Research Trends in Artificial Intelligence: Internet of Things E-Book
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- Herausgeber: Bentham Science Publishers
- Kategorie: Wissenschaft und neue Technologien
- Sprache: Englisch
Stay informed about recent trends and groundbreaking research driving innovation in the AI-IoT landscape.
AI, a simulated form of natural intelligence within machines, has revolutionized various industries, simplifying daily tasks for end-users. This book serves as a handy reference, offering insights into the latest research and applications where AI and IoT intersect. The book includes 12 edited chapters that provide a comprehensive exploration of the synergies between AI and IoT. The contributors attempt to address engineering opportunities and challenges in different fields.
Key Topics:
AI and IoT in Smart Farming: Explore how these technologies enhance crop yield and sustainability, revolutionizing agricultural practices.
AIoT (Artificial Intelligence of Things): Understand the amalgamation of AI and IoT and its applications, particularly focusing on smart cities and agriculture.
Smart Healthcare and Predictive Disease Analysis: Uncover the crucial role of AI and IoT in early disease prediction and improving healthcare outcomes.
Applications of AI in Various Sectors: Explore how AI contributes to sustainable development, sentiment analysis, education, autonomous vehicles, fashion, virtual trial rooms, and more.
Each chapter has structured sections with summaries and reference lists, making it an invaluable resource for researchers, professionals, and enthusiasts keen on understanding the potential and impact of these technologies in today's rapidly evolving world.
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Seitenzahl: 354
Veröffentlichungsjahr: 2001
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FOREWORD
Artificial Intelligence (AI) in healthcare and biomedical applications is taking good shape nowadays. The convergence of AI, the Internet of Things, Blockchain and healthcare aims at delivering features such as scalability, security and privacy to high-level intellectual functions that are beneficial to the new era of digital information. In recent times, AI has touched major milestones by overcoming the challenges faced in realizing the full potential of projects in various fields such as smart homes, agriculture, smart cities, healthcare and medical, etc. Due to these transformations, the data is increasing at a faster rate in terms of size, complexity, variety, and heterogeneity, and in the sequel, computational intelligence, and machine learning the key contributors to improve business intelligence.
The book outline and contents show that the major coverage of the book includes a brief introduction to the domain, research challenges, literature review and state-of-the-art, different algorithms/techniques / deployment methods, data acquisition techniques including types of sensors used in IoT and communication, preprocessing and data cleaning, if required, application development and design issues, mathematical modeling of the engineering problems for ai based solution, different resources like datasets, APIs, software tools and packages evaluated or proposed, results, discussion and performance measures and future research directions. This will help readers to get detailed insights into the application of computational intelligence in the healthcare domain.
In addition to this, the communication and computing systems encompass every stage of professional and personal life, including education, healthcare, re- identification, transportation and social security. Data Science is used to analyze data from wearable trackers to ensure their patients’ well-being, assist in hospital administration by reducing the waiting time and enhance public care. Cloud Security helps in the ease of scaling, increased reliability and availability, disaster recovery, and managing remote work. These key enablers for the healthcare and biomedical domain and more focus on IoT, big data and cloud will help readers to empower their research and learning in these areas.
Buyers, who belong to the category of researchers, will benefit from the state-of-art and future research directions provided in the book. Practicing engineers will benefit from the knowledge of the current challenges in technology, deployment methods and solutions. Post-graduate students will be introduced to new domains, and recent advancements in them. They will also be made aware of the rapid growth in technology and obsolesce.
PREFACE
Artificial intelligence (AI) has grown in popularity in today's world. It refers to the simulation of natural intelligence in machines that have been programmed to learn and emulate human actions. AI is being used by huge companies all over the world to make the lives of end-users easier. The smart sensors and actuators are two key components of the Internet of Things (IoT). The IoT enables seamless connection to devices irrespective of time and location and hence it is an important component of what is known as the Industrial Revolution 4.0. One of the most significant advantages of the IoT is the reduction of human errors and manual labor, as well as the increase in overall efficiency and cost-effectiveness, both in terms of time and cost. This book offers recent research work going on in different domains where AI and IoT can be used. This book is a one-stop-shop for real-time work to solve engineering problems in various domains. The first few chapters are focused on the importance and amalgamation of IoT and AI for smart farming. It gives details about the basics of AI and IoT, and different algorithms available in AI and IoT for solving problems in agriculture. Healthcare is an important domain where early prediction of disease can save valuable human lives. In view of this, the second section of the book includes chapters focusing on research in the health care domain.
In today’s era where enormous data are generated every day, it is very important to analyze the data and find solutions to various problems, and predict future trends. The next section of the book is dedicated to such recent trends and research in different fields where IoT and AI can help in making better analyses, and predictions. In the real world, data comes for various use cases and there is a need for source-specific data science models. The book includes chapters highlighting research work done by various authors in multidisciplinary domains considering the needs of today and tomorrow.
List of Contributors
IoT and AI-based Smart Farm: Optimizing Crop Yield and Sustainability
Namrata Nishant Wasatkar1,*,Pranali Gajanan Chavhan1,Vikas Kanifnath Kolekar1Abstract
The “Smart Farm” project is an IoT-based agriculture project aimed at optimizing crop yield and promoting sustainability in farming practices. By integrating various IoT devices and sensors, the project aims to improve the efficiency of farming operations, reduce waste, and enhance the quality and quantity of crop yields. The project focuses on using IoT technology to monitor and control various aspects of farming, including soil moisture, temperature, humidity, crop health, and livestock behaviour. By leveraging data from these sensors and devices, farmers can make more informed decisions about irrigation, pest control, and crop management, leading to increased productivity and sustainability. Overall, the Smart Farm project seeks to transform traditional farming practices into a more efficient, data-driven, and sustainable model that benefits both farmers and the environment.
INTRODUCTION
Agriculture is a critical industry that plays a significant role in global food security, economic development, and environmental sustainability. However, traditional farming practices often rely on manual labor, intuition, and guesswork, which can lead to inefficiencies, waste, and environmental degradation. In recent years, there has been a growing interest in using Internet of Things (IoT) technology to improve the efficiency and sustainability of farming operations. The “SmartFarm” project is an IoT-based agriculture project that aims to optimize crop yield and promote sustainability by integrating various sensors and devices into farming practices. By collecting and analyzing data from these devices, farm-
ers can make more informed decisions about irrigation, pest control, and crop management, leading to increased productivity and sustainability. This project represents a significant shift towards data-driven, efficient, and sustainable farming practices that benefit both farmers and the environment. In this paper, we will explore the various components of the SmartFarm project, including the sensors and devices used, the data analysis techniques employed, and the expected outcomes and benefits of the project.
Agriculture involves five steps are as follows:
Preparing the soil.Planting.Spraying applications, fertilizer or chemicals.Harvesting.Managing: Determining what you did well and what you’ll do next year by collecting data for all of these steps.Smart farming, also known as precision agriculture or digital farming, is an advanced agricultural system that uses technology to optimize crop production and maximize yields while reducing waste, energy consumption, and environmental impact. It involves the use of various technologies, such as sensors, drones, machine learning, and data analytics, to monitor and control every aspect of the farming process [1].
The main goal of smart farming is to increase the efficiency and productivity of agriculture by making data-driven decisions based on real-time information [2]. For example, farmers can use sensors to measure soil moisture, temperature, and nutrient levels to determine the optimal time to plant, irrigate, or apply fertilizers. Drones equipped with cameras and sensors can help farmers monitor crop growth, detect pests and diseases, and identify areas that need attention.
Smart farming also involves the use of precision machinery and robotics, such as automated tractors and harvesters, to reduce labor costs and improve accuracy. In addition, data analytics and machine learning algorithms can help farmers analyze large amounts of data to identify patterns and optimize farming practices for better yields.
Overall, smart farming is a promising approach to modern agriculture, as it has the potential to increase yields, reduce costs, and minimize environmental impact.
CHALLENGES AND ISSUES
Farming faces several challenges and issues that can impact crop yield, profitability, and sustainability [2]. Here are some of the most significant issues in farming:
Climate Change: Climate change is causing extreme weather events, such as droughts, floods, and heat waves, which can impact crop yields and soil health.Water Management: Access to water and efficient water management is critical for farming, especially in arid and semi-arid regions. Water scarcity and inefficient irrigation methods can lead to crop failure and reduced yields.Soil Health: Soil health is essential for crop growth, but soil degradation from erosion, overuse, and chemical use can lead to reduced yields and nutrient-poor crops.Pests and Diseases: Crop pests and diseases can devastate crops, reducing yield and quality, and increasing the need for pesticides and herbicides.Labor Shortage: Farm labor shortages can lead to increased costs and reduced efficiency, especially during peak seasons.Access to Markets: Farmers may face challenges in accessing markets to sell their products, especially small-scale and subsistence farmers.Food Security: Despite advancements in farming practices, many regions still face food insecurity due to poverty, conflict, and lack of access to resources.Sustainable Farming: Ensuring that farming practices are sustainable and do not harm the environment is becoming increasingly important to consumers and policymakers.Addressing these issues will require a combination of technological advancements, policy changes, and changes in farming practices to ensure that farming remains a sustainable and profitable industry.
PROCESS OF SMART FARMING
The “SmartFarm” project involves several processes that are aimed at optimizing crop yield and sustainability through the use of IoT technology [3]. Agriculture, which provides a country with the necessary fuel, food, fibre, and feed, is its foundation. Due to the significant advancements in bioinformatics, which permeate many areas of our lives, the important industry has grown more adaptable and sophisticated. A significant chapter in the history of global agriculture is that of “smart agriculture,” which began with the use of several cutting-edge technologies during various agricultural practises, including pre-cultivation, cultivation, seedling, fertilisation, weed detection, irrigation, pesticide spraying, till harvesting, and also pot-harvesting [4]. The following are the key processes involved in the project:
Sensor deployment: The first step in the Smart Farm project is to deploy various sensors and devices in the farming area. This includes soil moisture sensors, temperature and humidity sensors, crop health monitoring sensors, and livestock monitoring sensors.Data collection: Once the sensors are deployed, they collect data on various aspects of the farming area, including soil moisture, temperature, humidity, crop health, and livestock behavior. This data is collected and transmitted to a central server for analysis.Data analysis: The data collected from the sensors is analyzed using various data analysis techniques, such as statistical analysis, machine learning algorithms, and predictive modeling. The analysis is used to identify trends, patterns, and anomalies in the data, which can be used to optimize farming operations.Decision-making: Based on the insights gained from the data analysis, farmers can make informed decisions about irrigation, pest control, crop management, and livestock health. These decisions are aimed at optimizing crop yield and promoting sustainability in farming practices.Feedback loop: The SmartFarm project also involves a feedback loop, where the decisions made by farmers are fed back into the system, and the sensors and devices are adjusted accordingly. This allows the system to continuously learn and improve over time.Overall, the SmartFarm project involves a data-driven approach to farming, where IoT technology is used to optimize farming operations and promote sustainability. By collecting and analyzing data from various sensors and devices, farmers can make informed decisions that lead to increased productivity and reduced environmental impact.
There are several algorithms that can be used in smart farming to optimize crop yield and reduce resource waste [5]. Here are some examples:
Predictive Analytics
To evaluate vast volumes of gathered data, predictive analytics use machine learning algorithms from various sensors on the farm, such as soil moisture sensors, weather stations, and drone images, to forecast crop yields, plant diseases, and pest infestations.
Precision Farming
Precision farming involves using sensors and GPS technology to gather information on crop health and growth, soil conditions, and weather patterns. This information is then used to adjust the amount of fertilizers, water, and other inputs used in farming, reducing waste and maximizing yield.
Autonomous Equipment
Autonomous equipment, such as self-driving tractors and drones, can be programmed with machine learning algorithms to perform tasks such as planting, irrigation, and pesticide application, reducing labor costs and increasing efficiency.
Image Processing
Image processing algorithms can be used to analyze images captured by drones or other cameras to identify crop diseases, nutrient deficiencies, and other issues that may impact crop yield.
Blockchain Technology
Blockchain technology can be used to track the entire supply chain, from seed to final product, ensuring that all steps are transparent and traceable. This can help farmers to maintain high-quality standards and ensure food safety.
Decision Support Systems
Decision support systems use algorithms to analyze data and provide farmers with recommendations on the best course of action for planting, harvesting, and managing crops. This can help farmers to optimize crop yield and reduce waste.
Overall, these algorithms can help farmers to make data-driven decisions, improve crop yield, and reduce resource waste, resulting in more sustainable and profitable agriculture.
AUTONOMOUS EQUIPMENT FOR SMART FARMING
Autonomous equipment is becoming increasingly popular in smart farming as it allows farmers to increase efficiency, reduce labour costs, and optimize the use of resources [5, 6], shown in Fig. (1).
Here are some examples of autonomous equipment used in smart farming:
Fig. (1)) Autonomous Equipment for smart farming.Autonomous Tractors
Self-driving tractors can be programmed to perform tasks such as planting, tillage, and harvesting without the need for a human operator. They use sensors and GPS technology to navigate the field and perform tasks with precision.
Drones
Drones equipped with cameras and sensors can be used for a variety of tasks, such as crop mapping, plant counting, and monitoring crop health. They can also be used to apply pesticides and fertilizers with greater precision, reducing waste and environmental impact.
Robotic Harvesters
Robotic harvesters are designed to pick and sort fruits and vegetables without damaging them. They use computer vision and machine learning algorithms to identify ripe products and harvest them with precision.
Autonomous Seeders
Autonomous seeders can be used to plant crops with greater accuracy and efficiency. They can be programmed to plant seeds at precise depths and intervals, reducing the need for manual labor.
Autonomous Weeders
Autonomous weeders use machine learning algorithms to identify and remove weeds without harming the crops. They can be programmed to target specific types of weeds, reducing the use of herbicides.
Overall, autonomous equipment can help farmers to reduce labor costs, optimize resource use, and increase crop yield, resulting in more sustainable and profitable agriculture
In conclusion, smart farming has the potential to revolutionize agriculture by using IoT technology to optimize crop yield and sustainability. By collecting data from sensors and other devices, farmers can make data-driven decisions on when to plant, irrigate, and fertilize their crops. This can result in more efficient use of resources and higher crop yields. Additionally, smart farming can decrease waste and the use of pesticides and fertilisers to lessen the impact of agriculture on the environment. The IoT technology used in smart farming includes a variety of devices such as soil sensors, weather stations, drones, and autonomous equipment like tractors and harvesters. Machine learning algorithms can be applied to this data to provide insights and recommendations to farmers.
By adopting smart farming practices, farmers can improve their bottom line by reducing costs, increasing yields, and improving the quality of their products. Additionally, smart farming can help to ensure food security by producing more food with fewer resources, and improving the resilience of farming operations against climate change.
In general, smart farming might make agriculture a more efficient and sustainable enterprise and it is essential to invest in the development and adoption of these technologies to meet the growing demand for food while preserving our natural resources for future generations.
SENSORS IN SMART FARMS
There are several types of sensors that are commonly used in smart farms to collect data on various aspects of crop growth and environmental conditions. Some of the most common types of sensors used in smart farms include:
Soil Sensors
These sensors are used to measure soil moisture, temperature, and nutrient levels, which can help farmers determine when to irrigate, fertilize, or adjust other growing conditions.
In Fig. (2), soil moisture sensors are the usual name for sensors that monitor the volumetric water content. Volumetric Water Content (VWC), sometimes known as “soil moisture,” is a measurement of how much water is retained in the soil and is stated as a percent of the entire mixture. The kind of soil affects both how much water a soil can hold and whether it is accessible to plants. For many applications, measuring soil moisture is a crucial quality (not limited to irrigation). Sensors can measure soil moisture using a number of different technologies and methodologies.
Fig. (2)) Taxonomy of Soil Sensors.Tensiometers (Soil Matric Potential Sensors) calculate the matric potential or soil water potential. The force needed to extract water from the soil, known as soil matric potential, is a sign of stress for plants and crops. It may be used to calculate the soil's water fluxes and the amount of water that is stored there. The neutron probe method is regarded to be the most accurate for measuring soil moisture.
Weather Sensors
These sensors are used to collect data on temperature, humidity, wind speed and direction, and precipitation, which can help farmers make informed decisions about when to plant, irrigate, or harvest crops.
Typically, the environmental variables that weather sensors measure are used to classify them. Types of weather sensors are as follows:
Multi-weather sensors: Multi-weather sensors, as their name suggests, measure a number of variables using a single device. An illustration of a high-precision multi-weather sensor is the LAMBRECHT meteo WS7.Humidity and temperature sensors: Some of the most popular weather sensors are temperature and humidity sensors. They may be used to determine a plant's risk of harm from too much or too little moisture, compute a heat index, and more.Wind speed & quality sensors: Wind speed, direction, and quality sensors are used by people in a number of significant ways to analyse air-flow. Understanding winds is essential for choosing the best paths, conserving fuel, and ensuring the safety of the crew and cargo, for instance, in the marine industry.Water quality, level, & flow sensors: To keep communities safe, it is crucial to comprehend the volume, flow, and level of both natural and man-made bodies of water.Water quality sensors: These sensors measure the quality of water used for irrigation and animal husbandry, helping farmers identify potential issues and ensure the health of their crops and livestock.Sunlight & UV sensors: UV sensors measure the amount of sun radiation that enters a certain environment.Lightning sensors: Lightning sensors, as the name suggests, find lightning.Atmospheric pressure sensors: Understanding pressure is essential for many machine-driven industrial operations as well as comprehending the weather.Precipitation sensors: Rain, snow, sleet, and hail are all types of precipitation that are measured using precipitation sensors.Light sensors: These sensors are used to monitor the amount and quality of light that crops are receiving, which can help farmers optimize plant growth and yield.Air quality sensors: These sensors measure the quality of the air in the farming environment, including factors such as carbon dioxide and ammonia levels, which can impact crop growth and animal health.Plant Sensors
These sensors can measure various aspects of plant growth, such as photosynthesis rates, leaf temperature, and chlorophyll content, which can help farmers detect early signs of stress, disease, or other issues.
Plant disease sensors: Plant pathology uses digital photographs as crucial instruments for determining the health of plants. Red, Green, and Blue (RGB) digital pictures from digital cameras provide an easy source for illness detection, quantification, and diagnosis.Pest and disease sensors: These sensors can identify pests and illnesses in crops, enabling farmers to take preventative measures before they spread and do serious harm.Spectral sensors: Spectral sensors are often grouped according to their spectral resolution (i.e., the quantity and width of wavebands that can be monitored), spatial scale, and detector type (i.e., imaging or non-imaging sensor systems).Thermal sensors: Infrared thermography (IRT) measures plant temperature and has relationships with plant water status [7], crop stand microclimate [8], and variations in transpiration brought on by early plant pathogen infections [9].Fluorescence imaging Several chlorophyll fluorescence metrics are employed to calculate variations in plant photosynthetic activity.Nutrient Sensors
These sensors are used to monitor nutrient levels in the soil and water, which can help farmers optimize fertilization practices and avoid over-fertilization. For detecting soil nutrients, two popular types of potentiometric electrochemical sensors are ion-selective electrodes (ISE) and ion-selective field effect transistors (ISFET).
GPS Sensors
These sensors can be used to track the location of farming equipment, such as tractors and harvesters, and optimize routes and schedules for maximum efficiency.
Overall, the use of IoT sensors in smart farming can provide farmers with real-time data and insights that can help them make better decisions about their farming practices, leading to increased efficiency, productivity, and sustainability.
BENEFITS OF SMART FARMING
Smart farming, also known as precision agriculture, is an innovative approach to farming that involves using advanced technology to optimize crop yields, reduce waste, and increase efficiency [4]. Here are some of the key benefits of smart farming:
Improved Efficiency
Smart farming technologies such as sensors, drones, and GPS systems can help farmers monitor their crops in real-time and make data-driven decisions about when to water, fertilize, or harvest. This can help farmers optimize their use of resources and reduce waste, leading to increased efficiency and cost savings.
Increased Yields
By using precision agriculture techniques, farmers can gain a better understanding of their crops and their environment, which can help them optimize their growing conditions to achieve higher yields. For example, farmers can use sensors to monitor soil moisture levels and adjust irrigation systems accordingly, which can help plants grow faster and healthier.
Reduced Environmental Impact
Smart farming can help farmers reduce their environmental footprint by using resources more efficiently and reducing waste. By optimizing irrigation and fertilizer use, farmers can reduce runoff and pollution, which can have a positive impact on the environment.
Improved Quality and Safety
By monitoring their crops closely, farmers can detect problems early on and take action to prevent crop damage or contamination. This can help improve the quality and safety of their crops, which can lead to higher prices and increased demand from consumers.
Increased Profitability
By using precision agriculture techniques, farmers can optimize their yields and reduce their costs, which can lead to increased profitability. Smart farming can also help farmers diversify their income streams by enabling them to produce more crops on the same amount of land.
Overall, smart farming has the potential to transform the agricultural industry by increasing efficiency, improving yields, and reducing the environmental impact of farming.
THE IMPACT OF CLIMATE ON SMART FARMING
Climate has a significant impact on smart farming, as it affects crop growth and environmental conditions that are critical for farming. Climate change, in particular, has become a major challenge for farmers worldwide, as it has led to unpredictable weather patterns, more frequent extreme weather events, and changes in temperature and rainfall that can impact crop growth and yields [10].
Smart farming technologies can help farmers adapt to these changes by providing real-time data on weather conditions and soil moisture levels, allowing them to make informed decisions about irrigation, fertilization, and other farming practices. For example, if a smart farm sensor detects low soil moisture levels, the farmer can use that information to adjust irrigation practices to ensure that crops receive enough water to thrive.
In addition, smart farming technologies can help farmers reduce their environmental impact and carbon footprint by optimizing farming practices to use fewer resources and produce less waste. For example, precision irrigation can reduce water use, while precision fertilization can reduce the use of synthetic fertilizers, which can be harmful to the environment if overused.
Overall, smart farming technologies can help farmers adapt to the impacts of climate change and mitigate their environmental impact, while also improving crop yields and profitability. However, it is important to continue developing and improving these technologies to ensure that farmers have the tools they need to succeed in an increasingly unpredictable climate.
CASE STUDY OF SMART FARMING USING IOT
One example of smart farming using IoT is the project conducted by John Deere, a leading manufacturer of agricultural machinery, in collaboration with Intel and Climate Corporation. The project aimed to improve the efficiency and sustainability of farming operations by collecting and analyzing data from sensors and other IoT devices.
The project involved the deployment of sensors and IoT devices to gather data on soil moisture levels, temperature, and other environmental factors, as well as data on crop growth and yield. The data was then transmitted to a central hub, where it was analyzed using advanced algorithms to provide insights and recommendations to farmers.
Through this project, farmers were able to make more informed decisions about when and how much to water their crops, how much fertilizer to use, and when to harvest. This resulted in improved crop yields, reduced waste, and increased efficiency.
The project also enabled farmers to monitor and manage their operations remotely, using mobile devices and other IoT-enabled technologies. This allowed farmers to stay connected and informed, even when they were not physically on the farm.
The IoT is transforming the agricultural industry by giving farmers a wide range of tools to handle various problems they encounter in the field. With IoT-enabled devices, farmers can access their farms at any time and from practically anywhere [9].
Overall, the use of IoT in smart farming has the potential to transform the agriculture industry by providing farmers with new tools and insights to optimize their farming practices, reduce waste, and increase sustainability.
