CITS Electronics Mechanic Trade Syllabus (English)

Overview

The CITS Electronics Mechanic trade is a one-year program designed to train instructors to teach electronics repair, circuit design, and maintenance skills in ITIs. Divided into two semesters, the course covers Trade Technology (theory and practical), Training Methodology, Engineering Drawing, Workshop Calculation & Science, and Soft Skills. It aligns with NSQF Level 5 standards, emphasizing advanced electronics, embedded systems, and effective teaching methods. The syllabus adheres to the latest DGT guidelines for outcome-based learning.

Semester 1 Syllabus

Trade Technology - Theory

• Introduction to CITS and Electronics Mechanic: Role of instructors, scope of the electronics industry, and trends (e.g., IoT, wearable technology).

• Safety and Standards:

  • Advanced electrical and ESD (Electrostatic Discharge) safety protocols.

  • Compliance with IS, IEC, and IPC standards for electronics.

  • Safe handling of tools, chemicals, and soldering equipment.

• Electronics Fundamentals:

  • Advanced concepts: Semiconductors, diodes, transistors, and op-amps.

  • Analog and digital electronics: Signal processing and logic gates.

• Electronic Components:

  • Types and applications: Resistors, capacitors, inductors, and ICs.

  • Component testing and selection criteria.

• Circuit Design and Analysis:

  • Designing basic circuits: Amplifiers, oscillators, and filters.

  • Use of simulation software (e.g., Multisim, LTspice).

• Soldering and PCB Technology:

  • Advanced soldering techniques: Surface-mount technology (SMT).

  • PCB design basics: Layout and Gerber file generation.

• Measuring Instruments:

  • Advanced use of multimeters, oscilloscopes, and signal generators.

  • Calibration and troubleshooting of instruments.

• Quality Control: Inspection of circuits, soldering quality, and compliance with standards.

Trade Technology - Practical

• Implement ESD safety protocols and use PPE in electronics labs.

• Test and analyze electronic components (e.g., diodes, ICs) using multimeters.

• Design and simulate basic circuits (e.g., amplifiers) using Multisim/LTspice.

• Perform advanced soldering for SMT components on PCBs.

• Create a simple PCB layout using software (e.g., Eagle, KiCAD).

• Use oscilloscopes and signal generators to analyze circuit performance.

• Troubleshoot and repair basic electronic circuits.

• Conduct quality checks on soldered joints and PCB assemblies.

• Document circuit design and testing procedures.

Training Methodology

• Instructor Role: Lesson planning, teaching strategies, and student evaluation techniques.

• Communication Skills: Clear verbal and non-verbal communication for effective training.

• Classroom Management: Engaging diverse learners and ensuring discipline.

• Instructional Aids: Using projectors, digital tools, and e-learning platforms.

• Practical Training: Demonstrating electronics tasks, guiding practice, and offering feedback.

Semester 2 Syllabus

Trade Technology - Theory

• Advanced Electronics:

  • Microcontrollers: Architecture, programming (e.g., Arduino, PIC).

  • Embedded systems: Sensors, actuators, and interfacing.

• Communication Systems:

  • Basics of analog and digital communication: AM, FM, and modulation.

  • Introduction to wireless communication (e.g., Wi-Fi, Bluetooth).

• Power Electronics:

  • Power supplies: SMPS, UPS, and voltage regulators.

  • Inverters and converters: Design and applications.

• Automation and Control:

  • Programmable Logic Controllers (PLCs): Basics and applications.

  • Relay logic and control circuits.

• Consumer Electronics:

  • Repair and maintenance of devices: TVs, audio systems, and mobiles.

  • Troubleshooting common faults in consumer electronics.

• Industry 4.0 in Electronics:

  • IoT applications: Smart devices and home automation.

  • AI-based diagnostics and predictive maintenance in electronics.

• Entrepreneurship:

  • Starting an electronics repair or manufacturing business: Business plans, budgeting, and marketing.

  • Client acquisition and service strategies.

• Legal and Ethical Issues: Intellectual property, e-waste regulations, and ethical repair practices.

Trade Technology - Practical

• Program microcontrollers (e.g., Arduino) for embedded system projects.

• Design and test communication circuits (e.g., FM transmitter).

• Build and troubleshoot power supply circuits (e.g., SMPS, inverters).

• Set up and program PLCs for basic control applications.

• Repair consumer electronics (e.g., TVs, mobile chargers) in a lab setup.

• Develop an IoT-based project (e.g., smart home device) using sensors and microcontrollers.

• Perform predictive maintenance checks on electronic systems.

• Create a business plan for an electronics repair or service business.

• Document compliance with e-waste and safety regulations.

Training Methodology

• Advanced Teaching Techniques: Micro-teaching, flipped classrooms, and blended learning.

• Assessment and Evaluation: Designing tests, practical assessments, and grading systems.

• Digital Tools: Using Learning Management Systems (LMS), virtual labs, and e-learning modules.

• Mentoring: Supporting trainees in skill development and career planning.

• Project-Based Learning: Guiding trainees to complete electronics projects (e.g., IoT device).

Additional Components

Workshop Calculation & Science

• Calculations: Circuit calculations (e.g., resistance, power), signal frequency analysis.

• Science: Semiconductor physics, electromagnetic waves, and properties of electronic materials.

Engineering Drawing

• Drawing Basics: Circuit diagrams, PCB layouts, and schematic diagrams.

• Schematics: Wiring diagrams for control circuits and embedded systems.

Soft Skills & Employability Skills

• Communication: Client consultations, report writing, and technical presentations.

• Leadership: Managing electronics teams and projects.

• Time Management: Meeting repair and project deadlines.

Assessment

• Internal Assessment: Continuous evaluation via assignments, practicals, and tests.

• Final Examination: Theory and practical exams conducted by NCVT at year-end.

• Project Work: Complete an electronics project (e.g., embedded system design) and teaching demonstration.