Graduate Diploma In Automobile Engineering (Level-6) in London 2025

This module covers the principles and techniques of technical drawing essential for engineering design. Students will learn to create accurate 2D and 3D representations of engineering components using standardized methods, including orthographic projection, isometric views, and sectional drawings. Emphasis is placed on developing skills in visualization, precision, and interpretation of engineering plans. The course provides a foundation for effective communication of design ideas in the engineering field.

This module explores the fundamental properties of engineering materials, including mechanical, thermal, electrical, and magnetic characteristics. Students will examine the behavior of metals, polymers, ceramics, and composites under various conditions. The focus is on understanding how material properties influence performance, selection, and application in engineering designs. The course provides a foundation for selecting appropriate materials based on their physical and chemical properties for different engineering projects.

This module introduces the principles of mechanics, focusing on the behavior of particles and rigid bodies under the influence of forces. Key topics include statics, dynamics, kinematics, and the analysis of forces, moments, and equilibrium. Students will learn to apply Newton's laws of motion, work-energy principles, and impulse-momentum methods to solve real-world engineering problems. The course builds foundational knowledge for more advanced studies in structural and mechanical engineering.

This module provides a foundational understanding of the principles of electricity, focusing on electric circuits, current, voltage, resistance, and power. Students will explore Ohm's Law, Kirchhoff's laws, and the behavior of AC and DC circuits. The course covers the analysis and design of electrical circuits using basic components like resistors, capacitors, and inductors. Emphasis is placed on practical applications in engineering systems and understanding the role of electricity in modern technology.

This module builds on the concepts introduced in Engineering Mathematics I, focusing on advanced mathematical techniques for solving complex engineering problems. Key topics include multivariable calculus, partial differential equations, Laplace transforms, and Fourier series. Emphasis is placed on applying these methods to model and analyze systems in engineering disciplines. The course strengthens students' mathematical skills and prepares them for higher-level applications in engineering analysis and design.

This module introduces the principles governing the behavior of fluids in motion and at rest. Key topics include fluid properties, hydrostatics, fluid dynamics, and the conservation laws of mass, momentum, and energy. Students will learn to analyze fluid flow in various engineering systems, including pipes, channels, and pumps. The course emphasizes the application of theoretical concepts to solve practical engineering problems involving fluid transport and machinery.

This module covers the fundamental principles of thermodynamics, focusing on energy, heat, and work interactions in engineering systems. Key topics include the laws of thermodynamics, properties of pure substances, energy conversion processes, and thermodynamic cycles such as Carnot, Rankine, and refrigeration cycles. Students will learn to analyze and optimize the efficiency of systems involving heat engines, power plants, and refrigeration units. The course provides essential knowledge for energy management and thermal system design in engineering applications.

This module provides hands-on training in basic engineering skills and manufacturing processes. Students will gain practical experience in machining, welding, fitting, carpentry, and sheet metal work. Emphasis is placed on safety protocols, tool handling, and precision measurement techniques. The course aims to develop technical competence in the use of workshop equipment and fosters an understanding of material fabrication, assembly, and maintenance procedures in engineering projects.

This module introduces the basic concepts and techniques of computer programming, focusing on problem-solving and algorithm development. Key topics include variables, data types, control structures, functions, arrays, and debugging. Students will learn to write, test, and execute programs using a high-level programming language, typically C, Python, or Java. The course emphasizes logical thinking and structured programming techniques, providing a foundation for more advanced studies in software development and engineering applications.

This module explores techniques for mindfulness, meditation, and stress reduction to enhance mental well-being. Students will learn various meditation practices, including guided meditation, breath awareness, and progressive muscle relaxation, as well as their physiological and psychological benefits. The course emphasizes the importance of self-awareness, emotional regulation, and coping strategies for managing stress in both personal and professional contexts. By fostering a balanced mindset, students will develop skills to improve focus, resilience, and overall quality of life.

This module introduces fundamental concepts of economics and accounting relevant to engineering practice. Students will learn about financial statements, budgeting, cost analysis, and investment evaluation techniques, including net present value (NPV) and internal rate of return (IRR). The course also covers basic economic principles, market structures, and the impact of economic decisions on engineering projects. Emphasis is placed on applying these principles to make informed financial decisions and manage resources effectively in engineering environments.

This module provides an overview of the engineering profession, including its history, ethical responsibilities, and the role of engineers in society. Students will explore various engineering disciplines, professional organizations, and the importance of lifelong learning and professional development. The course emphasizes ethical decision-making, sustainability, and the impact of engineering solutions on the environment and society. Through case studies and group discussions, students will gain insights into the challenges and opportunities within the engineering profession, preparing them for successful careers.

This module introduces the principles and applications of digital electronics, focusing on the design and analysis of digital circuits. Key topics include binary number systems, logic gates, combinational and sequential circuits, and state machines. Students will learn to use various tools for designing and simulating digital systems, as well as the fundamentals of microcontrollers and programmable logic devices. Emphasis is placed on practical applications and troubleshooting techniques, preparing students for careers in electronics, computer engineering, and related fields.

This module introduces the principles and applications of digital electronics, focusing on the design and analysis of digital circuits. Key topics include binary number systems, logic gates, combinational and sequential circuits, and state machines. Students will learn to use various tools for designing and simulating digital systems, as well as the fundamentals of microcontrollers and programmable logic devices. Emphasis is placed on practical applications and troubleshooting techniques, preparing students for careers in electronics, computer engineering, and related fields.

This module covers the principles of electrical power generation, transmission, and utilization, with a focus on electrical machines and their applications. Key topics include AC and DC machines, transformers, power system components, and the operation of synchronous and asynchronous motors. Students will learn about efficiency, performance characteristics, and control techniques for electrical machines. The course emphasizes practical applications in industrial settings, preparing students for careers in electrical engineering, power systems, and renewable energy technologies.

This module explores the mechanical behavior of materials under various types of loading, focusing on stress, strain, and deformation. Key topics include elasticity, plasticity, shear and torsion, and the analysis of beams, columns, and frames. Students will learn to apply fundamental principles to determine the strength, stability, and failure modes of materials and structures. The course emphasizes real-world applications in engineering design, enabling students to assess material performance and optimize structural integrity in various engineering projects.

This module introduces the legal framework governing industrial relations and the rights and responsibilities of employers and employees. Key topics include labor law, workplace safety regulations, contracts, collective bargaining, and dispute resolution. Students will explore the role of governmental agencies, trade unions, and labor organizations in shaping industrial policy. The course emphasizes understanding legal principles and their practical implications for managing workplace issues, preparing students for careers in human resources, management, and legal consultancy within industrial settings.

This module focuses on the principles and applications of heat engines and work transfer devices in converting thermal energy into mechanical work. Key topics include the thermodynamic cycles of various heat engines, such as Carnot, Otto, and Diesel cycles, as well as concepts of efficiency and performance evaluation. Students will also explore work transfer devices, including turbines, compressors, and heat exchangers, and their roles in energy systems. Emphasis is placed on practical applications, system design, and optimization strategies for improving energy efficiency in engineering applications.

This module covers the design, development, and maintenance of automobiles, focusing on their systems and components. Key topics include engine design, vehicle dynamics, power transmission, suspension systems, and electrical systems. Students will learn about modern automotive technologies, including hybrid and electric vehicles, and the impact of regulations and environmental considerations on vehicle design. Emphasis is placed on hands-on experience through laboratory work and projects, preparing students for careers in the automotive industry, manufacturing, and research and development.

This module introduces the principles and techniques of finite element analysis (FEA) as a method for solving complex engineering problems. Key topics include the formulation of finite element models, discretization of structures, and the application of boundary conditions. Students will learn to analyze stress, strain, and deformation in various materials and structures using commercial FEA software. The course emphasizes practical applications in structural, thermal, and fluid analysis, enabling students to evaluate design performance and optimize engineering solutions in real-world scenarios.

This module focuses on the electronic systems and components used in modern vehicles, emphasizing their design, function, and integration. Key topics include vehicle control systems, sensors and actuators, communication networks (such as CAN and LIN), and power management systems. Students will explore the role of electronics in enhancing vehicle performance, safety, and efficiency, including advanced driver-assistance systems (ADAS) and electric vehicle technologies. The course emphasizes hands-on experience with diagnostic tools and software, preparing students for careers in automotive engineering, electronics design, and automotive technology development.

This module provides engineers with essential management skills and knowledge necessary for effective leadership in technical environments. Key topics include project management, resource allocation, team dynamics, and strategic planning. Students will learn about organizational behavior, communication strategies, and decision-making processes relevant to engineering projects. The course emphasizes practical applications through case studies and group projects, preparing students to navigate the complexities of managing engineering teams and projects while fostering innovation and efficiency in the workplace.

This module covers the principles and applications of refrigeration and air-conditioning systems, focusing on their design, operation, and efficiency. Key topics include thermodynamics of refrigeration cycles, heat transfer mechanisms, refrigerants, and system components such as compressors, evaporators, and condensers. Students will learn about the environmental impact of refrigerants, energy efficiency measures, and the latest technologies in HVAC systems. The course emphasizes practical skills through laboratory work and design projects, preparing students for careers in HVAC engineering, facility management, and sustainable energy solutions.

This module focuses on the principles and methodologies of designing mechanical components and systems for various applications. Key topics include material selection, failure analysis, stress and strain calculations, and the design of machine elements such as gears, shafts, bearings, and fasteners. Students will learn to apply engineering principles and standards to develop efficient, reliable, and safe machine designs. The course emphasizes project-based learning, enabling students to work on real-world design challenges and prepare for careers in mechanical engineering, product development, and manufacturing.

This module examines the principles and applications of electro-mechanical control systems, focusing on the integration of electrical and mechanical components in automation and robotics. Key topics include system modeling, feedback control, actuators, sensors, and signal processing. Students will learn to design and analyze control systems using techniques such as PID control, state-space representation, and frequency response methods. The course emphasizes practical applications through laboratory projects and simulations, preparing students for careers in automation, robotics, and mechatronics engineering.

This module explores the comprehensive design and integration of automotive systems, focusing on the interplay between various subsystems such as powertrain, chassis, electronics, and safety features. Key topics include system requirements analysis, performance optimization, and the use of computer-aided design (CAD) tools. Students will learn about the principles of vehicle dynamics, thermal management, and emissions control, as well as the latest advancements in electric and autonomous vehicles. The course emphasizes hands-on projects and collaborative design experiences, preparing students for careers in automotive engineering, product development, and system integration.

This module focuses on the principles and applications of instrumentation and control systems in monitoring and regulating industrial processes. Key topics include sensor technologies, data acquisition systems, control theory, and automation techniques. Students will learn about various types of sensors, signal conditioning, and control strategies such as PID control and feedback mechanisms. The course emphasizes the design and implementation of control systems using software tools and hardware platforms, preparing students for careers in process control, automation engineering, and system integration across various industries.

This module covers the principles and applications of instrumentation used in industrial settings for monitoring and controlling processes. Key topics include types of sensors and transducers, measurement techniques for pressure, temperature, flow, and level, as well as data acquisition and processing. Students will learn about calibration, signal conditioning, and the integration of instrumentation into control systems. The course emphasizes hands-on experience through laboratory work and projects, preparing students for careers in process control, automation, and instrumentation engineering across various industries.

This module provides students with the opportunity to undertake an independent research or design project, applying the knowledge and skills acquired throughout their degree program. Students will select a topic related to their field of study, conduct literature reviews, develop methodologies, and implement their projects. Emphasis is placed on critical thinking, problem-solving, and project management skills. Students will document their work in a comprehensive dissertation, presenting their findings and solutions. The course prepares students for professional practice and further academic research, fostering skills in communication, analysis, and technical writing.