IMI Accredited Master Technician & Automotive Lecturer, VW, Audi - دروس خصوصية

انضم للمدرسين

IMI Accredited Master Technician & Automotive Lecturer, VW, Audi

من 180.55 SAR /س

Are you looking to master complex vehicle diagnostics or transition into the world of Electric Vehicles? With over 11 years of experience working directly with the Volkswagen and Audi (VAG) Group, I provide expert-led training designed for everyone from automotive students to experienced technicians.

I am a current Automotive Lecturer and an IMI Accredited Master Technician. My background includes specialized roles as a Technical Support Specialist for BMW and Rolls Royce, and a Technical Manager for Audi, where I was responsible for solving the most complex mechanical and electrical faults.

المكان

عبر الانترنت من المملكة المتحدة

من أنا؟

am an enthusiastic, trustworthy, and reliable automotive professional with a genuine passion for the motor industry. With over 11 years of experience specifically within the Volkswagen and Audi (VAG) Group, I have progressed from an apprentice to an IMI Accredited Master Technician.
In my current role as an Automotive Lecturer, I specialize in delivering engaging lessons on automotive technology and repair, focusing on both theoretical knowledge and practical workshop skills. My teaching style is supportive and mentoring-focused, designed to help learners at all levels—from beginners to advanced technicians—develop the technical skills and industry knowledge needed to succeed in a modern workshop environment.

المستوى التعليمي

completed the Volkswagen Advanced Apprenticeship Programme. I hold a Diploma in Vehicle Maintenance and Repair Competence (VCQ) and a Diploma in Vehicle Maintenance and Repair Principles (VRQ). Additionally, I am an IMI Accredited Master Technician and hold numerous specialist certifications in Audi Occupant Safety, Climate Control, and High Voltage 3.0 systems.

الخبرة / المؤهلات

have over 11 years of experience within the Volkswagen and Audi (VAG) Group. My background includes serving as a Technical Manager for Audi and a Technical Support Specialist for BMW and Rolls Royce. Currently, I am an Automotive Lecturer at Newham College, where I specialize in teaching advanced diagnostics, EV/Hybrid technology, and repair standards

السن

شباب (13-17 سنة)

الكبار (18-64 سنة)

الكبار (65 سنة فأكثر)

مستوى الطالب

مبتدئ

متوسط

متقدم

المدة

60 دقيقة

90 دقيقة

120 دقيقة

الدرس يدور باللغة

الإنجليزية

مهارات

هندسة السيارات

الجاهزية في الأسبوع العادي

(GMT -04:00)

نيويورك

على الانترنت عبر كاميرا ويب

Mon

Tue

Wed

Thu

Fri

Sat

Sun

00-04

04-08

08-12

12-16

16-20

20-24

L’automatique est une science qui traite de la modélisation, de l’analyse, de l’identification et de la commande des systèmes dynamiques. Elle inclut la cybernétique au sens étymologique du terme, et a pour fondements théoriques les mathématiques, la théorie du signal et l’informatique théorique.

STEM solution that engages students by providing the resources to design, build and program their creations while
helping them develop essential skills such as creativity, critical thinking, collaboration, and communication.
lego EV3lego EV3

APQP (Advanced Product Quality Planning) is a methodology for managing development and industrialization projects, applicable for new products, but also for deviations from a product already submitted to a customer (modification of design, raw material, production site, etc.). It defines the steps, milestones and expected deliverables for each project activity, namely:

Schedule
Product Design and Development
Process Design and Development
Product and Process Validation
Production
The PPAP (Production Part Approval Process) corresponds to all the deliverables and justifications of conformity, resulting from the APQP, that each supplier must provide to its customer during the development project until the launch of series production. The content of the PPAP is also standardized for certain industries (18 elements for automotive and 11 for aeronautics), but may vary according to the requirements issued by the customer. It can therefore be considered as an output of the APQP process.

The APQP brings together various expertise and methods, from market research to FMECA or MSA, and aims to harmonize its management and feedback, whether to the client or to auditors. It aims to demonstrate the robustness of the company's design and manufacturing according to the requirements (functional, production rate) and specifications (drawings, technical documents) of the customer, through the rigorous validation of each required step. By way of example, we find below all the steps for the automotive APQP.

Course Description: CAN/LIN Protocols in Embedded Systems

Course Title: Embedded Systems Communication: CAN/LIN Protocols

Course Overview:
The "Embedded Systems Communication: CAN/LIN Protocols" course is designed to provide students with a comprehensive understanding of the Controller Area Network (CAN) and Local Interconnect Network (LIN) protocols used in embedded systems. The course aims to equip students with the necessary knowledge and skills to design, implement, and troubleshoot communication systems based on these protocols. Through a combination of theoretical lectures, hands-on lab exercises, and practical projects, students will gain a deep understanding of CAN/LIN protocols and their applications in various industries.

Course Objectives:
1. Understand the fundamental principles and concepts of CAN/LIN protocols.
2. Learn about the structure and architecture of CAN/LIN networks.
3. Explore the advantages, limitations, and trade-offs of using CAN/LIN in embedded systems.
4. Gain practical experience in designing and implementing CAN/LIN communication systems.
5. Develop skills in troubleshooting and debugging CAN/LIN networks.
6. Explore real-world applications of CAN/LIN protocols in automotive, industrial, and other embedded systems.
7. Understand the integration of CAN/LIN protocols with other communication interfaces.

Course Outline:

Module 1: Introduction to CAN/LIN Protocols
- Overview of embedded systems communication
- Evolution and history of CAN and LIN protocols
- Comparison of CAN and LIN with other communication protocols
- Application areas and industry standards

Module 2: CAN Protocol Fundamentals
- CAN bus architecture and components
- Physical and data link layers of the CAN protocol
- Message formats, identifiers, and addressing
- Error detection and fault tolerance mechanisms
- CAN protocol timing and synchronization

Module 3: LIN Protocol Fundamentals
- LIN network topology and components
- LIN frame structure and message types
- Master-slave communication and scheduling
- LIN protocol configuration and initialization
- Fault detection and handling in LIN networks

Module 4: CAN/LIN Network Design and Implementation
- Hardware requirements for CAN/LIN communication
- CAN/LIN transceivers and controllers
- Network topology and node addressing
- Bus arbitration and message prioritization
- Software development for CAN/LIN systems

Module 5: CAN/LIN Network Diagnostics and Troubleshooting
- CAN/LIN network analysis tools and techniques
- Error detection, fault localization, and error recovery
- Diagnostic trouble codes and error reporting
- Strategies for debugging and optimizing CAN/LIN systems

Module 6: Applications of CAN/LIN Protocols
- CAN/LIN in automotive systems: vehicle networks, diagnostics, and control systems
- CAN/LIN in industrial automation: process control, sensors, and actuators
- CAN/LIN in consumer electronics and home automation
- Integration of CAN/LIN with other communication interfaces (e.g., Ethernet, SPI, I2C)

Module 7: Project Work
- Hands-on projects involving the design and implementation of CAN/LIN communication systems
- Real-world case studies and application development
- Team-based projects to apply the acquired knowledge and skills

Prerequisites:
- Basic knowledge of embedded systems and microcontroller programming
- Understanding of digital electronics and computer architecture
- Familiarity with C or C++ programming language
- Passionate about the automotive field

Assessment Methods:
- Quizzes and exams to assess theoretical knowledge
- Assignments to evaluate practical implementation skills
- Project work and presentations to assess application and problem-solving abilities

By the end of this course, students will have a solid foundation in the theory, implementation, and troubleshooting of CAN/LIN protocols in embedded systems. They will be prepared to work on projects and develop communication systems based on CAN/LIN, enabling them to contribute to various industries where embedded systems play a crucial role.

The main objective of these subjects is to introduce students to the basic principles of automotive mechanics, and includes an understanding of the function of basic components of vehicles and basic competencies in maintenance and repair subjects.

Article content:

Introduction to Automotive: A presentation of the history of automobiles, technological developments, and current trends in the automotive industry.

Engine Function: Study of the basic principles of an internal combustion engine, including air management, carburetor, and lighting. Understand the different types of engines (core, diesel, electric) and composites.

Transmission Systems: Explore different transmission types (manual and automatic) and vehicles. Understand the basic principles of force transmission.

Charging Systems: Study of charging systems, including disc brakes and drum tires. Training in tire maintenance and repair techniques.

Suspension and directional systems: Understand the components of the suspension and directional system and their role in road course and channel comfort.

Automotive Electricity and Electronics: An introduction to the electrical and electronic systems of vehicles, including the battery, charging system, lighting system, and engine management systems.

Preventive Maintenance: Learn about basic maintenance procedures, oil drain data, filter replacements, and fluid checks.

Diagnosis and Repair: Develop diagnostic competencies to identify and repair mechanical problems. Use of auto repair tools and equipment.

Car Security: A discussion of safety standards and safety equipment in vehicles, as well as good practices for the safety channel.

Training methods: Introduction to Automotive Mechanics courses generally combine theoretical conferences in the classroom with practical work in the workshop. Students get the opportunity to practically measure their knowledge by performing simple repairs on real vehicles.

Assessment: Student assessment can include written tests, workshop practical work, research projects and assessments of practical competencies.

Conclusion: Introduction to Automotive Mechanics is essential material for anyone who needs to work in the automotive industry, learn automotive mechanics, or simply understand the function of their own vehicle. It provides a solid base for ongoing training in this ever-evolving field.

Dimensional printing is the most advanced manufacturing tool currently, and through the training course you will learn about it
1- Types of 3D printing machines and the differences found in them
2- How to choose the appropriate 3D printer
3- Modifying the engineering design to make it suitable for 3D printing
4- Use 3D printing programs such as CURA, ORCA and simplify 3D

As an engineer specializing in the automotive industry, I use my professional experience to offer support courses in mathematics to high school and high school students, in accordance with the Moroccan program. My goal is to strengthen the basics, deepen the essential concepts and support each student in their academic success and exams.

At the same time, I offer personalized advice for post-baccalaureate orientation, helping students identify the courses and opportunities that best match their academic and professional goals.

For engineering enthusiasts, and more specifically those interested in the automotive industry and embedded systems, I also offer introductory courses to discover the fundamentals of this dynamic and innovative field.

I devote part of my free time to this mission in order to share my knowledge and contribute to the development of tomorrow's talents.

Hello, I am an electrical engineer having an extensive experience as a professor in higher education in engineering science and electrical engineering, as well as great experience as an embedded systems engineer, in EE architecture, ADAS, Testing and validations in the automotive sector.

In this course, I offer training in engineering fields related to automotive engineering, system engineering, testing and validation, embedded systems, and ADAS systems. My methodology is based on the acquisition of theoretical concepts in a simple manner, as well as the practical aspects of current market techniques.

I also offer CV correction/preparation sessions, preparation for job interviews mainly in the automotive sector.

AMDEC
PDCA
Ishikawa
Amélioration continue ( KAIZEN , KANBAN , VSM , 5 S, 8D , ....)
Plan de surveillance
Normes ISO 9001 , ISO 18001 , ISO 45001, ISO 14001
Audits qualité
système de management environnemental SME
validation des lignes et équipements de production

L’automatique est une science qui traite de la modélisation, de l’analyse, de l’identification et de la commande des systèmes dynamiques. Elle inclut la cybernétique au sens étymologique du terme, et a pour fondements théoriques les mathématiques, la théorie du signal et l’informatique théorique.

STEM solution that engages students by providing the resources to design, build and program their creations while
helping them develop essential skills such as creativity, critical thinking, collaboration, and communication.
lego EV3lego EV3

APQP (Advanced Product Quality Planning) is a methodology for managing development and industrialization projects, applicable for new products, but also for deviations from a product already submitted to a customer (modification of design, raw material, production site, etc.). It defines the steps, milestones and expected deliverables for each project activity, namely:

Schedule
Product Design and Development
Process Design and Development
Product and Process Validation
Production
The PPAP (Production Part Approval Process) corresponds to all the deliverables and justifications of conformity, resulting from the APQP, that each supplier must provide to its customer during the development project until the launch of series production. The content of the PPAP is also standardized for certain industries (18 elements for automotive and 11 for aeronautics), but may vary according to the requirements issued by the customer. It can therefore be considered as an output of the APQP process.

The APQP brings together various expertise and methods, from market research to FMECA or MSA, and aims to harmonize its management and feedback, whether to the client or to auditors. It aims to demonstrate the robustness of the company's design and manufacturing according to the requirements (functional, production rate) and specifications (drawings, technical documents) of the customer, through the rigorous validation of each required step. By way of example, we find below all the steps for the automotive APQP.

Course Description: CAN/LIN Protocols in Embedded Systems

Course Title: Embedded Systems Communication: CAN/LIN Protocols

Course Overview:
The "Embedded Systems Communication: CAN/LIN Protocols" course is designed to provide students with a comprehensive understanding of the Controller Area Network (CAN) and Local Interconnect Network (LIN) protocols used in embedded systems. The course aims to equip students with the necessary knowledge and skills to design, implement, and troubleshoot communication systems based on these protocols. Through a combination of theoretical lectures, hands-on lab exercises, and practical projects, students will gain a deep understanding of CAN/LIN protocols and their applications in various industries.

Course Objectives:
1. Understand the fundamental principles and concepts of CAN/LIN protocols.
2. Learn about the structure and architecture of CAN/LIN networks.
3. Explore the advantages, limitations, and trade-offs of using CAN/LIN in embedded systems.
4. Gain practical experience in designing and implementing CAN/LIN communication systems.
5. Develop skills in troubleshooting and debugging CAN/LIN networks.
6. Explore real-world applications of CAN/LIN protocols in automotive, industrial, and other embedded systems.
7. Understand the integration of CAN/LIN protocols with other communication interfaces.

Course Outline:

Module 1: Introduction to CAN/LIN Protocols
- Overview of embedded systems communication
- Evolution and history of CAN and LIN protocols
- Comparison of CAN and LIN with other communication protocols
- Application areas and industry standards

Module 2: CAN Protocol Fundamentals
- CAN bus architecture and components
- Physical and data link layers of the CAN protocol
- Message formats, identifiers, and addressing
- Error detection and fault tolerance mechanisms
- CAN protocol timing and synchronization

Module 3: LIN Protocol Fundamentals
- LIN network topology and components
- LIN frame structure and message types
- Master-slave communication and scheduling
- LIN protocol configuration and initialization
- Fault detection and handling in LIN networks

Module 4: CAN/LIN Network Design and Implementation
- Hardware requirements for CAN/LIN communication
- CAN/LIN transceivers and controllers
- Network topology and node addressing
- Bus arbitration and message prioritization
- Software development for CAN/LIN systems

Module 5: CAN/LIN Network Diagnostics and Troubleshooting
- CAN/LIN network analysis tools and techniques
- Error detection, fault localization, and error recovery
- Diagnostic trouble codes and error reporting
- Strategies for debugging and optimizing CAN/LIN systems

Module 6: Applications of CAN/LIN Protocols
- CAN/LIN in automotive systems: vehicle networks, diagnostics, and control systems
- CAN/LIN in industrial automation: process control, sensors, and actuators
- CAN/LIN in consumer electronics and home automation
- Integration of CAN/LIN with other communication interfaces (e.g., Ethernet, SPI, I2C)

Module 7: Project Work
- Hands-on projects involving the design and implementation of CAN/LIN communication systems
- Real-world case studies and application development
- Team-based projects to apply the acquired knowledge and skills

Prerequisites:
- Basic knowledge of embedded systems and microcontroller programming
- Understanding of digital electronics and computer architecture
- Familiarity with C or C++ programming language
- Passionate about the automotive field

Assessment Methods:
- Quizzes and exams to assess theoretical knowledge
- Assignments to evaluate practical implementation skills
- Project work and presentations to assess application and problem-solving abilities

By the end of this course, students will have a solid foundation in the theory, implementation, and troubleshooting of CAN/LIN protocols in embedded systems. They will be prepared to work on projects and develop communication systems based on CAN/LIN, enabling them to contribute to various industries where embedded systems play a crucial role.

The main objective of these subjects is to introduce students to the basic principles of automotive mechanics, and includes an understanding of the function of basic components of vehicles and basic competencies in maintenance and repair subjects.

Article content:

Introduction to Automotive: A presentation of the history of automobiles, technological developments, and current trends in the automotive industry.

Engine Function: Study of the basic principles of an internal combustion engine, including air management, carburetor, and lighting. Understand the different types of engines (core, diesel, electric) and composites.

Transmission Systems: Explore different transmission types (manual and automatic) and vehicles. Understand the basic principles of force transmission.

Charging Systems: Study of charging systems, including disc brakes and drum tires. Training in tire maintenance and repair techniques.

Suspension and directional systems: Understand the components of the suspension and directional system and their role in road course and channel comfort.

Automotive Electricity and Electronics: An introduction to the electrical and electronic systems of vehicles, including the battery, charging system, lighting system, and engine management systems.

Preventive Maintenance: Learn about basic maintenance procedures, oil drain data, filter replacements, and fluid checks.

Diagnosis and Repair: Develop diagnostic competencies to identify and repair mechanical problems. Use of auto repair tools and equipment.

Car Security: A discussion of safety standards and safety equipment in vehicles, as well as good practices for the safety channel.

Training methods: Introduction to Automotive Mechanics courses generally combine theoretical conferences in the classroom with practical work in the workshop. Students get the opportunity to practically measure their knowledge by performing simple repairs on real vehicles.

Assessment: Student assessment can include written tests, workshop practical work, research projects and assessments of practical competencies.

Conclusion: Introduction to Automotive Mechanics is essential material for anyone who needs to work in the automotive industry, learn automotive mechanics, or simply understand the function of their own vehicle. It provides a solid base for ongoing training in this ever-evolving field.

Dimensional printing is the most advanced manufacturing tool currently, and through the training course you will learn about it
1- Types of 3D printing machines and the differences found in them
2- How to choose the appropriate 3D printer
3- Modifying the engineering design to make it suitable for 3D printing
4- Use 3D printing programs such as CURA, ORCA and simplify 3D

As an engineer specializing in the automotive industry, I use my professional experience to offer support courses in mathematics to high school and high school students, in accordance with the Moroccan program. My goal is to strengthen the basics, deepen the essential concepts and support each student in their academic success and exams.

At the same time, I offer personalized advice for post-baccalaureate orientation, helping students identify the courses and opportunities that best match their academic and professional goals.

For engineering enthusiasts, and more specifically those interested in the automotive industry and embedded systems, I also offer introductory courses to discover the fundamentals of this dynamic and innovative field.

I devote part of my free time to this mission in order to share my knowledge and contribute to the development of tomorrow's talents.

Hello, I am an electrical engineer having an extensive experience as a professor in higher education in engineering science and electrical engineering, as well as great experience as an embedded systems engineer, in EE architecture, ADAS, Testing and validations in the automotive sector.

In this course, I offer training in engineering fields related to automotive engineering, system engineering, testing and validation, embedded systems, and ADAS systems. My methodology is based on the acquisition of theoretical concepts in a simple manner, as well as the practical aspects of current market techniques.

I also offer CV correction/preparation sessions, preparation for job interviews mainly in the automotive sector.

AMDEC
PDCA
Ishikawa
Amélioration continue ( KAIZEN , KANBAN , VSM , 5 S, 8D , ....)
Plan de surveillance
Normes ISO 9001 , ISO 18001 , ISO 45001, ISO 14001
Audits qualité
système de management environnemental SME
validation des lignes et équipements de production

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