Terrain assessment for precision agriculture using vehicle dynamic modelling

Reina, Giulio; Milella, Annalisa; Galati, Rocco

doi:10.1016/j.biosystemseng.2017.06.025

Cited by 56 publications

(43 citation statements)

References 23 publications

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“…For example, acceleration-based terrain classification methods were introduced for planetary exploration rovers (Brooks and Iagnemma, 2005 ) and rough-terrain robots (DuPont et al, 2008 ). However, the vehicles adopted for the tests are based on wheels and they are typically equipped with no suspension systems (Masha et al, 2017 ; Reina et al, 2017a ). This last aspect can be considered as a limiting factor since the roughness that it is possible to run against in terrains like ploughed and rocky soil or gravel can generate unintended mechanical stress to the robot frame and the sensors.…”

Section: Introductionmentioning

confidence: 99%

Terrain Awareness Using a Tracked Skid-Steering Vehicle With Passive Independent Suspensions

Galati

Reina

2019

Front. Robot. AI

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This paper presents a novel approach for terrain characterization based on a tracked skid-steer vehicle with a passive independent suspensions system. A set of physics-based parameters is used to characterize the terrain properties: drive motor electrical currents, the equivalent track, the power spectral density for the vertical accelerations and motor currents. Based on this feature set, the system predicts the type of terrain that the robot traverses. A wide set of experimental results acquired on various surfaces are provided to verify the study in the field, proving its effectiveness for application in autonomous robots.

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Section: Introductionmentioning

confidence: 99%

Terrain Awareness Using a Tracked Skid-Steering Vehicle With Passive Independent Suspensions

Galati

Reina

2019

Front. Robot. AI

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“…Thus, composing and solving of the model examples is one of the most important stages for development and implementation of the economic and mathematical models. (11)(12)(13)(14)(15)(16)(17)(18) The work presents setting and model example for the problem for selection of the investment sources and objects. The basic provisions of the economic and mathematical model are given bellow.…”

Section: Methodsmentioning

confidence: 99%

Mathematical modeling in economics for selection of optimum investment solution

Alukhanyan

Panfilova

2021

E3S Web Conf.

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This work is devoted to development of economic and mathematical models for selection of the optimum investment solution. Moreover, it states the basis for development of model examples and correction of the model considering the results obtained in the examples. In the work the problem is set for selection of the investment sources and objects, which is limited to the linear programming problem. The controlled variable and basic limitations simulating real credit and monetary relations are distinguished in the provided model. The discounted profit obtained from implementation of the optimum investment portfolio is considered as a target function. The economic and mathematical model presented in the article allows finding the optimum investment solution within the limits of the credit and monetary relations taking place both at the micro- and macroeconomic level.

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“…Field tests were conducted in a peach orchard and the results demonstrated the potential to guide utility vehicles in orchards. Reina et al [55] examined terrain assessment for precision agriculture using the Husky A200 UGV. The authors conducted experiments in a farm for validating the proposed terrain classifier and identified terrain classes.…”

Section: Physical Space: Real-world Implementationmentioning

confidence: 99%

AgROS: A Robot Operating System Based Emulation Tool for Agricultural Robotics

2019

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This research aims to develop a farm management emulation tool that enables agrifood producers to effectively introduce advanced digital technologies, like intelligent and autonomous unmanned ground vehicles (UGVs), in real-world field operations. To that end, we first provide a critical taxonomy of studies investigating agricultural robotic systems with regard to: (i) the analysis approach, i.e., simulation, emulation, real-world implementation; (ii) farming operations; and (iii) the farming type. Our analysis demonstrates that simulation and emulation modelling have been extensively applied to study advanced agricultural machinery while the majority of the extant research efforts focuses on harvesting/picking/mowing and fertilizing/spraying activities; most studies consider a generic agricultural layout. Thereafter, we developed AgROS, an emulation tool based on the Robot Operating System, which could be used for assessing the efficiency of real-world robot systems in customized fields. The AgROS allows farmers to select their actual field from a map layout, import the landscape of the field, add characteristics of the actual agricultural layout (e.g., trees, static objects), select an agricultural robot from a predefined list of commercial systems, import the selected UGV into the emulation environment, and test the robot’s performance in a quasi-real-world environment. AgROS supports farmers in the ex-ante analysis and performance evaluation of robotized precision farming operations while lays the foundations for realizing “digital twins” in agriculture.

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Terrain assessment for precision agriculture using vehicle dynamic modelling

Cited by 56 publications

References 23 publications

Terrain Awareness Using a Tracked Skid-Steering Vehicle With Passive Independent Suspensions

Terrain Awareness Using a Tracked Skid-Steering Vehicle With Passive Independent Suspensions

Mathematical modeling in economics for selection of optimum investment solution

AgROS: A Robot Operating System Based Emulation Tool for Agricultural Robotics

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