Volcano-monitoring Ultraviolet PiCam

By Rosemary Hattersley. Posted

Iceland is currently on standby for imminent eruptions, while Sicily’s Mount Etna gave off stunning emissions in late summer. However, most volcanic activity takes place in lesser-known, less touristy and often poorer nations, where preparations for a big blowout are far harder to facilitate. Furthermore, their remote locations can make installing equipment to track seismic activity an expensive challenge.

“UV cameras provide invaluable data for both monitoring and research,” explains University of Sheffield volcanologist Dr Thomas Wilkes, “but funding in volcanology, particularly for monitoring organisations, is often limited, prohibiting their widespread adoption.” For his PhD thesis, Tom set about designing low-cost ground-based remote sensing instruments using Raspberry Pi 3B+, having initially been attracted by the £20 Camera Module after a tip-off from a colleague (also called Tom). He read up on all things Raspberry Pi using our forums and online resources and was able to publish both his research paper and set up his first sulphur dioxide monitoring camera in 2016. Two images are taken – one in which UV light is absorbed and one where it isn’t. Overlaying the images reveals where sulphur dioxide – a corrosive, acidic gas –  is being emitted and in what quantity.

The two Toms continue to work together and are both members of Sheffield-based VolcanoTech. They aim to get more instruments onto volcanoes and acquire unprecedented long-term datasets that contribute to volcano research and monitoring. Designing and constructing low-cost scientific instrumentation is crucial for developing countries, where funding for equipment can be quite limited but where many of the world’s active volcanoes are located.

This fully enclosed, Raspberry Pi 3B-based volcano monitoring system can be deployed in remote locations

Tell-tale signs

A volcano’s degassing behaviour changes before an eruption, often increasing or decreasing. Since sulphur dioxide is the gas most prevalent at active volcano sites, Tom focused on monitoring this using a UV camera. There were already scientific-grade UV cameras in the field in some locations, but they cost tens of thousands of pounds, whereas Tom aimed to develop a UV camera “an order of magnitude cheaper” and much smaller, making it suitable for permanent installation and remote reporting. Monitoring volcanoes often involves tracking how sulphur dioxide diverges from a baseline and then investigating those changes. Tom’s system uses the Beer-Lambert law of absorption, comparing the optical depth of plume pixels in an image to the background sky radiance.

The sulphur dioxide volcano-monitoring kits have a 28 × 21 in field of view with optical depths calibrated by a co-aligned spectrometer

Tom and his colleagues didn’t know much about Raspberry Pi at the outset, “which made the detailed knowledge and wealth of experimentation by others invaluable when it came to asking specific questions or pulling ideas from pre-existing threads.” A particularly fruitful discovery was a YouTube video by Les Wright which simplified the process of removing the Bayer filter from the camera lens to enhance its sensitivity to ultraviolet light. This worked well for a Raspberry Pi Camera 1.3, but Tom reports that he was unable to remove the Bayer filter in the same way for the newer Raspberry Pi Camera Module. The process in any case requires a fume cupboard and dangerous chemicals (see ‘Warning’ box). Tom originally made use of the UV camera in a spectrometer he used for sulphur dioxide monitoring. Although this worked well, he subsequently decided to focus on the camera-based system.

How predictable

Having created an affordable alternative to the £10,000 scientific cameras, Tom has been working on modifying the camera design so they can be deployed permanently on volcanoes, without the need for human interaction. To date, only Stromboli in the Aeolian Islands, and Etna just to the south, have fixed monitoring. “We are now beginning to build high time-resolution sulphur dioxide emission rate datasets from several volcanoes, the likes of which are quite rare in volcanology,” he says.

Optical depth image captured at Lascar volcano near Buenos Aires with a control rectangle of clear sky

Getting the cameras installed on hazardous volcanoes is no mean feat! Using a Starlink satellite connection has helped them overcome the major issue of handling and processing the terabytes of data each camera acquires each year, as well as partially solving issues relating to debugging camera installations remotely. With cameras in the Amazon rainforest as well as the Atacama desert, temperature extremes and huge amounts of rainfall add to the challenges. However, once in place, they’ll give volcanologists significantly improved monitoring capabilities that contribute to longer-term volcanological research – an increasingly critical aspect of their work “since a volcano can exhibit significant changes in activity over a wide range of time scales.

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