In a Polytechnic in AME College in India, you will study a wide range of subjects that build your foundation in aircraft systems, maintenance procedures, and aviation safety. The curriculum is designed to help you understand how an aircraft works, how its parts are maintained, and how safety standards are followed in aviation.
You will begin with core fundamentals like Aircraft Structures & Materials, where you learn about different aircraft components, metals, composites, and how they behave under stress. This is followed by subjects like Aerodynamics, which explains how aircraft fly, how lift is generated, and how forces act on an aeroplane during flight.
You’ll also study Propulsion Systems, which covers piston engines, turbine engines, jet engines, and their working principles. This helps you understand everything about power generation in an aircraft. Another important part of the syllabus is Avionics and Aircraft Electrical Systems, where you learn about navigation systems, communication equipment, sensors, wiring, circuits, and electrical safety in aircraft.
As you move ahead, you’ll learn Maintenance Practices, where hands-on training becomes a major part. You get practical exposure to inspection methods, repair techniques, safety protocols, tools, equipment handling, and workshop procedures. You’ll also study Aviation Legislation, which teaches you the rules, regulations, and standards set by national and international aviation authorities for maintenance, safety, and aircraft certification.
During the Diploma in Electronics and Communication Engineering College in Delhi NCR, students study a broad and well-structured curriculum that blends fundamental engineering concepts with specialized knowledge in electronics and communication technologies. The subjects taught throughout the three-year program are designed to help students understand how electronic devices and communication systems work, are built, and are maintained in real-world industries.
In the early phase of the course, students begin by learning the essential sciences that support all engineering disciplines, including applied physics and applied mathematics. These subjects create a foundation for understanding how electricity, magnetism, signals, and systems function. As students move forward, they begin to explore material science, where they understand the properties of different materials used in building electronic components and circuits.
As the course advances, it introduces students to analog and digital electronics, which are central to understanding how modern devices operate. Students learn how signals are generated, amplified, filtered, and interpreted, both in analog and digital forms. In the study of communication systems, students are exposed to the technologies used in radio, television, mobile phones, and satellite transmissions. This includes topics like modulation, frequency analysis, and transmission protocols that are crucial for sending and receiving information accurately and efficiently.
One of the most critical areas of study is microprocessors and microcontrollers. These are small computing units that form the heart of many electronic systems. Students learn how to program them and use them in embedded applications such as automation, robotics, and smart electronics. Alongside this, subjects like audio-video systems allow students to explore the science behind broadcasting, sound engineering, and multimedia devices.
In the later stages of the diploma, signal processing becomes a key area of focus. Students understand how to manipulate and improve signals like voice, video, or data, and prepare them for further processing or transmission. Embedded systems become increasingly important as students begin to build devices that interact with the physical world using sensors and actuators controlled by software and microcontrollers.
Practical training is an ongoing part of the curriculum, with students spending time in labs where they can build circuits, program devices, and test electronic systems. These sessions complement their classroom learning and prepare them for real-life engineering challenges.