By Mark Henderson
Special to Marketing and Communications
A small unmanned aircraft with multiple propellers flies over a privately owned farm near Sterlington. Suddenly, it hovers feet above a field of soybeans.
Its mission: To capture vital information concerning the health of the crop.
For three years, two University of Louisiana Monroe faculty members have flown drones over the same piece of property.
One, a geographer, conducts research. The other, an aviator, puts his years of flight experience, many in the Air Force, to use operating and teaching the new technology. Together they have blazed a trail that holds benefits for both farmers in the field and students in the classroom.
The work of Dr. Paul Karlowitz, associate professor of aviation, and Dr. Sean Chenoweth, assistant professor of geosciences, is yielding information that would empower growers to practice precision agriculture, saving them time and money.
The size of the average farm has grown through the years. It鈥檚 difficult, Chenoweth says, for farmers to know exactly what鈥檚 happening on all the acreage at any one time.
Farmers often choose the easiest route and treat all of their land with fertilizer and chemicals.
The problems, however, usually are isolated 鈥 weeds over here, too much water over there. The alternative to expensive blanket treatment has been walking the rows of crops looking for problems 鈥 an inefficient use of time.
Chenoweth鈥檚 research proposes answers.
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Eye in the sky
Chenoweth uses an assortment of cameras attached to the drones to determine the health of the crop. One of the cameras reads infrared reflection.
鈥淵ou can see a vegetation鈥檚 health,鈥 Chenoweth said. 鈥淗ealthy plants let off more infrared radiation, pinpointing where in the field crops may be suffering.鈥
When data from the camera is downloaded on computer, darker areas of the field indicate healthier plants.
鈥淚f there鈥檚 a problem with a crop, the reduced radiation given off can provide a warning two weeks before the eye can detect it,鈥 Chenoweth said.
Another camera, which measures heat, can help a farmer determine the wetness of the soil across his fields, allowing him to make precision decisions on questions of irrigation.
Isolate the problems, save time and money.
Once, Karlowitz used a quad-propeller drone, flying on a late afternoon, to locate 20 to 30 feral hogs bedding down in a farmer鈥檚 field. The hogs had eaten several acres of corn. The drone told the farmer exactly where to find the hogs.
Recently, 不良研究所 added a hyperspectral camera to its arsenal. The camera attached to the eight-propeller drone can provide so much data, Chenoweth says, that it 鈥渢akes hours to download.鈥
A seven-minute flight can provide 60 gigabytes of data, Karlowitz said.
This new camera can differentiate species of plants.
鈥淓ach plant has a reflective signature, like a fingerprint,鈥 Chenoweth says. 鈥淵ou can tell the sex of trees, and what specie of tree you have.鈥
The technology can also help farmers determine where they might have weed issues, Karlowitz says.
鈥淧igweed is hard to kill. Hyperspectral data can pinpoint where that pigweed is in the field,鈥 Karlowitz says. 鈥淭hat cuts down costs and time because the farmer doesn鈥檛 have to treat his entire acreage.鈥澨
The technology also could prove valuable to law enforcement, Karlowitz says. A drone can fly over a field where police might suspect marijuana is being grown among other crops, and the reflective signature can spot it quickly.
Chenoweth is using the information gathered by the numerous drone flights for long-term research. He鈥檚 studying how short-term atmospheric conditions affect the field with an eye toward climate change.
He now has three years of data available from that soybean field near Sterlington, but with each generation of technology, the data at his fingertips expands. Over time he鈥檒l be able to compare weather conditions of one year to another, and how that played out in the field.
Although the research points to how the technology can guide farmers to do their jobs more efficiently, Chenoweth says drones have not been put to use yet in northeastern Louisiana for many reasons.
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On the cutting edge
The biggest hurdle is money, Karlowitz says. A farmer would have to invest in at least one drone, the cameras, software programs, a powerful computer and drone insurance.
鈥淎 farmer wants to know what鈥檚 the average cost per acre, but that information just does not exist yet,鈥 he says.
Drones could not be put to commercial use until just recently, when the Federal Aviation Administration released its rules governing their use. Previously, drone operators had to have a pilot鈥檚 license and file flight plans, so when Chenoweth needed to gather research, he relied on Karlowitz to operate the drone. Under the new rules, the FAA created a special license classification for drone operators, known as a Part 107 license. Because the rules are so new, there has not been sufficient time for many to study and take the exam.
The test consists of 60 questions drawn from a manual of 600 questions and answers covering such things as rules of restricted airspace. It costs $150 to take the test.
鈥淢ost farmers don鈥檛 want to study to take such a test, there鈥檚 no time,鈥 says Chenoweth, who recently received his license and can fly the drone on his own now. The same is true about learning the ever-sophisticated software to optimize the use of data.
听Karlowitz adds that the license only indicates you know the rules governing drone usage. A person can earn a license without ever having flown a drone. Flight training is additional cost and effort.
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Embracing the coming wave
What might be cost prohibitive for individual farmers, however, provides opportunity for 不良研究所 students.
With the FAA releasing drones to commercial use, 不良研究所 is hoping to claim its niche in the emerging technology. Currently, 不良研究所 offers a concentration on drones within its general aviation program. In the fall, the university will offer a degree in Unmanned Aircraft Systems Management.听
For 不良研究所 students, they will have an advantage in the market because large universities are just getting into the field, Karlowitz says.听
Karlowitz sees the day a 不良研究所 graduate can invest in the technology and contract with many farmers to provide the service, recovering costs through many clients.
Although 不良研究所 has invested much effort in using drones for agricultural research, and those efforts will provide opportunities to train UASM students in flying drones, the potential uses go far beyond Chenoweth鈥檚 research, Karlowitz said. Among the possibilities:
鈥淥ne of our graduates who has his FAA drone license was hired by Dow Chemical. They said he had all of the skills they were looking for,鈥 Karlowitz says.
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Growing exposure
The research efforts also are being incorporated into 不良研究所鈥檚 agribusiness studies.
Dr. Zach Moore, director of 不良研究所鈥檚 agribusiness program within the College of Business, says students are required to take a class on how the drones are being used by Chenoweth and Karlowitz.
鈥淲e have a little motto we developed here. Put business in agribusiness. We want our students to be exposed to the precision technology. They take the course so that they know what the technology can do for you,鈥 Moore said.听
鈥淚t鈥檚 a managerial tool, and we expect the students to use the information to make good decisions, how it can lower the cost by using prescriptive rather than blanket methods.鈥
Moore says about 30 percent of the agribusiness students will go back to the family farm. The others intend to use their agribusiness degree to enter banking, real estate or commodities trading. They will still be introduced to the drones and their data.
鈥淔or instance, an ag lender needs to know how a customer鈥檚 business works. It鈥檚 important to have an ability to understand what鈥檚 going on on the other side of the desk to best serve them,鈥 Moore says.
For Karlowitz, who is busy developing the curriculum for the new UASM program, it鈥檚 an exciting time. 鈥淚t鈥檚 an emerging technology that is changing so fast. It will be our job to train students on how to fly and help researchers in their work.鈥
And help farmers easily see the details hidden in the hundreds of acres 鈥 treat those weeds over here, cut down on the water over there.