ICTQual Level 6 Diploma in Electrical Engineering 360 Credits – Three Years

Energize Your Career with Industry-Ready Electrical Skills.

ATTICS International is Directly Approved Centre of ICTQual AB

Course Overview

The ICTQual Level 6 Diploma in Electrical Engineering (360 Credits – Three Years) is a comprehensive qualification designed to develop advanced technical expertise in electrical systems, power distribution, and modern industrial technologies. This program provides in-depth knowledge of electrical circuit design, power generation and transmission, control systems, renewable energy technologies, automation, and electrical safety practices. It integrates theoretical foundations with practical applications to prepare learners for real-world engineering challenges in industrial, commercial, and infrastructure environments.

Over the three-year duration, students build industry-relevant competencies aligned with international engineering standards and employer requirements. The diploma equips graduates with the skills needed to design, install, maintain, and manage electrical systems while ensuring safety, efficiency, and sustainability. This qualification supports career progression into roles such as electrical engineer, maintenance supervisor, power systems technician, or automation specialist, and also provides a pathway to higher education and professional advancement in the global electrical engineering sector.

Course Structure

This is a three-year diploma program designed to build comprehensive Electrical Engineering knowledge and practical skills.

Total Credits: 360
Total Study Units: 36
Credits per Year: 120
Units per Year: 12

Study Units

Engineering Mathematics I
Fundamentals of Electrical Circuits
Principles of Electronics
Digital Logic Design
Electrical Machines and Transformers
Introduction to Control Systems
Engineering Drawing and CAD
Introduction to Microprocessors and Microcontrollers
Electrical Measurement and Instrumentation
Physics for Engineers
Health and Safety in Engineering
Sustainability in Electrical Engineering

Engineering Mathematics II
Power Systems Analysis
Analog Electronics
Embedded Systems and Applications
Electrical Energy Systems
Signals and Systems
Principles of Automation and Robotics
Industrial Electronics
Communication Systems Engineering
Renewable Energy Technologies
Electrical Project Management
Technical Report Writing and Research Methods

Advanced Power Electronics
Smart Grid Technology
Electrical Machine Design
Advanced Control Systems
High Voltage Engineering
Instrumentation and Process Control
Advanced Embedded Systems
Energy Storage and Conversion Systems
Wireless and Optical Communication
Electromagnetic Compatibility
Capstone Project
Professional Development and Ethical Practices

Learning Outcomes

Learning outcomes are clear statements that describe what a learner is expected to know, understand, and be able to do after completing a course or training program.

They define the specific skills, knowledge, and competencies students will gain and demonstrate upon successful completion.

Year 1: Foundational Knowledge

Engineering Mathematics I

Apply fundamental mathematical concepts such as calculus, algebra, and trigonometry to solve engineering problems.
Utilize mathematical tools to model and analyze simple electrical and electronic systems.

Fundamentals of Electrical Circuits

Analyze electrical circuits using basic laws and theorems, such as Ohm’s Law and Kirchhoff’s Laws.
Design and simulate basic electrical circuits for practical applications.

Principles of Electronics

Understand the operation of basic electronic components such as diodes and transistors.
Apply principles of electronics to design simple amplifiers and rectifiers.

Digital Logic Design

Develop logic circuits using combinational and sequential design techniques.
Use truth tables and Karnaugh maps to simplify and optimize digital circuits.

Electrical Machines and Transformers

Explain the working principles of electrical machines and transformers.
Perform calculations to determine the performance parameters of these devices.

Introduction to Control Systems

Understand the fundamental concepts of control systems, including feedback and stability.
Design simple control systems using proportional, integral, and derivative (PID) controllers.

Engineering Drawing and CAD

Create accurate engineering drawings using traditional and computer-aided design (CAD) tools.
Interpret and produce technical drawings for electrical and electronic components.

Introduction to Microprocessors and Microcontrollers

Understand the architecture and operation of microprocessors and microcontrollers.
Develop basic programs to control hardware systems using microcontrollers.

Electrical Measurement and Instrumentation

Use measurement tools and instruments to quantify electrical parameters like voltage, current, and resistance.
Evaluate the accuracy and reliability of electrical measurement systems.

Physics for Engineers

Apply fundamental physics concepts, such as electromagnetism and mechanics, to engineering scenarios.
Solve problems involving energy, force, and motion in electrical systems.

Health and Safety in Engineering

Identify potential hazards in engineering environments and implement appropriate safety measures.
Understand and comply with health and safety regulations in engineering practice.

Sustainability in Electrical Engineering

Evaluate the environmental impact of electrical engineering solutions and processes.
Incorporate sustainable practices and energy-efficient designs into engineering projects.

Year 2: Intermediate Proficiency

Engineering Mathematics II

Apply advanced mathematical methods, such as differential equations and complex numbers, to solve engineering problems.
Use numerical techniques to analyze electrical and electronic systems.

Power Systems Analysis

Analyze power generation, transmission, and distribution systems.
Use computational tools to evaluate the performance and stability of power systems.

Analog Electronics

Design and analyze analog circuits, including oscillators and amplifiers.
Understand the operation of integrated circuits in practical applications.

Embedded Systems and Applications

Design and program embedded systems for specific applications.
Integrate hardware and software components for efficient system operation.

Electrical Energy Systems

Understand the principles of electrical energy generation, conversion, and distribution.
Evaluate the performance and efficiency of different energy systems.

Signals and Systems

Analyze signals and their transformations in time and frequency domains.
Design and implement basic signal processing techniques.

Principles of Automation and Robotics

Understand the fundamentals of automation and robotic systems.
Design and simulate simple robotic systems using basic control techniques.

Industrial Electronics

Design and analyze circuits used in industrial applications, such as power electronics and drives.
Understand the role of electronic systems in industrial automation.

Communication Systems Engineering

Understand the principles of analog and digital communication systems.
Analyze the performance of communication systems under different conditions.

Renewable Energy Technologies

Evaluate the working principles and applications of renewable energy systems.
Design basic renewable energy solutions, such as solar and wind power systems.

Electrical Project Management

Plan and manage electrical engineering projects, including resource allocation and scheduling.
Apply project management tools to ensure successful project completion.

Technical Report Writing and Research Methods

Develop technical writing skills for documenting research and project findings.
Use research methods to solve engineering problems and present results effectively.

Year 3: Advanced Specialization and Application

Advanced Power Electronics

Design and analyze advanced power electronic converters and systems.
Understand the applications of power electronics in renewable energy and industrial automation.

Smart Grid Technology

Analyze the components and functionality of smart grid systems.
Develop solutions for integrating renewable energy sources into the smart grid.

Electrical Machine Design

Apply design principles to develop efficient and reliable electrical machines.
Evaluate the performance of machine designs under different operating conditions.

Advanced Control Systems

Design and implement advanced control strategies for dynamic systems.
Use computational tools to simulate and optimize control system performance.

High Voltage Engineering

Understand the principles of high voltage generation and insulation.
Analyze the behavior of high voltage systems under various conditions.

Instrumentation and Process Control

Design and implement advanced instrumentation systems for industrial applications.
Apply process control techniques to maintain system stability and efficiency.

Advanced Embedded Systems

Develop complex embedded systems using advanced programming and hardware techniques.
Integrate sensors and actuators for real-time control applications.

Energy Storage and Conversion Systems

Evaluate the performance of energy storage technologies, such as batteries and supercapacitors.
Design systems for efficient energy storage and conversion.

Wireless and Optical Communication

Understand the principles and technologies behind wireless and optical communication systems.
Analyze the performance of communication systems in different environments.

Electromagnetic Compatibility

Identify and mitigate electromagnetic interference in electrical and electronic systems.
Design systems to meet electromagnetic compatibility standards.

Capstone Project

Apply theoretical and practical knowledge to design and implement a comprehensive engineering project.
Demonstrate project management, teamwork, and problem-solving skills.

Professional Development and Ethical Practices

Understand the ethical responsibilities of an electrical engineer and the importance of professionalism.
Develop strategies for continuous learning and career growth in the engineering field.

Certification Route

This qualification offers two flexible pathways for certification.

Route 1: New Learners (No Experience)

Enrollment & Training
Learners must enroll with an ICTQual Approved Training Centre and complete all required study units through formal training that includes theoretical instruction and practical activities.

Assessment
Learners are required to complete and submit assignments based on the course learning outcomes. These assessments evaluate understanding and the ability to apply electrical engineering concepts in practical situations.

Certification
After successfully completing all assignments and assessments, learners will be awarded the ICTQual Level 6 Diploma in Electrical Engineering (360 Credits – Three Years).

Route 2: Experienced & Competent Candidates

Eligibility
Candidates must have a minimum of 6 years of verified experience in electrical engineering or a related technical field relevant to the qualification.

Competence Assessment
The ICTQual Approved Training Centre will assess the candidate’s existing knowledge and skills to ensure they meet the course learning outcomes.

Evidence Submission
Candidates must submit documented proof of work experience, including job roles, responsibilities, and tasks demonstrating competence in required areas.

Knowledge Verification
Centres will confirm familiarity with all learning outcomes. If gaps are identified, a skills gap assessment or additional learning may be required.

Certification
Upon successful verification of competence and experience, candidates will be awarded the ICTQual Level 6 Diploma in Electrical Engineering (360 Credits – Three Years) without completing the full training program.

Certification Benefits

ICTQual Level 6 Diploma in Electrical Engineering (360 Credits – Three Years)

International Recognition – A globally respected qualification that enhances professional credibility.
British Council Verifiable – Confirms authenticity and improves worldwide acceptance.
MOFA & Embassy Attestable – Suitable for legal use and overseas employment documentation.
Supports Iqama & Work Visa Approval – Helps meet employment requirements in Gulf countries.
Enhanced Career Opportunities – Opens doors to roles in power generation, construction, manufacturing, oil & gas, and industrial sectors.
Industry-Relevant Skills – Develops practical expertise in electrical systems, automation, and safety practices.
Career Advancement – Supports progression to supervisory, technical, and engineering roles.
Pathway to Higher Education – Enables further studies and professional development in electrical engineering.
Professional Recognition – Demonstrates technical competence and commitment to engineering excellence.

This certification strengthens career prospects locally and internationally while meeting professional and employment requirements.

Course Details

Duration: 4 to 36 Months

Mode: Online and incampus

Assessments: Assignments and work based

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Course Eligibility

Learners should meet the following entry requirements:

A Level 5 qualification or relevant diploma in electrical engineering or a related technical field is recommended.
Relevant work experience in electrical or technical fields (preferred but not mandatory).
Ability to communicate in English (reading and speaking)

Course Fee

150k PKR / 450G BP / 600 USD

FAQs

Yes, it is suitable for new learners, and there is also a competency-based route for experienced professionals.

Yes, the qualification is internationally recognized and British Council verifiable, enhancing global acceptance.

Yes, it is MOFA and Embassy attestable, making it suitable for international job and legal documentation requirements.

Yes, it supports employment opportunities and documentation requirements such as Iqama and work visa approvals.

Graduates can work as electrical engineers, maintenance supervisors, power systems technicians, automation technicians, or industrial electricians.

Yes, candidates with at least 6 years of relevant experience may qualify through a competency assessment route.