Implementation of Sensors and Artificial Intelligence for Environmental Hazards Assessment in Urban, Agriculture and Forestry Systems

The implementation of artificial intelligence (AI), together with robotics, sensors, sensor networks, Internet of Things (IoT), and machine/deep learning modeling, has reached the forefront of research activities, moving towards the goal of increasing the efficiency in a multitude of applications and purposes related to environmental sciences. The development and deployment of AI tools requires specific considerations, approaches, and methodologies for their effective and accurate applications. This Special Issue focused on the applications of AI to environmental systems related to hazard assessment in urban, agriculture, and forestry areas

Optimizing Plant Water Use Efficiency for a Sustainable Environment

The rising shortage of water resources in crop-producing regions worldwide and the need for irrigation optimisation call for sustainable water savings. The allocation of irrigation water will be an ever-increasing source of pressure because of vast agricultural demands under changing climatic conditions. Consequently, irrigation has to be closely linked with water-use efficiency with the aim of boosting productivity and improving food quality, singularly in those regions where problems of water shortages or collection and delivery are widespread. The present Special Issue (SI) showcases 19 original contributions, addressing water-use efficiency in the context of sustainable irrigation management to meet water scarcity conditions. These papers cover a wide range of subjects including (i) interaction mineral nutrition and irrigation in horticultural crops, (ii) sustainable irrigation in woody fruit crops, (iii) medicinal plants, (iv) industrial crops, and (v) other topics devoted to remote sensing techniques and crop water requirements, genotypes for drought tolerance, and agricultural management. The studies were carried out in both field and laboratory surveys, with modelling studies also being conducted, and a wide range of geographic regions are also covered. The collection of these manuscripts presented in this SI updates on and provides a relevant contribution for efficient saving water resources

Proceedings of the European Conference on Agricultural Engineering AgEng2021

This proceedings book results from the AgEng2021 Agricultural Engineering Conference under auspices of the European Society of Agricultural Engineers, held in an online format based on the University of Évora, Portugal, from 4 to 8 July 2021. This book contains the full papers of a selection of abstracts that were the base for the oral presentations and posters presented at the conference. Presentations were distributed in eleven thematic areas: Artificial Intelligence, data processing and management; Automation, robotics and sensor technology; Circular Economy; Education and Rural development; Energy and bioenergy; Integrated and sustainable Farming systems; New application technologies and mechanisation; Post-harvest technologies; Smart farming / Precision agriculture; Soil, land and water engineering; Sustainable production in Farm buildings

Irrigation Systems and Practices in Challenging Environments

The book Irrigation Systems and Practices in Challenging Environments is divided into two interesting sections, with the first section titled Agricultural Water Productivity in Stressed Environments, which consists of nine chapters technically crafted by experts in their own right in their fields of expertise. Topics range from effects of irrigation on the physiology of plants, deficit irrigation practices and the genetic manipulation, to creating drought tolerant variety and a host of interesting topics to cater for the those interested in the plant water soil atmosphere relationships and agronomic practices relevant in many challenging environments, more so with the onslaught of global warming, climate change and the accompanying agro-meteorological impacts. The second section, with eight chapters, deals with systems of irrigation practices around the world, covering different climate zones apart from showing casing practices for sustainable irrigation practices and more efficient ways of conveying irrigation waters - the life blood of agriculture, undoubtedly the most important sector in the world

Assessment of fruit growth response to water stress in a super-high-density olive orchard: monitoring, physiological mechanisms and potential use to schedule irrigation.

Olive fruit growth has an important effect on the final yield, and thus, it is important to study its response to water stress, and to know how olive fruits grow under no water restriction. The present PhD. Thesis centered on the fruit growth, and the factors that influence it, such as the root system distribution, the leaf gas exchange and the water relations between fruits and leaves as well as on the utility of continuous measurements of fruit diameter variations. Therefore, in Chapter 2 we assessed the influence of the increment of drip lines (from one to two drip lines per tree row) on the belowground and aboveground vegetative and on the fruit growth, during two irrigation seasons. We also estimated leaf stomatal conductance from sap flux measurements, and simulated photosynthesis (Chapter 3). From the simulated photosynthesis, we compared its accumulated values with growth, both vegetative growth (leaf area and number of internodes in current-year stems) and fruit growth (fruit dry weight and oil content). As fruit growth is not only influenced by photosynthesis, but also by the water relations, we assessed the influence of water stress on the water relations between fruits and leaves, and its influence on fruit growth (Chapter 4). Additionally, we performed pressure-volume curves with olive fruits from well irrigated and deficit irrigated treatments. Finally, we evaluated the usefulness of fruit dendrometers, and the indexes derived from its measurements, to assess tree water status and to schedule irrigation (Chapter 5). The results presented in this PhD. Thesis improve the knowledge on the factors involved in fruit growth and present a first step towards the use of fruit dendrometers in olive trees. Additionally, these results are important for the development of future studies on the olive fruit growth physiology