Internet of Things

“…Afterward, the collected data need to be processed, analyzed, and integrated to make decisions by using suitable communications platforms and protocols. In this regard, IoT is widely used to describe embedded systems through Internet connectivity in order to allow the interaction with other systems, human, or services, on a global scale [122,118]. According to Mukhopadhyay [122], IoT can increase reliability, sustainability, and efficiency by improved access to information.…”

“…In this regard, IoT is widely used to describe embedded systems through Internet connectivity in order to allow the interaction with other systems, human, or services, on a global scale [122,118]. According to Mukhopadhyay [122], IoT can increase reliability, sustainability, and efficiency by improved access to information. However, to provide Internet to the whole facility is a high investment that should be carefully analyzed.…”

Energy efficiency in discrete-manufacturing systems: Insights, trends, and control strategies

“…Afterward, the collected data need to be processed, analyzed, and integrated to make decisions by using suitable communications platforms and protocols. In this regard, IoT is widely used to describe embedded systems through Internet connectivity in order to allow the interaction with other systems, human, or services, on a global scale [122,118]. According to Mukhopadhyay [122], IoT can increase reliability, sustainability, and efficiency by improved access to information.…”

“…In this regard, IoT is widely used to describe embedded systems through Internet connectivity in order to allow the interaction with other systems, human, or services, on a global scale [122,118]. According to Mukhopadhyay [122], IoT can increase reliability, sustainability, and efficiency by improved access to information. However, to provide Internet to the whole facility is a high investment that should be carefully analyzed.…”

Energy efficiency in discrete-manufacturing systems: Insights, trends, and control strategies

“…• synthesis of the structural and algorithmic organization of a computerized system, taking into account a complete list of the physical and chemical factors of the greenhouse microclimate (Laktionov et al, 2017a(Laktionov et al, , 2017b); • implementation of the system development and research stages using up-to-date software for simulation of microprocessor devices (Benrejeb and Boubaker, 2012;Das et al, 2015;Gori Ayub, 2016;Nkenyereye and Jang, 2016) and the main ideas of Internet of Things, Industry 4.0 and Data Mining technologies (Doknić, 2014;Mukhopadhyay and Suryadevara, 2014;Ghayvat et al, 2015;Pirbhulal et al, 2017); and • implementation of the physical model of the computerized monitoring and control system by means of available and efficient microprocessor platforms (Das et al, 2015;Thati et al, 2015;Dhanalakshmi and Leni, 2017;Laktionov et al, 2017b) and sensor technologies (Mukhopadhyay et al, 2006(Mukhopadhyay et al, , 2008Mohd Syaifudin et al, 2009;Haefke et al, 2011;Laktionov et al, 2017a). Thus, studies on the elimination of these deficiencies in existing systems for computerized monitoring and control of industrial greenhouse microclimate parameters, taking into account the main conceptual ideas for constructing such systems, can be performed by simulation methods.…”

Results of Simulation and Physical Modeling of the Computerized Monitoring and Control System for Greenhouse Microclimate Parameters

Internet of Things (IoT) Fundamentals