Prasun Barua

CMOS technology, short for Complementary Metal Oxide Semiconductor, is a fundamental technology in the design and fabrication of integrated circuits (ICs). It plays a critical role in various electronic components, including microprocessors, batteries, and digital sensors. CMOS technology is known for its significant advantages, such as low power consumption and high integration density, making it the preferred choice in modern electronics. Table of Contents 1. Definition of CMOS Technology 2. Historical Background 3. How CMOS Technology Works 4. Advantages of CMOS Technology 5. Applications of CMOS Technology 6. Disadvantages of CMOS Technology 7. The Future of CMOS Technology 8. FAQs 1. Definition of CMOS Technology CMOS technology is a process technology used to fabricate integrated circuits. It utilizes complementary and symmetrical pairs of p-type and n-type MOSFETs (Metal-Oxide

A paper battery is an innovative energy storage device that combines the functionalities of a battery and a supercapacitor. It is constructed using a thin, lightweight paper substrate that is treated to improve its electrical conductivity. Paper batteries present a sustainable alternative to traditional batteries due to their eco-friendly materials and lightweight design. As technology advances and the demand for renewable energy sources grows, paper batteries are becoming a focal point for researchers and industries alike. Table of Contents History of Paper Batteries Design and Composition How Paper Batteries Work Types of Paper Batteries Applications of Paper Batteries Advantages and Disadvantages The Future of Paper Batteries FAQs 1. History of Paper Batteries The concept of paper batteries emerged in the early 21st century, driven by the need for lighter, more flexible energy storage solutions. The first significant developments came in 2007 w

An electric generator is a device that converts mechanical energy into electrical energy, typically through electromagnetic induction. It plays a critical role in the production of electricity in various applications, ranging from portable power sources to large power plants. Understanding how an electric generator works involves a look at its basic principles, components, and different types available. Table of Contents Principle of Operation Main Components of an Electric Generator Types of Electric Generators Applications of Electric Generators FAQs 1. Principle of Operation The fundamental principle behind electric generators is Faraday’s law of electromagnetic induction, which states that a change in magnetic field within a closed loop of wire induces an electromotive force (EMF) in the wire. This process can be broken down into several key steps: The mechanical energy (from a turbine, engine, or other sources) is used to rotate a co