A team of researchers from the Universitat Oberta de Catalunya (UOC) has designed and tested a new system for detecting asbestos that has not yet been removed from the roofs of buildings, despite regulatory requirements. The software, developed in partnership with DetectA, applies artificial intelligence, deep learning and computer vision methods to aerial photographs, using RGB images, which are the most common and economical type. This represents a very important competitive advantage over previous attempts to create a similar system, which required multiband images that are more complex and difficult to obtain. The success of this much more scalable project will allow the removal of this highly toxic building material to be more systematically and effectively monitored.
"Unlike infrared or hyperspectral imaging methods, our decision to train AI with RGB images ensures the methodology is versatile and adaptable. In Europe and many other countries around the world this type of aerial imaging is freely available in very high resolutions," explained Javier Borge Holthoefer, lead researcher of the Complex Systems group (CoSIN3) at the Internet Interdisciplinary Institute (IN3). Borge Holthoefer is leading this research, together with Àgata Lapedriza, researcher with the eHealth Center's Artificial Intelligence for Human Well-being group (AIWELL) and a member of the UOC's Faculty of Computer Science, Multimedia and Telecommunications. Their research has been published as open access in Remote Sensing. UOC doctoral students Davoud Omarzadeh, Adonis González-Godoy, Cristina Bustos and Kevin Martín Fernández also contributed to the project, together with the founders of DetectA, Carles Scotto and César Sánchez.
The researchers trained the deep learning system using thousands of photographs held by the Cartographic and Geological Institute of Catalonia, teaching the AI tool which roofs contain asbestos and which do not. 2,244 images were used (1,168 positive for asbestos and 1,076 negative). 80% were used to train and validate the system, with the remaining images reserved for the final test. The software is now able to determine if asbestos is present in new images by assessing different patterns, such as the colour, texture and structure of the roofs, as well as the area surrounding the buildings. The project will be useful in urban, industrial, coastal and rural areas. By law, municipalities should have performed a survey of buildings containing asbestos by April 2023, but not all of them have yet done so.
Hyperspectral photographs make it easier to detect asbestos, because they contain many more layers of information, but they are not ideal for developing an efficient detection method, due to their limited availability and the high cost of obtaining them. The system developed by the UOC researchers is the first to use RGB images, which can be taken from aircraft and are commonly used by many countries' cartographic services. "Although these images contain less information, we have achieved comparable results by training the deep learning system well, with a success rate of over 80%," explained the CoSIN3 researcher.
Banned for over two decades
More than twenty years after its use in construction was banned, asbestos remains a major public health problem. It is estimated that, in Catalonia alone, over four million tonnes of asbestos fibre cement is still in place. According to the World Health Organization it causes more than 100,000 deaths a year globally, mainly from lung cancer, but also other conditions including pleural tumours and pulmonary fibrosis. The legal target for removing asbestos from public buildings is 2028 and the target for private buildings is 2032.
The development of this technological solution will contribute to tackling one of the key issues in the fight against asbestos: how authorities can identify which roofs contain asbestos, so it can be removed by qualified, accredited professionals. "There is currently no protocol or effective system for locating the asbestos that is still out there, because it is expensive and time-consuming to inventorize using people on the ground," said Borge Holthoefer.
Now his team is looking into expanding the AI system training base in order to make it as effective in rural environments as it is in urban and industrial locations, where it is a little more reliable because the system was trained with more data from these areas, and also because asbestos wear and conservation is different in rural conditions, and it may be covered by layers of vegetation.
This research project contributes to the UN's Sustainable Development Goals (SDGs) 3 (Good Health and Well-being), 9 (Industry, Innovation and Infrastructure) and 11 (Sustainable Cities and Communities).
UOC R&I
The UOC's research and innovation (R&I) is helping overcome pressing challenges faced by global societies in the 21st century by studying interactions between technology and human & social sciences with a specific focus on the network society, e-learning and e-health.
Over 500 researchers and more than 50 research groups work in the UOC's seven faculties, its eLearning Research programme and its two research centres: the Internet Interdisciplinary Institute (IN3) and the eHealth Center (eHC).
The university also develops online learning innovations at its eLearning Innovation Center (eLinC), as well as UOC community entrepreneurship and knowledge transfer via the Hubbik platform.
Open knowledge and the goals of the United Nations 2030 Agenda for Sustainable Development serve as strategic pillars for the UOC's teaching, research and innovation. More information: research.uoc.edu.
