Today’s crop breeders are trying to boost yields while preparing these plants to withstand severe weather and changing climates. To succeed, they must locate the genes for high-yielding, hardy traits in crop plants’ DNA. Yesterday, a robot developed by the University of Illinois to find these proverbial needles in the haystack was recognized by the best systems paper award at Robotics: Science and Systems, the preeminent robotics conference held this week in Pittsburgh.
“There’s a real need to accelerate breeding to meet global food demand,” said Girish Chowdhary, an assistant professor of field robotics in the Department of Agricultural and Biological Engineering and the Coordinated Science Lab at Illinois. “In Africa, the population will more than double by 2050, but today the yields are only a quarter of their potential.”
Crop breeders run massive experiments comparing thousands of different cultivars, or varieties, of crops over hundreds of acres and measure key traits, like plant emergence or height, by hand. The task is expensive, time-consuming, inaccurate, and ultimately impossible—a team can only manually measure a fraction of plants in a field.
“The lack of automation for measuring plant traits is a bottleneck to progress,” said first author Erkan Kayacan, now a postdoctoral researcher at the Massachusetts Institute of Technology. “But it’s hard to make robotic systems that can count plants autonomously: the fields are vast, the data can be noisy (unlike benchmark datasets), and the robot has to stay within the tight rows in the challenging under-canopy environment.”
Illinois’ 13-inch wide, 24-pound TerraSentia robot is transportable, compact and autonomous. It captures each plant from top to bottom using a suite of sensors (cameras), algorithms, and deep learning. Using a transfer learning method, the researchers taught TerraSentia to count corn plants with just 300 images, as reported (DOI: 10.15607/RSS.2018.XIV.036) at this conference.
“One challenge is that plants aren’t equally spaced, so just assuming that a single plant is in the camera frame is not good enough,” said co-author ZhongZhong Zhang, a graduate student in the College of Agricultural Consumer and Environmental Sciences (ACES). “We developed a method that uses the camera motion to adjust to varying inter-plant spacing, which has led to a fairly robust system for counting plants in different fields, with different and varying spacing, and at different speeds.”
This work was supported by the Advanced Research Project Agency-Energy (ARPA-E) as part of the TERRA-MEPP project at the Carl R. Woese Institute for Genomic Biology. The robot is now available through the start-up company, EarthSense, Inc. which is equipping the robot with advanced autonomy and plant analytics capabilities.
This article originally appeared on the TERRA-MEPP website and EurekAlert.