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

Build Expertise in Vehicle Systems, Diagnostics, and Innovation.

ATTICS International is Directly Approved Centre of ICTQual AB

Course Overview

The ICTQual Level 6 Diploma in Automotive Engineering (360 Credits – Three Years) is a comprehensive qualification designed to develop advanced technical knowledge and practical skills required in the modern automotive industry. This program provides in-depth training in vehicle systems, engine technology, automotive electronics, diagnostics, hybrid and electric vehicle technology, maintenance engineering, and workshop management. By combining theoretical principles with hands-on applications, the diploma prepares learners to diagnose, maintain, and optimize vehicle performance in today’s rapidly evolving mobility sector.

Over the three-year duration, students gain industry-relevant competencies aligned with global automotive standards and technological advancements. Graduates develop the ability to service, repair, and manage modern automotive systems while ensuring safety, efficiency, and environmental compliance. This qualification supports career progression into roles such as automotive engineer, vehicle diagnostics specialist, workshop supervisor, fleet maintenance manager, or EV technician, and also provides a pathway to higher education and professional advancement in the global automotive engineering sector.

Course Structure

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

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

Study Units

Introduction to Automotive Engineering
Mathematics for Automotive Engineering
Physics for Automotive Engineering
Mechanical Engineering Principles
Automotive Systems and Technology
Electrical and Electronic Systems in Vehicles
Engineering Materials for Automotive Design
Vehicle Chassis and Suspension Systems
Introduction to Vehicle Diagnostics
Manufacturing Processes for Automotive Engineering
Automotive Environmental Issues
Health, Safety, and Environmental Management

Advanced Engine Technologies
Vehicle Dynamics and Handling
Advanced Automotive Electronics
Transmission and Powertrain Systems
Vehicle HVAC Systems
Vehicle Safety Systems
Hybrid and Electric Vehicle Technologies
Automotive Aerodynamics
Automotive Materials Engineering
Vehicle Assembly and Production Techniques
Automotive Diagnostics and Troubleshooting
Vehicle Testing and Performance Evaluation

Advanced Vehicle Design and Prototyping
Automotive Control Systems
Automotive Quality Control and Assurance
Sustainability in Automotive Engineering
Automotive Project Management
Automotive Research and Development
Vehicle Electromagnetic Compatibility
Automotive Business and Marketing
Autonomous Vehicles and Future Technologies
Vehicle Fleet Management and Operations
Automotive Regulatory Compliance and Standards
Capstone Project in Automotive Engineering

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: Foundation and Core Engineering Principles

Introduction to Automotive Engineering

Identify the key principles of automotive engineering and its significance in modern vehicle design and development.
Understand the major components and systems of a vehicle, and their functions.
Develop the ability to assess the role of automotive engineers in improving vehicle performance and innovation.

Mathematics for Automotive Engineering

Apply mathematical techniques to solve automotive engineering problems related to vehicle design and performance.
Utilize algebra, calculus, and geometry to model and analyze automotive systems.
Demonstrate proficiency in using mathematical tools to optimize automotive components and systems.

Physics for Automotive Engineering

Apply physical principles such as motion, force, and energy to solve automotive engineering problems.
Analyze the impact of physical laws on the design, performance, and safety of vehicles.
Understand the relationship between physical properties and the efficiency of automotive systems.

Mechanical Engineering Principles

Develop a solid understanding of mechanical principles including statics, dynamics, and thermodynamics as applied to automotive engineering.
Apply mechanical engineering principles to the design and evaluation of automotive systems and components.
Understand the interaction between mechanical engineering concepts and automotive technologies.

Automotive Systems and Technology

Identify the main systems in vehicles, such as powertrains, braking systems, and suspension.
Understand the technological advancements in automotive systems that improve vehicle performance.
Develop the ability to analyze the interaction of various automotive technologies in modern vehicles.

Electrical and Electronic Systems in Vehicles

Understand the role of electrical and electronic systems in vehicle operation and performance.
Apply principles of circuit design, sensors, and control systems to vehicle electronics.
Develop problem-solving skills to troubleshoot electrical issues in automotive systems.

Engineering Materials for Automotive Design

Identify the types of materials used in automotive design, including metals, plastics, and composites.
Analyze the mechanical properties of materials used in automotive applications.
Understand the relationship between material selection and vehicle performance, safety, and durability.

Vehicle Chassis and Suspension Systems

Analyze the function of vehicle chassis and suspension systems in providing stability and comfort.
Understand the design principles of chassis and suspension systems to enhance vehicle handling.
Develop the ability to select appropriate chassis and suspension components for specific vehicle types.

Introduction to Vehicle Diagnostics

Understand the basic principles and tools of vehicle diagnostics.
Identify common vehicle faults using diagnostic systems and troubleshooting techniques.
Apply diagnostic methods to evaluate the performance of vehicle components and systems.

Manufacturing Processes for Automotive Engineering

Identify various manufacturing processes used in automotive production, such as casting, machining, and welding.
Understand the relationship between manufacturing processes and the quality of automotive products.
Develop the ability to optimize manufacturing techniques to improve efficiency and reduce costs.

Automotive Environmental Issues

Understand the environmental challenges facing the automotive industry, including air quality and waste management.
Explore solutions to reduce the environmental impact of vehicles, such as fuel efficiency and emissions reductions.
Assess the role of automotive engineers in designing sustainable vehicles and manufacturing processes.

Health, Safety, and Environmental Management

Understand the importance of health, safety, and environmental standards in automotive engineering.
Apply relevant health and safety regulations in automotive design, manufacturing, and testing.
Develop strategies to manage environmental impact and improve sustainability in automotive engineering projects.

Year 2: Advanced Automotive Technologies and Systems

Advanced Engine Technologies

Analyze the components and operation of advanced engine systems, including turbocharging, hybridization, and fuel injection.
Evaluate the performance and efficiency of different engine technologies.
Apply advanced techniques to improve engine efficiency, emissions, and overall performance.

Vehicle Dynamics and Handling

Understand the fundamental principles of vehicle dynamics, including tire-road interaction, stability, and control.
Apply knowledge of suspension, steering, and braking systems to optimize vehicle handling and performance.
Develop solutions to improve vehicle handling, particularly under dynamic driving conditions.

Advanced Automotive Electronics

Understand advanced automotive electronic systems, including in-vehicle networks, sensors, and ECU programming.
Apply electronics to improve vehicle safety, performance, and comfort.
Develop diagnostic and troubleshooting skills for complex automotive electronic systems.

Transmission and Powertrain Systems

Analyze the function and performance of transmission and powertrain systems in vehicles.
Understand the design and operation of manual, automatic, and continuously variable transmissions (CVT).
Apply knowledge to optimize powertrain efficiency, reduce emissions, and improve driving dynamics.

Vehicle HVAC Systems

Understand the principles and design of heating, ventilation, and air conditioning (HVAC) systems in vehicles.
Analyze the impact of HVAC systems on vehicle comfort, fuel efficiency, and environmental sustainability.
Develop solutions for improving HVAC system performance and energy efficiency in modern vehicles.

Vehicle Safety Systems

Understand the design and operation of advanced vehicle safety systems such as airbags, collision avoidance, and lane assist.
Evaluate the effectiveness of safety systems in preventing accidents and reducing injury.
Develop strategies to improve vehicle safety through advanced system integration.

Hybrid and Electric Vehicle Technologies

Understand the core principles and technologies behind hybrid and electric vehicles.
Analyze the advantages and challenges of hybrid and electric powertrains compared to traditional combustion engines.
Develop skills to design and integrate hybrid and electric powertrains into modern vehicles.

Automotive Aerodynamics

Apply aerodynamic principles to vehicle design to reduce drag, improve fuel efficiency, and enhance stability.
Understand the effects of vehicle shape and surface finish on aerodynamic performance.
Develop strategies to optimize vehicle aerodynamics for both performance and environmental impact.

Automotive Materials Engineering

Identify and analyze advanced materials, including lightweight composites and high-strength alloys, used in automotive applications.
Apply material science principles to improve vehicle safety, performance, and sustainability.
Develop solutions for selecting and manufacturing materials that meet specific vehicle performance requirements.

Vehicle Assembly and Production Techniques

Understand the processes involved in the assembly and production of vehicles, including robotic automation and quality control.
Analyze production workflows and systems to optimize vehicle manufacturing.
Apply lean manufacturing principles to reduce waste and improve production efficiency.

Automotive Diagnostics and Troubleshooting

Develop advanced diagnostic skills for troubleshooting complex automotive systems, including electrical, mechanical, and electronic faults.
Use modern diagnostic tools, including OBD-II systems and software, to identify and resolve issues.
Develop a methodical approach to system diagnostics and fault resolution.

Vehicle Testing and Performance Evaluation

Understand the principles and methods of vehicle testing, including road testing, performance evaluation, and regulatory compliance.
Apply testing techniques to assess vehicle safety, fuel efficiency, and emissions.
Analyze test data to recommend improvements in vehicle design and performance.

Year 3: Industry Applications, Management, and Innovation

Advanced Vehicle Design and Prototyping

Apply advanced design principles to create innovative vehicle prototypes using CAD and other design software.
Understand the prototyping process, from concept to production-ready models.
Develop skills to test and refine prototypes for performance, safety, and manufacturability.

Automotive Control Systems

Understand the design and application of control systems in modern vehicles, including adaptive cruise control and stability control systems.
Apply control theory to optimize vehicle performance, comfort, and safety.
Analyze and improve control algorithms for vehicle systems using real-time feedback.

Automotive Quality Control and Assurance

Apply quality control methodologies to ensure automotive components meet industry standards and specifications.
Use statistical tools and techniques to monitor and control product quality throughout the production process.
Develop strategies for continuous improvement in automotive manufacturing and assembly processes.

Sustainability in Automotive Engineering

Understand the environmental impact of the automotive industry, focusing on sustainability issues such as energy consumption and material usage.
Develop solutions to improve the sustainability of automotive designs through energy-efficient technologies and eco-friendly materials.
Analyze the role of automotive engineers in promoting sustainability through lifecycle assessments and sustainable manufacturing practices.

Automotive Project Management

Understand the principles of project management, including scope, time, cost, and quality management in automotive projects.
Apply project management tools and techniques to plan, execute, and close automotive engineering projects.
Develop the ability to manage resources, stakeholders, and risks in large-scale automotive engineering projects.

Automotive Research and Development

Conduct research to solve emerging problems in automotive engineering, focusing on new technologies and methods.
Analyze and evaluate new automotive concepts and prototypes to assess feasibility and performance.
Apply R&D principles to develop innovative automotive solutions and improve existing systems.

Vehicle Electromagnetic Compatibility

Understand the principles of electromagnetic compatibility (EMC) and its relevance to vehicle design and performance.
Analyze the impact of electromagnetic interference on vehicle systems, particularly electronics and communication.
Develop strategies to mitigate EMC issues in vehicle design and ensure compliance with industry standards.

Automotive Business and Marketing

Understand the principles of business and marketing in the automotive industry, including market research, product positioning, and branding.
Analyze consumer behavior and identify trends to guide automotive product development.
Develop marketing strategies for automotive products, focusing on competitive advantages and customer needs.

Autonomous Vehicles and Future Technologies

Understand the core technologies behind autonomous vehicles, including sensors, machine learning, and vehicle-to-vehicle communication.
Analyze the potential impact of autonomous vehicles on the automotive industry and society.
Explore the future of automotive technologies, including connected vehicles, AI, and next-generation propulsion systems.

Vehicle Fleet Management and Operations

Understand the principles of managing and maintaining a fleet of vehicles, focusing on cost optimization, performance, and safety.
Develop strategies for tracking and optimizing fleet performance through data analysis and monitoring tools.
Apply fleet management principles to maximize the efficiency and lifespan of vehicles in various industries.

Automotive Regulatory Compliance and Standards

Understand the regulatory framework governing the automotive industry, including safety, environmental, and quality standards.
Apply industry standards to ensure vehicle designs meet legal and regulatory requirements.
Develop strategies to navigate regulatory changes and ensure ongoing compliance in automotive engineering projects.

Capstone Project in Automotive Engineering

Apply all the knowledge and skills acquired during the course to solve a real-world automotive engineering challenge.
Conduct research, design, prototype, and test a solution to an automotive engineering problem.
Present the results of the capstone project, demonstrating technical expertise, problem-solving ability, and innovation.

Certification Route

This qualification offers two flexible pathways for certification.

Route 1: New Learners (No Experience)

Enrollment & Training
Learners enroll with an ICTQual Approved Training Centre and complete all required study units through theoretical and practical training.

Assignments & Assessment
Learners must complete assignments aligned with the learning outcomes to demonstrate understanding and practical application.

Certification
After successfully completing coursework and assessments, learners will be awarded the ICTQual Level 6 Diploma in Civil Engineering 360 Credits – Three Years.

Route 2: Experienced & Competent Candidates

Eligibility
Minimum 6 years of verified experience in civil engineering or a related field.

Competence Assessment
The training centre evaluates the candidate’s existing knowledge and skills against the course learning outcomes.

Evidence Submission
Candidates provide documented proof of work experience, roles, and responsibilities demonstrating competence.

Knowledge Verification
A skills gap assessment may be conducted if additional learning is required.

Certification
Upon successful verification, candidates are awarded the ICTQual Level 6 Diploma in Civil Engineering 360 Credits – Three Years without completing full training.

Certification Benefits

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

International Recognition – A globally respected qualification that enhances professional credibility and employability.
British Council Verifiable – Confirms authenticity and strengthens worldwide acceptance.
MOFA & Embassy Attestable – Suitable for overseas employment and legal documentation requirements.
Supports Iqama & Work Visa Approval – Helps meet employment and residency requirements in Gulf countries.
High-Demand Career Opportunities – Opens doors to roles in automotive manufacturing, service centers, dealerships, transport fleets, and mobility industries.
Industry-Relevant Skills – Develops practical expertise in vehicle diagnostics, automotive electronics, maintenance systems, and EV technologies.
Career Advancement – Supports progression into supervisory, technical, and workshop management roles.
Pathway to Higher Education – Enables further studies and professional growth in automotive and mechanical engineering.
Professional Recognition – Demonstrates technical competence and readiness for modern automotive technologies.

This certification strengthens global career prospects while meeting professional and international 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 automotive, mechanical, or a related technical field is recommended.
Relevant work experience in automotive 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, the diploma is suitable for new learners and also offers 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 automotive engineers, vehicle diagnostics technicians, workshop supervisors, fleet maintenance managers, or EV technicians.

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