Advances in Unmanned Aerial System Remote Sensing for Precision Viticulture

Sassu, Alberto; Gambella, Filippo; Ghiani, Luca; Mercenaro, Luca; Caria, Maria; Pazzona, Antonio Luigi

doi:10.3390/s21030956

Cited by 33 publications

(16 citation statements)

References 114 publications

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“…A high-density point cloud was generated, and from its interpolation, a DSM and then a DTM were computed. After the performance of the radiometric calibration, reflectance maps of each band are generated, and the NDVI [11] is computed using the reflectance from the NIR and red bands, as in Equation (2). A CSM was computed from the subtraction of the altitude values of the DTM to the DSM, as in Equation (3).…”

Section: Data Processingmentioning

confidence: 99%

“…According to the definition adopted by the International Society of Precision Agriculture, Precision Agriculture (PA) can be defined as the "management strategy that gathers, processes and analyses temporal, spatial and individual data and combines it with other information to support management decisions according to estimated variability for improved resource use efficiency, productivity, quality, profitability and sustainability of agricultural production" [1]. Sassu et al [2] argue that PA is related with the use of technology to manage the spatial and temporal variability associated with agricultural production, so that it can improve the crop performance, bringing economic benefits and environmental quality with the correct use of pollutants. Regardless of the sources used to establish PA, they all include several innovative technologies, such as the use of data acquired by Unmanned Aerial Vehicles (UAVs), satellite imagery data, the use of Geographical Information Systems (GIS) technologies, nutrient management field mapping, Internet of Things (IoT) sensors, and data processing techniques such as Machine Learning and Deep Learning, among others, allowing experts to use specific tools to optimize agriculture production [2][3][4].…”

Section: Introductionmentioning

confidence: 99%

“…Sassu et al [2] argue that PA is related with the use of technology to manage the spatial and temporal variability associated with agricultural production, so that it can improve the crop performance, bringing economic benefits and environmental quality with the correct use of pollutants. Regardless of the sources used to establish PA, they all include several innovative technologies, such as the use of data acquired by Unmanned Aerial Vehicles (UAVs), satellite imagery data, the use of Geographical Information Systems (GIS) technologies, nutrient management field mapping, Internet of Things (IoT) sensors, and data processing techniques such as Machine Learning and Deep Learning, among others, allowing experts to use specific tools to optimize agriculture production [2][3][4]. Rmote sensing imagery, such as Sentinel-2 images or Landsat, combined with environmental data (climate, soil, elevation) have been used to forecast agriculture production [5,6].…”

Section: Introductionmentioning

confidence: 99%

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QVigourMap: A GIS Open Source Application for the Creation of Canopy Vigour Maps

Duarte¹,

Teodoro²,

Sousa

et al. 2021

Agronomy

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In a precision agriculture context, the amount of geospatial data available can be difficult to interpret in order to understand the crop variability within a given terrain parcel, raising the need for specific tools for data processing and analysis. This is the case for data acquired from Unmanned Aerial Vehicles (UAV), in which the high spatial resolution along with data from several spectral wavelengths makes data interpretation a complex process regarding vegetation monitoring. Vegetation Indices (VIs) are usually computed, helping in the vegetation monitoring process. However, a crop plot is generally composed of several non-crop elements, which can bias the data analysis and interpretation. By discarding non-crop data, it is possible to compute the vigour distribution for a specific crop within the area under analysis. This article presents QVigourMaps, a new open source application developed to generate useful outputs for precision agriculture purposes. The application was developed in the form of a QGIS plugin, allowing the creation of vigour maps, vegetation distribution maps and prescription maps based on the combination of different VIs and height information. Multi-temporal data from a vineyard plot and a maize field were used as case studies in order to demonstrate the potential and effectiveness of the QVigourMaps tool. The presented application can contribute to making the right management decisions by providing indicators of crop variability, and the outcomes can be used in the field to apply site-specific treatments according to the levels of vigour.

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Section: Data Processingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

QVigourMap: A GIS Open Source Application for the Creation of Canopy Vigour Maps

Duarte¹,

Teodoro²,

Sousa

et al. 2021

Agronomy

View full text Add to dashboard Cite

show abstract

“…Differences in their management, accuracy, economical cost, and other important factors have been extensively discussed, yielding various advantages and disadvantagesdirectly related to the targeted crop and conditions-of both methods. Although satellite image acquisition of large areas saves considerable time, it has a low and inadequate resolution for precision viticulture [23,24]. The effectiveness of Sentinel-2 imagery and high-resolution UAV aerial images was evaluated [25], concluding that the resolution of the satellite imagery was insufficient for their direct use for describing vineyard variability.…”

Section: Introductionmentioning

confidence: 99%

Assessment of Vineyard Canopy Characteristics from Vigour Maps Obtained Using UAV and Satellite Imagery

Campos

García-Ruiz

Gil

2021

Sensors

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Canopy characterisation is a key factor for the success and efficiency of the pesticide application process in vineyards. Canopy measurements to determine the optimal volume rate are currently conducted manually, which is time-consuming and limits the adoption of precise methods for volume rate selection. Therefore, automated methods for canopy characterisation must be established using a rapid and reliable technology capable of providing precise information about crop structure. This research providedregression models for obtaining canopy characteristics of vineyards from unmanned aerial vehicle (UAV) and satellite images collected in three significant growth stages. Between 2018 and 2019, a total of 1400 vines were characterised manually and remotely using a UAV and a satellite-based technology. The information collected from the sampled vines was analysed by two different procedures. First, a linear relationship between the manual and remote sensing data was investigated considering every single vine as a data point. Second, the vines were clustered based on three vigour levels in the parcel, and regression models were fitted to the average values of the ground-based and remote sensing-estimated canopy parameters. Remote sensing could detect the changes in canopy characteristics associated with vegetation growth. The combination of normalised differential vegetation index (NDVI) and projected area extracted from the UAV images is correlated with the tree row volume (TRV) when raw point data were used. This relationship was improved and extended to canopy height, width, leaf wall area, and TRV when the data were clustered. Similarly, satellite-based NDVI yielded moderate coefficients of determination for canopy width with raw point data, and for canopy width, height, and TRV when the vines were clustered according to the vigour. The proposed approach should facilitate the estimation of canopy characteristics in each area of a field using a cost-effective, simple, and reliable technology, allowing variable rate application in vineyards.

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“…In case of remotely sensed imagery, the UAV (unmanned aerial vehicle) is being increasingly used for accurately monitoring of crops [ 9 , 10 , 11 ] due to its very high spatial and temporal resolution, low cost, easy access to difficult zones and absence of soil compaction. All these characteristics make UAV technology an adequate tool for mapping perennial crops such as almond [ 12 , 13 ], olive [ 14 , 15 ], or vineyards at the field scale for different proposes related with—e.g., 3D canopy characterization, water stress, or site-specific weed control [ 16 , 17 , 18 , 19 , 20 , 21 , 22 ]. As happens with on-ground images, one of the most challenging objectives for UAV image analysis is to develop cost-effective, robust and straightforward repeatable procedures for vineyard yield estimation at field scale.…”

Section: Introductionmentioning

confidence: 99%

Grape Cluster Detection Using UAV Photogrammetric Point Clouds as a Low-Cost Tool for Yield Forecasting in Vineyards

Torres‐Sánchez

Mesas‐Carrascosa

Santesteban

et al. 2021

Sensors

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Yield prediction is crucial for the management of harvest and scheduling wine production operations. Traditional yield prediction methods rely on manual sampling and are time-consuming, making it difficult to handle the intrinsic spatial variability of vineyards. There have been significant advances in automatic yield estimation in vineyards from on-ground imagery, but terrestrial platforms have some limitations since they can cause soil compaction and have problems on sloping and ploughed land. The analysis of photogrammetric point clouds generated with unmanned aerial vehicles (UAV) imagery has shown its potential in the characterization of woody crops, and the point color analysis has been used for the detection of flowers in almond trees. For these reasons, the main objective of this work was to develop an unsupervised and automated workflow for detection of grape clusters in red grapevine varieties using UAV photogrammetric point clouds and color indices. As leaf occlusion is recognized as a major challenge in fruit detection, the influence of partial leaf removal in the accuracy of the workflow was assessed. UAV flights were performed over two commercial vineyards with different grape varieties in 2019 and 2020, and the photogrammetric point clouds generated from these flights were analyzed using an automatic and unsupervised algorithm developed using free software. The proposed methodology achieved R2 values higher than 0.75 between the harvest weight and the projected area of the points classified as grapes in vines when partial two-sided removal treatment, and an R2 of 0.82 was achieved in one of the datasets for vines with untouched full canopy. The accuracy achieved in grape detection opens the door to yield prediction in red grape vineyards. This would allow the creation of yield estimation maps that will ease the implementation of precision viticulture practices. To the authors’ knowledge, this is the first time that UAV photogrammetric point clouds have been used for grape clusters detection.

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Advances in Unmanned Aerial System Remote Sensing for Precision Viticulture

Cited by 33 publications

References 114 publications

QVigourMap: A GIS Open Source Application for the Creation of Canopy Vigour Maps

QVigourMap: A GIS Open Source Application for the Creation of Canopy Vigour Maps

Assessment of Vineyard Canopy Characteristics from Vigour Maps Obtained Using UAV and Satellite Imagery

Grape Cluster Detection Using UAV Photogrammetric Point Clouds as a Low-Cost Tool for Yield Forecasting in Vineyards

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