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plant growth modeling and irrigation systems is also explained. The chapter ends with a discussion of current problems along with possible future implementation of new approaches to solve them.

       – Chapter 4 provides insight into the opportunities presented by the use of robots in agriculture, known as agribots, and focuses on the advancements in different types of agribots in terms of sensing, mobility, path planning, and manipulation. It also talks about the status and progress of robots in Indian agriculture, concentrating on Indian-based robotic startups and case studies involving the use of robots in harvesting crops along with the challenges faced when deploying robots in the field.

       – Chapter 5 delves into the Colombian palm oil (PO) industry. The contribution of this study is twofold: First, it provides a more comprehensive review of the PO industry technology literature based on Scopus and Clarivate Analytics, using the reporting checklist of preferred reporting items for systematic reviews and meta-analyses (PRISMA). Second, as far as the authors know, this is one of the first studies to address the technological solutions applied by Colombia’s PO producers and aims to help fill this research gap.

       – Chapter 6 presents a case on smart agriculture and discusses intelligent agriculture in a greenhouse-based multi-agent system (MAS), which is made up of several agents located in an environment that interact according to some defined relationships. In this work, each part of the greenhouse environment is represented by one or more agent, with each agent coordinating with other agents to achieve set goals. In addition, it discusses the society of agents in which two types of agents can be found: 1) reactive agents characterized by simple behavior, whose mission it is to perform tasks that do not require intelligent reasoning, and 2) cognitive or intelligent agents, which are tasked with performing more complex missions and require reasoning to make good decisions.

       – Chapter 7 is a study on the use of automatic and intelligent methods in the management of irrigation of agricultural land. Among these technologies are artificial intelligence and the Internet of Things (IoT), which are used to optimize the management of irrigation water in agricultural lands. The elements of the agricultural system and its environment are presented by things in direct contact with each other by relying on information and communication technology (ICT).

       – Chapter 8 discusses how modern agriculture has become knowledge intensive and how improved access to and availability of information and communication technologies (ICTs), especially cell phones, computers, radio, internet, and social media, has created many more opportunities for multi-format information gathering, processing, storage, retrieval, management and sharing.

       – Chapter 9 presents an overview of nanotechnology and nanosensors in forestry and agriculture, including its use in forest health protection, forest management, wood and paper processing, and chemotaxonomy. The nanotechnology sector has best applied this technology in precision farming by developing nanobionic plants by inserting nanosensors into living plants that can be utilized to communicate as infrared devices and for sensing objects in the plant’s environment. Therefore, the nanobionics approach has opened a new vista into plant nanomaterial research. Some nanobionics approaches for agriculture and forestry development are also briefly discussed.

       – Chapter 10 is all about mathematical models of the water resources management process of canals in the middle reaches of the Chirchik River, which were developed using simplified differential equations of Saint Venant in partial derivatives to model the necessary conditions for optimizing water distribution. An algorithm for solving the problem of optimal water resources management of distributed irrigation canals was also developed.

       – Chapter 11 discusses various principles of reengineering of agricultural resources and throws light on open problems, challenges, and future trends.

       – Chapter 12 shows how the supply chain management method is used for planning maintenance strategy, storing products, moving material through the organization and its distribution channel, which leads directly to maximum profits through cost-saving fulfilment of orders. A simple supply chain acts as a bridge between demand and supply. Startups are bringing a new shape to the agri-supply chain by using new-age technologies like AI, machine learning, IoT and blockchain management, that procure directly from farm gates and supply to retailers.

       – Chapter 13 discusses the need for an institutional approach of using digital techniques in modern agrarian production. This approach is illustrative of the synergy of economic, ecological, and social effectiveness as a progressive direction in which the development of a global economic system can be worked out. A general model was used to determine a new organization of the informational paradigm of agricultural activities based on the agility of the knowledge and analytical data being transferred into the value of information.

       – Chapter 14 provides a comprehensive analysis of four aspects of AI implementation in treatment of wastewater: management, technology, reuse and economics of wastewater. It also provides an insight into the future prospects of the use of AI in the treatment of wastewater, which, in complex practical applications, simultaneously addresses pollutant removal, water reuse and management and cost-efficient challenges.

       – Chapter 15 presents methods for assessing the impact of digital transformation risks on the business model of agricultural enterprises. Industry 4.0 is accompanied by the rapid transformation of several sectors under the influence of “breakthrough” digital innovations such as blockchain, IoT, AI, and augmented reality.

       – Chapter 16 presents a unified systematic approach to the issue of modeling the dynamics of water management facilities. There is a wide range of mathematical models of individual objects of different complexity, which is why the choice of mathematical models that will describe the complex processes of water distribution in water management systems with the required degree of accuracy is a very problematic task.

       – Chapter 17 showcases the use of blockchain technology that has become a phenomenon in recent years and is evolving into a form that institutionalized organizations can benefit from. The IoT integrates blockchain technology into the agricultural sector and provides the automation of the control mechanisms in the agricultural food supply chain. The study evaluated in this chapter utilizes technology in various forms, from farm to fork. Furthermore, a Fintech solution framework via blockchain created for digitalization of the agricultural commodity value chain is presented that secures the contract creation, transfer, and redemption (burn) processes.

       – Chapter 18 discusses how new-age entrepreneurs are using technological innovations to address supply chain challenges and unlock value across it. India’s startup agricultural ecosystem is mushrooming, with over 450 startups that are currently operational, over 50% of which are focused on making the supply chain more efficient by improving market linkages. Inputs play a crucial role in extracting higher yields. The existing delivery system is not appropriate due to poor supply, lack of subsidies, improper infrastructure, lack of farm credit, and poor delivery systems.

       – Chapter 19 is about the adoption of blockchain technology in the Malaysian agriculture sector and proposes a framework of

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