![](\"\/wp-content\/uploads\/2026\/01\/RPF-droneincendios-2025-10-info-ING-DESK.png\")
\n <\/picture>The GHG profile generated by the sensor suite and AI engine also offers insights into the overall health of the forest under observation. \u201cA single flyover can tell us whether a reforestation program is being successfully implemented, with seedlings growing as expected, or whether it is a matter of greenwashing\u2014in other words, using sustainability as a marketing ploy rather than for practical outcomes,\u201d Caurin says.<\/p>\n
A new winged version<\/strong> The EESC team opted to outfit the drone with low-cost sensors to measure GHG concentrations. \u201cThey\u2019re not ultra-precise, but they\u2019re affordable and provide a useful signal of gas presence,\u201d the researcher notes. \u201cHigh-precision sensors can cost more than R$100,000. That\u2019s a steep investment for hardware mounted on drones that can crash, break, or simply go missing.\u201d The EESC group demonstrated both the drone platform and the performance of the chosen GHG sensors in a chapter of The Future of Electric Aviation and Artificial Intelligence<\/em>, a book published by Springer Nature earlier this year.<\/p>\n The USP drone was originally developed as a component of a broader data platform for tracking GHG emissions across the Amazon. The project’s coordinator, physicist Paulo Artaxo of USP\u2019s Institute of Physics, notes that current drone endurance remains limited and that sensor accuracy must improve before the system can fully meet the demands of forest monitoring. \u201cDeveloping a domestically built drone for GHG measurements and forest-health diagnostics is an important first step,\u201d Artaxo says. \u201cBut to achieve real operational value, the system would need several improvements, including higher-precision sensors and longer endurance.\u201d<\/p>\n Even so, the technology package developed at S\u00e3o Carlos has already drawn interest from two companies that are negotiating licensing agreements to manufacture the drone. It has also caught the eye of the municipal Civil Defense agency, which has conducted field tests of the system in collaboration with the local Fire Department. \u201cIn wildfire response, drones equipped with gas-sensing instruments are invaluable,\u201d says environmental engineer Pedro Fernando Caballero Campos, who heads Civil Defense operations in S\u00e3o Carlos.<\/p>\n Caballero notes that tracking gas concentrations before, during, and after a fire improves understanding of combustion dynamics and enhances prevention strategies. \u201cIt also lets us study atmospheric gases under varying conditions, and get a clearer picture of air quality and how it affects both human and animal health,\u201d he adds.<\/p>\n Antonio Carlos Duad Filho \/ EESC-USP <\/span>A prototype of the small-class drone developed at USP S\u00e3o CarlosAntonio Carlos Duad Filho \/ EESC-USP <\/span><\/p><\/div>\n Civil defense agencies in several Brazilian states\u2014among them S\u00e3o Paulo and Mato Grosso do Sul\u2014already deploy small-class imported drones for wildfire operations. Their onboard technology packages, however, differ from the system being developed at USP. Some units carry thermal imagers with infrared sensors; others combine thermal and visible-spectrum cameras. Priced between R$50,000 and R$100,000, according to vendors, these drones are used primarily to detect and locate heat signatures and to help guide fire-suppression crews in the field.<\/p>\n Larger, longer-endurance drones are also employed for forest and rural-area surveillance and for early detection of wildfire outbreaks. In Brazil, Xmobots\u2014founded in 2007 by former students of USP\u2019s Polytechnic School with funding from FAPESP\u2014was an early pioneer in supplying drones for wildfire-monitoring missions. Since 2020, the S\u00e3o Carlos\u2013based company has offered a model equipped with a thermal infrared sensor, an optical camera, and a rangefinder for real-time distance measurements.<\/p>\n Mounted on a platform with a full 360-degree field of view, these sensors are supported by an AI system capable of facial recognition and license-plate identification. This allows the drone to help identify individuals or vehicles potentially involved in unlawful activities. Beyond environmental monitoring and wildfire detection, the aircraft is also deployed for surveillance missions.<\/p>\n The drone is a winged VTOL system measuring 1.86 meters long with a 3.64-meter wingspan, developed as part of the company\u2019s Nauru drone family. With a four-hour endurance and a 60-kilometer operational radius, it can reach altitudes of up to 3,000 meters. \u201cIt\u2019s the only drone in Brazil authorized by ANAC\u2014our national civil aviation authority\u2014to operate above 400 feet (about 192 m) and to fly at night,\u201d says commercial director Thatiana Miloso.<\/p>\n The Nauru 500C is used primarily to patrol public areas, commercial forest plantations, and agricultural operations. According to Xmobots, citing data from the Brazilian Confederation of Agriculture and Livestock (CNA), wildfires inflicted roughly R$14.6 billion in losses on Brazil\u2019s agribusiness sector between June and August 2024. Xmobots is now working on an upgraded version of the drone. \u201cWe\u2019re enhancing the system\u2019s performance by adding environmental and gas-analysis sensors,\u201d says electrical engineer Leonardo Gomes, a project manager at the company.<\/p>\n Xmobots <\/span>Xmobots\u2019s NauruC model used for environmental monitoring and wildfire detectionXmobots <\/span><\/p><\/div>\n Water-and foam-jet capability<\/strong> The system lifts a hose roughly 6 centimeters in diameter to heights of up to 30 m and can project a precision stream of water or foam out to 25 m. The hose remains connected at ground level to a fire engine or hydrant, ensuring continuous flow. The drone also carries a thermal imager and a virtual reality sensor, giving operators a real-time field of view.<\/p>\n The first two UAVI100 units were delivered in May to the Manaus Fire Department. \u201cOur drone has already seen action in real fire-suppression operations. Three additional units are on order,\u201d says UAVI\u2019s managing director Ricardo Pietro. \u201cFire departments in Paran\u00e1, Goi\u00e1s, and Mato Grosso have also placed orders, and we\u2019ve already received inquiries from as far away as Portugal,\u201d he adds.<\/p>\n The drones are used mainly for urban firefighting along forest edges and buffer zones. New versions are under development, including models with nozzle-control systems and payload modules designed to carry chemical fire suppressant or silica-fabric fire blankets. \u201cOur R&D team collaborates closely with fire-service personnel to deliver equipment tailored to users\u2019 different needs,\u201d Pietro notes.<\/p>\n The story above was published with the title “Firefighting drones<\/strong>” in issue 356 of October\/2025.<\/p>\n Projects
\nThe USP team is now developing a new, second-generation model. Alongside the rotors that enable vertical takeoff and landing, the new design will incorporate fixed wings, significantly reducing the energy required for horizontal flight. The upgraded drone is expected to stay aloft for nearly an hour, double the endurance of the current prototype. \u201cTo survey large areas effectively, we’re aiming for even greater endurance\u2014on the order of 90 to 120 minutes,\u201d Caurin explains. He adds that covering vast landscapes will ultimately require a coordinated fleet of drones.<\/p>\n![\"\"](\"https:\/\/revistapesquisa.fapesp.br\/wp-content\/uploads\/2026\/01\/RPF-drone-incendio-usp-2025-10-800.jpg\")
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\nDrones are also being used for direct fire suppression. Leading the way in Brazil is the UAVI100 \u201cFirefighter,\u201d launched this year by UAVI, a company based in S\u00e3o Jos\u00e9 dos Campos\u2019s Science Park. The aircraft features eight motors, two batteries, a 20-minute endurance window, and a payload capacity of 150 kilograms.<\/p>\n
\n1.<\/strong> CEPOF \u2013 Optics and Photonics Research Center (n\u00b0 13\/07276-1<\/a>); Grant Mechanism<\/strong> Research, Innovation, and Dissemination Centers (RIDCs); Principal Investigator<\/strong> Vanderlei Salvador Bagnato (IFSC-USP); Investment<\/strong> R$51,786,666.96.
\n2.<\/strong> Research and Innovation Center for Greenhouse Gases \u2013 RCG2I (n\u00b0 20\/15230-5<\/a>); Grant Mechanism<\/strong> Engineering Research Centers (CPEs); Agreement<\/strong> BG E&P Brasil (Shell Group); Principal Investigator<\/strong> Julio Romano Meneghini (USP); Investment<\/strong> R$25,376,639.63.
\n3.<\/strong> Design of a certifiable avionics system for unmanned aerial vehicles (UAVs) for civil applications (n\u00b0 13\/50946-8<\/a>); Grant Mechanism<\/strong> Innovative Research in Small Businesses (PIPE); Agreement<\/strong> FINEP PIPE\/PAPPE Subsidy; Principal Investigator<\/strong> Giovani Amianti (Xmobots); Investment<\/strong> R$876,283.32.<\/p>\n