Abstract
With the advent of agriculture 3.0 and 4.0, in view of efficient and sustainable use of resources, researchers are increasingly focusing on the development of innovative smart farming and precision agriculture technologies by introducing automation and robotics into the agricultural processes. Autonomous agricultural field machines have been gaining significant attention from farmers and industries to reduce costs, human workload, and required resources. Nevertheless, achieving sufficient autonomous navigation capabilities requires the simultaneous cooperation of different processes; localization, mapping, and path planning are just some of the steps that aim at providing to the machine the right set of skills to operate in semi-structured and unstructured environments. In this context, this study presents a low-cost, power-efficient local motion planner for autonomous navigation in vineyards based only on an RGB-D camera, low range hardware, and a dual layer control algorithm. The first algorithm makes use of the disparity map and its depth representation to generate a proportional control for the robotic platform. Concurrently, a second back-up algorithm, based on representations learning and resilient to illumination variations, can take control of the machine in case of a momentaneous failure of the first block generating high-level motion primitives. Moreover, due to the double nature of the system, after initial training of the deep learning model with an initial dataset, the strict synergy between the two algorithms opens the possibility of exploiting new automatically labeled data, coming from the field, to extend the existing model’s knowledge. The machine learning algorithm has been trained and tested, using transfer learning, with acquired images during different field surveys in the North region of Italy and then optimized for on-device inference with model pruning and quantization. Finally, the overall system has been validated with a customized robot platform in the appropriate environment.
Highlights
Nowadays, with the continuous growth of the human population, agriculture industries and farmers have been facing the exponential augmentation of global demand of food production.According to the projections of growth established in 2017 by the United Nations [1], by 2050, the global population will be around 9.7 billion and it is expected to reach 11.1 billion in 2100
We present a low-cost, robust local motion planner for autonomous navigation in vineyards trying to overcome some of the present limitations
We introduce the optimization adjustments applied to the network in order to boost the frequency control to 47.15 Hz
Summary
With the continuous growth of the human population, agriculture industries and farmers have been facing the exponential augmentation of global demand of food production.According to the projections of growth established in 2017 by the United Nations [1], by 2050, the global population will be around 9.7 billion and it is expected to reach 11.1 billion in 2100. Precision agriculture [2] and digital farming [3] have gradually contributed with autonomous robotic machines and information collection to improve crop yield and resource management, to reduce the labor costs, and in part, to increase the production efficiency. This has led to equip harvesting machineries with driverless systems in order to maximize the navigation efficiency by reducing the number of intersections in the path, and the amount of fuel consumed [4]. Most of the proposed solutions require a combination of real-time kinematic GPS (RTK-GPS) [17,18] and costly sensors like three-dimensional multi-channel Light
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