New radar system could lead to better defences against avalanches

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Photo of avalanche on a snowy mountain-side against a blue sky

An artificially triggered avalanche thunders down a mountain side at the Vallee de la Sionne in Anzere near Sion, February 2015

Denis Balibouse/Reuters

A new radar-based imaging system with an unprecedented ability to penetrate snow-powder clouds could lead to greater avalanche protection for towns, buildings, roads and railways.

Successfully installed and tested in the Swiss Alps last winter, the system produces 3D images that reveal how snow flows deep inside avalanches. This new data will strengthen computer models that are used not only to understand the behaviour of avalanches but also to pinpoint ways of building better defences against them.

Funded by the Engineering and Physical Sciences Research Council (EPSRC), the Advanced MIMO Radar Development for Geophysical Imaging Applications system was developed by a team from University College London (UCL), Durham University and Sheffield University, working in close collaboration with the Swiss Federal Institute for Snow and Avalanche Research (SLF).

Project leader Professor Paul Brennan, of UCL, says: It's not possible to predict precisely when avalanches will happen, but our radar imaging system aids understanding of how they behave when they do occur. By penetrating the powder cloud, it can observe the nature and direction of the flow of the 90 per cent of snow that would otherwise remain invisible.

As well as killing more than 150 people worldwide each year, avalanches cause substantial damage and disruption. A range of anti-avalanche protection measures are available, from snow fences, nets, dams and barriers to tree-planting, reinforcement of buildings and the laying out of towns and villages to minimise damage. These measures can all be expensive, however, with the cost of safeguarding one hectare estimated to be around £750,000.

The insights into avalanche behaviour produced by the new imaging system could ultimately help SLF refine such measures so that they deliver better, more cost-effective protection. Working on the classic 'echo sounder' principle that has underpinned radar ever since its invention in the early 20th century, the system uses an antenna to transmit radio waves and a 1.95 metre receiver array to capture them as they reflect back from the snow.

The power and wavelength of the radio waves maximise their ability to penetrate into the snow as it moves. The system, which has a 30° field of view providing full coverage of an avalanche track, offers greater sensitivity and higher resolution images than any other similar system previously developed. It can work autonomously or can be operated manually over a Virtual Private Network.

The project has interacted closely with research led by British Antarctic Survey (BAS) and funded by the Natural Environment Research Council (NERC) that has used radar to measure and monitor, with millimetre precision, the melt rates of Antarctic ice shelves - key to understanding how sea levels may rise in future in response to climate change.

Professor Brennan comments: Two members of our team spent two months in Antarctica working with BAS, which was invaluable in informing development of our imaging system. Our system is an excellent scientific research tool generating real-world field data that SLF can put to productive and potentially life-and money-saving use in the years ahead.

- Ends -

Notes for Editors:

The three-year project Advanced MIMO Radar Development for Geophysical Imaging Applications began in March 2013 and ended in March 2016, receiving a total of just over £305,000 in EPSRC funding. Funding was also provided by the Swiss National Science Foundation as part of its High Resolution Radar Imaging of Snow Avalanches project.

Links of relevance

NERC-funded BAS-led project

This has produced the first-ever year-long record of ice melt on West Antarctica's Pine Island Glacier to be generated by a ground-based echo sounder.

The Engineering and Physical Sciences Research Council (EPSRC)

As the main funding agency for engineering and physical sciences research, our vision is for the UK to be the best place in the world to Research, Discover and Innovate. By investing £800 million a year in research and postgraduate training, we are building the knowledge and skills base needed to address the scientific and technological challenges facing the nation. Our portfolio covers a vast range of fields from healthcare technologies to structural engineering, manufacturing to mathematics, advanced materials to chemistry. The research we fund has impact across all sectors. It provides a platform for future economic development in the UK and improvements for everyone's health, lifestyle and culture. We work collectively with our partners and other Research Councils on issues of common concern via UK Research and Innovation.

University College London

University College London was founded in 1826. It was the first English University established after Oxford and Cambridge, the first to open up university education to those previously excluded from it, and the first to provide systematic teaching of law, architecture and medicine. UCL is among the world's top universities, as reflected by performance in a range of international rankings and tables. UCL currently has over 35,000 students from 150 countries and over 11,000 staff. Annual income is more than £11 billion.

Reference: PN 46-16

Contact Details

In the following table, contact information relevant to the page. The first column is for visual reference only. Data is in the right column.

Name: Professor Paul Brennan
Department: Department of Electronic and Electrical Engineering
Organisation: University College London
Telephone: +44 20 7679 3191

In the following table, contact information relevant to the page. The first column is for visual reference only. Data is in the right column.

Name: EPSRC Press Office
Telephone: 01793 444404

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