Aboveground plant efficiency has improved significantly in 7 recent years, and the improvement has led to a steady increase in global food 8 production. The improvement of belowground plant efficiency has potential to 9 further increase food production. However, belowground plant roots are harder 10 to study, due to inherent challenges presented by root phenotyping. Several 11 tools for identifying root anatomical features in root cross-section images 12 have been proposed. However, the existing tools are not fully automated and 13 require significant human effort to produce accurate results. To address this 14 limitation, we use a fully automated approach, specifically, the Faster Region-15 based Convolutional Neural Network (Faster R-CNN), to identify anatomical 16 traits in root cross-section images. By training Faster R-CNN models on root cross-section images, we can detect objects such as root, stele and late 18 metaxylem, and predict rectangular bounding boxes around such objects. 19 Subsequently, the bounding boxes can be used to estimate the root diameter, 20 stele diameter, late metaxylem number, and average diameter. Experimental 21 evaluation using standard object detection metrics, such as intersection-over-22 union and mean average precision, has shown that the Faster R-CNN models 23 trained on rice root cross-section images can accurately detect root, stele 24 and late metaxylem objects. Furthermore, the results have shown that the 25 measurements estimated based on predicted bounding boxes have small root 26 mean square error when compared with the corresponding ground truth values, 27 suggesting that Faster R-CNN can be used to accurately detect anatomical 28 features. A webserver for performing root anatomy using the Faster R-CNN 29 models trained on rice images is available at https://rootanatomy.org, together 30 with a link to a GitHub repository that contains a copy of the Faster R-CNN 31 code. The labeled images used for training and evaluating the Faster R-CNN 32 models are also available from the GitHub repository. 33 The crop scientific community has made significant strides in increasing 37 global food production through advances in genetics and management, with 38 majority of the progress achieved by improving aboveground plant efficiency 39 [1, 2, 3]. The belowground plant roots, which provide water and nutrients 40 for plant growth, are relatively less investigated. This is primarily because of 41 the difficulty in accessing the roots, and the complexity of phenotyping root 42 biology and function [4, 5]. Hence, root potential has largely been untapped 43 in crop improvement programs [4, 5]. Over the past decade, different root 44 phenotyping approaches have been developed for studying root architecture, 45 including basket method for root angle [6], rhizotron method for tracking root 46 branching, architecture and growth dynamics [7], shovelomics, a.k.a., root 47 crown phenotyping [8], among others. Recent advances in magnetic resonance 48imaging and X-ray computed tomogra...
