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This book focuses on the numerous energy harvesting techniques and their system implementation towards the fulfilment of energy requirements in compact electronic devices. These cover a wide range of applications in portable devices, bio-medical services, agriculture needs, mechanical systems, sensor networks, automobiles, food sector, home appliances, industry needs, etc. The authors detail energy harvesting methods using the latest technologies in acoustics, bio-chemical, thermal, artificial light, fluid flow, vibrations, EM energy, RF energy, piezoelectric, electrostatic, photovoltaic, thermoelectric, hybrid harvesting, ultrasonic, infrared, light, wind, and solar. The book is intended for researchers, academics, professionals, and students in energy harvesting.
Kinetic energy harvesting converts movement or vibrations into electrical energy, enables battery free operation of wireless sensors and autonomous devices and facilitates their placement in locations where replacing a battery is not feasible or attractive. This book provides an introduction to operating principles and design methods of modern kinetic energy harvesting systems and explains the implications of harvested power on autonomous electronic systems design. It describes power conditioning circuits that maximize available energy and electronic systems design strategies that minimize power consumption and enable operation. The principles discussed in the book will be supported by real case studies such as battery-less monitoring sensors at water waste processing plants, embedded battery-less sensors in automotive electronics and sensor-networks built with ultra-low power wireless nodes suitable for battery-less applications.
The transformation of vibrations into electric energy through the use of piezoelectric devices is an exciting and rapidly developing area of research with a widening range of applications constantly materialising. With Piezoelectric Energy Harvesting, world-leading researchers provide a timely and comprehensive coverage of the electromechanical modelling and applications of piezoelectric energy harvesters. They present principal modelling approaches, synthesizing fundamental material related to mechanical, aerospace, civil, electrical and materials engineering disciplines for vibration-based energy harvesting using piezoelectric transduction. Piezoelectric Energy Harvesting provides the first comprehensive treatment of distributed-parameter electromechanical modelling for piezoelectric energy harvesting with extensive case studies including experimental validations, and is the first book to address modelling of various forms of excitation in piezoelectric energy harvesting, ranging from airflow excitation to moving loads, thus ensuring its relevance to engineers in fields as disparate as aerospace engineering and civil engineering. Coverage includes: Analytical and approximate analytical distributed-parameter electromechanical models with illustrative theoretical case studies as well as extensive experimental validations Several problems of piezoelectric energy harvesting ranging from simple harmonic excitation to random vibrations Details of introducing and modelling piezoelectric coupling for various problems Modelling and exploiting nonlinear dynamics for performance enhancement, supported with experimental verifications Applications ranging from moving load excitation of slender bridges to airflow excitation of aeroelastic sections A review of standard nonlinear energy harvesting circuits with modelling aspects.
With its inclusion of the fundamentals, systems and applications, this reference provides readers with the basics of micro energy conversion along with expert knowledge on system electronics and real-life microdevices. The authors address different aspects of energy harvesting at the micro scale with a focus on miniaturized and microfabricated devices. Along the way they provide an overview of the field by compiling knowledge on the design, materials development, device realization and aspects of system integration, covering emerging technologies, as well as applications in power management, energy storage, medicine and low-power system electronics. In addition, they survey the energy harvesting principles based on chemical, thermal, mechanical, as well as hybrid and nanotechnology approaches. In unparalleled detail this volume presents the complete picture -- and a peek into the future -- of micro-powered microsystems.
The use of energy it is argued started about two million years ago when humans started cooking their food using firewood. As humans developed new skills with increased activities, energy interaction and usage emerged. Energy was used not only for domestic functions but also for space applications. With industrialization, humans realized that energy was needed to move machines and do other things as well. In this quest, and without understanding the consequences of using fossil fuels extensively, many problems arose. Researchers in energy embarked on a journey to study different forms of energy. To understand different needs, researchers have tried to come up with ways in which small-scale energy harvesting can be adapted to different needs that do not require heavy-duty energy production.This book attempts to present a number of ideas regarding a few selected small-scale energy harvesting methods and techniques as well as theories and products that may be helpful in improving the quality of life. Some of the new products are still in the prototype stage, while others are already being utilized. Many researchers in small-scale energy harvesting and those aspiring to follow this path of research will find this book not only motivating but also a useful guide in their endeavors.
An indispensable guide for engineers and data scientists in design, testing, operation, manufacturing, and maintenance A road map to the current challenges and available opportunities for the research and development of Prognostics and Health Management (PHM), this important work covers all areas of electronics and explains how to: assess methods for damage estimation of components and systems due to field loading conditions assess the cost and benefits of prognostic implementations develop novel methods for in situ monitoring of products and systems in actual life-cycle conditions enable condition-based (predictive) maintenance increase system availability through an extension of maintenance cycles and/or timely repair actions; obtain knowledge of load history for future design, qualification, and root cause analysis reduce the occurrence of no fault found (NFF) subtract life-cycle costs of equipment from reduction in inspection costs, downtime, and inventory Prognostics and Health Management of Electronics also explains how to understand statistical techniques and machine learning methods used for diagnostics and prognostics. Using this valuable resource, electrical engineers, data scientists, and design engineers will be able to fully grasp the synergy between IoT, machine learning, and risk assessment.
This book describes power management integrated circuits (PMIC), for power converters and voltage regulators necessary for energy efficient and small form factor systems. The authors discuss state-of-the-art PMICs not only for battery powered wearable devices, but also energy harvesting-based devices. The circuits presented support voltage scaling to reduce the overall average power consumption of a wearable device, resulting in longer device operating time. The discussion includes many designs, control techniques and approaches to distribute efficiently the power among different blocks in the device. • Demonstrates for readers how to innovate in designing power management integrated circuits (PMIC) suitable for wearable devices, powered by either battery or harvesting energy; • Introduces a dual outputs switched capacitor, using a single voltage regulator to minimize the area overhead and discusses the effect of having more than two outputs on the area and power efficiency; • Introduces a novel clock-less digital LDO regulator that eliminates the use of the clocked comparator and serial shift register in the conventional design; • Presents experimental results of energy harvesting-based power management units (PMU), using different combinations of power converters and voltage regulators, providing a guide for designers to select the appropriate option based on device requirements.
Accelerometer Manufacturing 1. Market Overview: The global accelerometer manufacturing industry has experienced significant growth over the past few years, driven by the increasing demand for accurate motion sensing devices across various sectors such as automotive, aerospace, healthcare, and consumer electronics. Accelerometers have become essential components in a wide range of applications, including navigation systems, gaming consoles, and wearable devices. The market is characterized by rapid technological advancements, leading to the development of smaller, more precise, and energy-efficient accelerometers. 2. Market Segmentation: The market for accelerometers can be segmented based on technology (MEMS-based accelerometers, piezoelectric accelerometers, and others), application (automotive, aerospace, industrial, healthcare, consumer electronics, and others), and geography. MEMS-based accelerometers dominate the market share due to their compact size, low cost, and high accuracy, making them ideal for various applications. 3. Regional Analysis: • North America: The United States and Canada lead the market due to the presence of key manufacturers and technological advancements in the region. • Europe: Countries like Germany, France, and the United Kingdom are major contributors, driven by the automotive and aerospace industries. • Asia-Pacific: China, Japan, and South Korea are witnessing significant growth, fueled by the expanding consumer electronics market and increasing investments in research and development. 4. Market Drivers: • Technological Advancements: Ongoing research and development activities are leading to the introduction of advanced accelerometers, enhancing their sensitivity and accuracy. • Growing Automotive Industry: Increasing demand for accelerometers in automotive safety systems, vehicle navigation, and stability control systems is driving market growth. • Rising IoT Adoption: Accelerometers are integral to IoT devices, boosting demand for motion sensing components. • Healthcare Applications: Accelerometers play a crucial role in medical devices, wearable health monitors, and telemedicine, contributing to market expansion. 5. Market Challenges: • Intense Competition: The market is highly competitive with numerous established players, leading to price wars and margin pressures. • Supply Chain Disruptions: Global supply chain disruptions and shortages of raw materials can hinder manufacturing processes. • Regulatory Compliance: Adherence to stringent regulations and quality standards poses challenges for manufacturers. 6. Opportunities: • Emerging Economies: Untapped markets in developing countries offer significant growth opportunities for accelerometer manufacturers. • Smart Industry: Accelerometers are vital for predictive maintenance in smart manufacturing, opening avenues for market expansion. • Collaborative Partnerships: Collaborations with technology companies and research institutions can lead to innovative product developments. 7. Future Outlook: The accelerometer manufacturing industry is poised for substantial growth, driven by the proliferation of IoT devices, advancements in sensor technologies, and the increasing integration of accelerometers in emerging applications such as virtual reality and robotics. As industries continue to demand precise motion sensing solutions, the market is anticipated to witness steady growth globally. Conclusion: In conclusion, the global accelerometer manufacturing industry is thriving amid technological innovations and increasing applications across diverse sectors. While challenges exist, strategic partnerships, innovation, and market diversification will be key to overcoming these hurdles. Manufacturers must focus on research and development, quality assurance, and exploring new market segments to stay competitive and capitalize on the growing demand for accurate motion sensing devices worldwide.
Energy Harvesting Technologies provides a cohesive overview of the fundamentals and current developments in the field of energy harvesting. In a well-organized structure, this volume discusses basic principles for the design and fabrication of bulk and MEMS based vibration energy systems, theory and design rules required for fabrication of efficient electronics, in addition to recent findings in thermoelectric energy harvesting systems. Combining leading research from both academia and industry onto a single platform, Energy Harvesting Technologies serves as an important reference for researchers and engineers involved with power sources, sensor networks and smart materials.
(Content updated) Agri-Tools Manufacturing 1. Market Overview: The Agri-Tools Manufacturing industry is a vital part of the agriculture sector, providing essential equipment and machinery to support farming operations. Growth is driven by the increasing demand for advanced and efficient farming tools to meet the rising global food production requirements. 2. Market Segmentation: The Agri-Tools Manufacturing market can be segmented into several key categories: a. Hand Tools: • Basic manual tools used for tasks like planting, weeding, and harvesting. b. Farm Machinery: • Larger equipment such as tractors, Plows, and combines used for field cultivation and crop management. c. Irrigation Equipment: • Tools and systems for efficient water management and irrigation. d. Harvesting Tools: • Machinery and hand tools for crop harvesting and post-harvest processing. e. Precision Agriculture Tools: • High-tech equipment including GPS-guided machinery and drones for precision farming. f. Animal Husbandry Equipment: • Tools for livestock management and animal husbandry practices. 3. Regional Analysis: The adoption of Agri-Tools varies across regions: a. North America: • A mature market with a high demand for advanced machinery, particularly in the United States and Canada. b. Europe: • Growing interest in precision agriculture tools and sustainable farming practices. c. Asia-Pacific: • Rapidly expanding market, driven by the mechanization of farming in countries like China and India. d. Latin America: • Increasing adoption of farm machinery due to the region's large agricultural sector. e. Middle East & Africa: • Emerging market with potential for growth in agri-tools manufacturing. 4. Market Drivers: a. Increased Farming Efficiency: • The need for tools and machinery that can increase farm productivity and reduce labour costs. b. Population Growth: • The growing global population requires more efficient farming practices to meet food demands. c. Precision Agriculture: • The adoption of technology for data-driven decision-making in farming. d. Sustainable Agriculture: • Emphasis on tools that support sustainable and eco-friendly farming practices. 5. Market Challenges: a. High Initial Costs: • The expense of purchasing machinery and equipment can be a barrier for small-scale farmers. b. Technological Adoption: • Some farmers may be resistant to adopting new technology and machinery. c. Maintenance and Repairs: • Ensuring proper maintenance and timely repairs can be challenging. 6. Opportunities: a. Innovation: • Developing advanced and efficient tools using IoT, AI, and automation. b. Customization: • Offering tools tailored to specific crops and regional needs. c. Export Markets: • Exploring export opportunities to regions with growing agricultural sectors. 7. Future Outlook: The future of Agri-Tools Manufacturing looks promising, with continued growth expected as technology continues to advance and the need for efficient and sustainable agriculture practices increases. Innovations in machinery and equipment, along with the adoption of precision agriculture tools, will play a significant role in transforming the industry and addressing the challenges faced by the agriculture sector. Conclusion: Agri-Tools Manufacturing is a cornerstone of modern agriculture, providing farmers with the equipment and machinery they need to feed a growing global population. As the industry continues to evolve, there will be opportunities for innovation and collaboration to develop tools that are not only efficient but also environmentally friendly. Agri-tools manufacturers play a critical role in supporting sustainable and productive farming practices, making them essential contributors to the global food supply chain.