Assessment of data fusion oriented on data mining approaches to enhance precision agriculture practices aimed at increase of Durum Wheat (Triticum turgidum L. var. durum) yield

D’Accolti, A.; Maggio, Sabrina; Massaro, Alessandro; Galiano, Angelo; Birardi, Vitangelo; Pellicani, Leonardo

doi:10.21839/jfna.2018.v1i1.229

“…In this direction neural networks such as Long Short Term Memory (LSTM) [39] and Artificial Neural Networks (ANNs) [40] could also be applied for: • processing production inefficiencies: the LSTM/ANNs networks could predict sanitation inefficiencies by processing and crossing data of the experimental test of cultivation (in Fig. 7 is shown the experimental field used to acquire and to collect data for the preprocessing of vegetables); the BC will include data and information about sanitation test by adopting different no-chemical pre-treatment solutions; • delays in transport: the algorithms predict production according to metrological sales prediction [41], [42]; • risk of persistent contamination: the neural network could predict the contamination evolution by indicating the risk using different approaches for sanitation; • field condition prediction: precision agriculture and data mining [43], [44] could facilitate the data processing by analyzing other factors that could influence product sanitation such as hydric stress, temperature, humidity and evapotranspiration [45]. The production process traceability by BC could activate automatic smart contracts thus accelerating marketing and commercial processes.…”

Section: Discussionmentioning

confidence: 99%

Blockchain and Technologies Matching with the Case of Study of Vegetables Production

Massaro¹

2021

ITII

0

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The proposed work describes a new approach based on supply chain traceability by blockchain (BC). The basic BC network has been designed and applied for vegetables process monitoring and tracing. The paper proposes some results of an industry research project by describing the whole scenario, the architectures implementing BC, the sequence diagram principle, and the prototype network embedding blocks and transactions. The discussion is also addressed on the possibility to combine different technique such as artificial intelligence, and image processing to improve pre-cut vegetable quality. The paper proposed preliminary results proves that the adopted technologies and the methodologies found in the literature are suitable for the sanitation process certification and for quality traceability. The mentioned approaches are useful to apply the suggested frameworks for other supply chains.

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“…In this direction neural networks such as Long Short Term Memory (LSTM) [39] and Artificial Neural Networks (ANNs) [40] could also be applied for: • processing production inefficiencies: the LSTM/ANNs networks could predict sanitation inefficiencies by processing and crossing data of the experimental test of cultivation (in Fig. 7 is shown the experimental field used to acquire and to collect data for the preprocessing of vegetables); the BC will include data and information about sanitation test by adopting different no-chemical pre-treatment solutions; • delays in transport: the algorithms predict production according to metrological sales prediction [41], [42]; • risk of persistent contamination: the neural network could predict the contamination evolution by indicating the risk using different approaches for sanitation; • field condition prediction: precision agriculture and data mining [43], [44] could facilitate the data processing by analyzing other factors that could influence product sanitation such as hydric stress, temperature, humidity and evapotranspiration [45]. Fig.…”

Section: Discussionmentioning

confidence: 99%

Blockchain and Technologies Matching with the Case of Study of Vegetables Production

Massaro¹

2020

Preprint

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<div>Alessandro Massaro: Professor Alessandro Massaro (ING/INF/01, FIS/01,FIS/03) carried out scientific research </div><div>at the Polytechnic University of Marche, at CNR, and at Italian Institute of Technology (IIT) as Team Leader by activating laboratories for nanocomposite sensors for </div><div>industrial robotics. He is in MIUR register as scientific expert in competitive Industrial Research and social </div><div>development, and he is currently head of the Research and Development section and scientific director of MIUR Research Institute Dyrecta Lab Srl. Member of the International Scientific Committee of Measurers IMEKO and IEEE Senior member, recently received an award from the National Council of Engineers as Best Engineer of Italy 2018 (Top Young Engineer 2018). </div>

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“…Approaches around data mining in agriculture have used different schemes to solve a variety of problems, from satellite images in the estimation of possible uses and land cover, to predicting production, yield, and incidence of diseases of a crop through machine learning techniques, among others (Mucherino et al., 2009; Patel and Patel, 2014; Milovic and Radojevic, 2015; Mistry and Shah, 2016; Kodeeshwari and Ilakkiya, 2017; D'Accolti et al., 2018; Ait Issad et al., 2019; Anton et al., 2019; Vignesh and Vinutha, 2020). In order to complement the previously mentioned approaches, Scopus, ScienceDirect, Google Scholar, IEEE Digital Library, and Springer Link databases were consulted.…”

Section: Related Workmentioning

confidence: 99%

A proposal for a multi‐domain data fusion strategy in a climate‐smart agriculture context

López

¹

,

Grass

²

,

Casas

³

et al. 2020

Int Trans Operational Res

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Agriculture provides food, raw materials, and employment opportunities for a significant percentage of the world's population. Climate, economic, political, social, and other conditions affect decision making in agricultural processes. In many cases, these conditions imply the loss of suitability of many areas for some traditional crops. In contrast, these areas can produce new crops by taking advantage of changing conditions. In this sense, having reliable tools and information for decision making is essential in adapting to new agricultural productivity scenarios. The above implies having sufficient and relevant data sources to reduce the uncertainty in the decision‐making processes. However, data by nature tend to be diverse in structure, storage formats, and access protocols. Data fusion tasks have been immersed in a multitude of applications and have been approached from different points of view when implementing a suitable solution. We propose a multi‐domain data fusion strategy to support data analysis tasks in agricultural contexts. We also describe all the data sources collected, which are the main input to the proposed strategy. The combined data sources were also evaluated through a preliminary exploratory analysis in a multi‐label learning approach. Finally, the data fusion strategy is explained through an example in agricultural crop production.

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Assessment of data fusion oriented on data mining approaches to enhance precision agriculture practices aimed at increase of Durum Wheat (Triticum turgidum L. var. durum) yield

Cited by 6 publications

References 66 publications

Blockchain and Technologies Matching with the Case of Study of Vegetables Production

Blockchain and Technologies Matching with the Case of Study of Vegetables Production

Blockchain and Technologies Matching with the Case of Study of Vegetables Production

A proposal for a multi‐domain data fusion strategy in a climate‐smart agriculture context

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