hold?

Whether the model developed will prove useful in the future depends on several factors from today's perspective. For example, the number of webcams in the Alpine region can still be expanded. There is also room for improvement in the positioning of the webcams. At present, most webcams are set up for tourist purposes and therefore tend to show tourist attractions rather than avalanche slopes.


CADS is a project in which researchers from the Informatics Institute of the University of Innsbruck together with Lo.La Peak Solutions GmbH have developed a model for recognising avalanches on webcam images. You can find more information on this topic at

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