What drones may come: The future of unmanned flight approaches
The once-small community of drone hobbyists has transformed into a worldwide phenomenon. In 2016 especially, significant technology improvements and regulatory clarity have paved the way for even more dramatic changes in the coming years.
Among the biggest adopters of drones, and experimenters with them, have been universities. As the director of the University of California system’s Center of Excellence on Unmanned Aircraft System Safety– effectively the drone headquarters of our whole 10-campus system– I have an excellent view of the drone industry’s past, present and future.
The truly surprising details are about how wide and diverse a range of purposes drones are serving on our campuses– and what’s coming next. As we begin exploring what drones can do, and identifying what commercial and social uses they might serve, the work provides a glimpse into the future of drone flight across the country, and throughout our economy.
Drones have only recently reached the commercial mainstream. However, university engineering departments have been designing and building them for decades. For years, engineering students, for instance, have studied the advanced control algorithms that keep drones flying level and straight. Their work has helped bring us to the point where drones are even available for sale in toy stores.
It is no surprise that our engineers are still working on drones and related technology such as sensors, automation and innovative platforms. Some introductory engineering classes involve students building and flying drones; more advanced students learn about flight dynamics and algorithms that help drones stay aloft.
In recent years, though, our engineering departments are focusing less on building the aircraft and more on improving ability, safety and navigation to carry equipment that allows drones to help with different tasks.
Researchers are developing navigation systems that don’t rely on GPS satellites. This could help allow drones to navigate autonomously inside buildings, in deep canyons, underground or other places where GPS signals are unavailable or unreliable. Whether delivering packages to remote locations or handling emergency tasks in hazardous conditions, this type of capability could significantly expand drones’ usefulness.
Another research group is working on ways for drones to help detect gas leaks from oil pipelines. With millions of miles of pipelines across the country, that is a monumental task. Attaching methane-sniffing sensors to drones could make it much easier: Autonomous drones could fly the routes of every pipeline nearly constantly, registering the location and volume of leaks, and alerting repair and cleanup crews.
Growth in agriculture and environmental work
Our largest use of drones has been out in the fields. Two-thirds of the UC system’s drone flights, which encompass thousands of flights and hundreds of flight hours, have been for agricultural and environmental research. This suggests that those areas could provide breakout opportunities for drone uses.
Some scholars have found many ways drones can replace existing manned aircraft, like with a pesticide-spraying helicopter that could reduce time and costs and provide safer operations. The biggest factor has been how easy drones make it to collect data that were extremely difficult, or even impossible, to collect before.
For example, drones with special thermal cameras are allowing researchers to investigate water consumption rates of several varieties of crops in the Sacramento-San Joaquin Delta. The drones’ data collection is so detailed that the scholars can count individual melons, allowing much better estimates of crop yield. When farmers know much more precisely how big the harvest will be, they can better estimate how much money they’ll make– and can make better budget decisions with the information.
Drones are also proving themselves useful in high-resolution aerial coastal survey mapping. With drones, they’re able to collect data more frequently with greater detail, and do a better job mapping and analyzing environmental data. That helps improve our understanding of coastal ecology, and prepares local residents and communities for possible disasters because the drones are able to get closer to certain environments which scientists will be able extract more information from.
When monitoring giant sequoias, a team of five to seven people would have to map the area, which would take about a week. A drone flight has been able to replace that work with a two-minute flight. That makes it easier to track how the trees are responding and growing to changes in their environment.
Beyond the academic realm
To meet the demand from people with no experience in drone technology, we have developed special workshops for students, faculty, staff and uc research partners to learn about drone technology, regulations and flight instruction.
Campus film and media departments regularly use drones to make sweeping images of our scenic campus locations for promotional videos and reports. Beyond that, though, university facilities workers have been using drones to monitor construction sites, inspect building areas that are hard to get to (like roofs) and keep an eye on the university’s sizable landholdings. All of these uses can significantly improve worker cost, productivity and safety savings.
Students are also using drones recreationally, which has raised safety and privacy concerns on our campuses, just as it has off-campus. With plenty of green spaces, many students want to fly their drones and other model aircraft on campus, even near dorms or other housing.
This sort of just-for-fun experimentation can make it challenging to regulate drone flights based on what the drone is doing. Universities are often test locations for new technologies. Our work– both recreational and formal– encourages creativity and can foster an entrepreneurial spirit. We can expect that at least some of these early uses for drones will eventually spill into the commercial and consumer markets.