Mustafa - Consultant ASSEMBLEUR
Ref : 090119C002-
1020 BRUXELLES (Belgique)
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Consultant, Développeur, Consultant technique (43 ans)
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Freelance
Expérience professionnelle
07.08 – 01.09 CONSULTANT AT ALTRAN EUROPE, BRUSSELS - BELGIUM
03.08 – 06.08 ORBIT SENSOR PROJECT FOR CORAC GROUP PLC, LONDON - UK
Electronics Development Engineer
Context
Corac is a technology and intellectual property company with expertise in the turbo machinery sector (********). Corac was planning to use non-contact proximity sensors for their Orbit Sensor to electronically monitor the displacement of the motor shaft.
Objectives
The objectives were, firstly, to evaluate the suitability of different non-contact proximity sensors\technologies that can be used for the Orbit Sensor. Then, to carry out a design study, and finally a design/simulation of the modelling of the probe.
Technical Environment
Finite Element Method Magnetics (FEMM) and MS-Office
Results & Benefits
A Market Research study report of non-contact displacement sensors was supplied. FEMM simulations has been performed and a finite element design study to optimise the Orbit Sensor was supplied
12.07 – 02.08 CURRENT TRANSDUCERS PROJECT FOR CORAC GROUP PLC
Electronics Development Engineer
Context
Corac was planning to build a Sensor Card for monitoring the current outputs from insulated gate bipolar transistor (IGBT) H-Bridges to the compressors motors. To that end, two Current Transducer Evaluation Boards had been purchased to be evaluated.
Objectives
Corac’s objectives were, firstly, to define the design requirements for the Sensor Card, and secondly to evaluate which Current Transducer was the most suitable for measuring the current flowing in the motor winding.
Technical Environment
Pulse generator, NMOSFET, MOSFET driver, Oscilloscope, Oven
OrCad, MS-Office
Results & Benefits
A report about the requirements specification of the Sensor Card was supplied. A report about the performance of the Evaluations Boards was supplied. Finally, a design of the Sensor Card was submitted.
4. ACADEMIC EXPERIENCES
01.05 – 11.07 PHD PROJECT – HAPTIC SENSING TECHNOLOGY FOR MEMS DESIGN AND MANUFACTURE - HERIOT-WATT UNIVERSITY, EDINBURGH - UK
Context
The commercial tools available for MicroElectroMechanical Systems (MEMS) design such as MEMSCAP and ANSYS are not efficient yet to detect at the design stage, potential faults and defects within the manufacturing process. One cure is to implement simulation driven product development cycle to avoid the need of physical prototypes.
Objectives
To develop a software package based on simulation driven development cycle.
Approach
Demonstrate the usefulness of haptic sensing technology for MEMS
Find an appropriate method for modelling MEMS and to reduce the computation cost.
Demonstrate the validity of the modelling method with MEMS components
I demonstrated that it was possible to do real-time simulation by implementing Cosserat theory into haptic sensing technology.
Analysis functional, UML diagram
For real-time simulation, optimized algorithms have been developed to meet the update requirements of the haptic system which consists of two loops: i) the haptic loop (also known as real time loop) which is updated at 1 KHz to avoid force artefacts since we are able to detect discrete event at less than 1 KHz and ii) the display loop (known as the scene graph loop) which is updated at 30 Hz since the Human Visual System (HVS) has a flicker fusion frequency around 30-60 Hz.
Testing/Debugging
I also developed a User-Friendly interface (C++) where cantilever, microbridge or membrane (plate) can be selected and enabling the user to interact with their MEMS components with force feedback rendering.
The program was about 15 000 lines
Technical Environment
C and C++ (Object Oriented, OO)
Microsoft Visual Studio .NET 2003, OpenHaptics (from SensAble)
OpenGL, libraries: GLUI and GLUT
MAPLE 10, ANSYS
MS-Project and MS-Office
Results & Benefits
First one to investigate this in my field.
A new approach has been developed for modelling MEMS components based on Cosserat theory which reduced the computation time and therefore enables real-time simulation.
13 International Papers/Journals have been published
11.03 MSC COURSEWORK IN DIGITAL SIGNAL PROCESSING, HERIOT-WATT UNIVERSITY
Objective
The objective of the coursework was to design an FIR filter to isolate a single Dual Tone Multi-Frequency (DTMF)
Approach
Write a MATLAB script that will generate a DTMF test signal representing a seven digit telephone number
Design a Bandpass FIR Filter Design; using MATLAB the Bandpass FIR Filter coefficients was generated
Testing the FIR Bandpass Filter using MATLAB
Testing the Real-Time Implementation of a Bandpass FIR Filter using the C6711 DSK
Technical Environment
Code Composer Studio (CCSTUDIO)
C6711 DSK
Matlab
Oscilloscope
Excel
Results & Benefits
Report about the design of the FIR filter has been supplied
I completed this project successfully, marks obtained 85%,
05.04 – 09.04 MSC DISSERTATION – AUTONOMOUS VEHICLE – HERIOT-WATT UNIVERSITY
Objectives
The objective of this project was to compare the performance, the efficiency and the reliability of different devices/sensors which can provide similar functions using different technologies. In this project, the analysis of the different devices was focused mainly for robot vehicle applications, and finally a small on board processing was also achieved with different boards built on it.
Approach
Study the sensors
Evaluate the performance of different sensors, e.g. ultrasonic sensors vs. infrared sensors to detect objects and avoid them.
Integrate the sensors on a robot
Testing/debugging
Technical Environment
C programming (MPLAB IDE), microcontroller (PIC 18F452)
DC motors, H Bridge circuit, Oscilloscope
SRF04 ultrasonic sensor (Devantech)
Sharp Infrared sensor, Light sensors, Motion sensors
Results & Benefits
Two vehicle robots have been built
MSc dissertation submitted
I completed this project successfully, marks obtained 75%
03.04 – 04.04 MSC COURSEWORK – EMBEDDED PROJECT – HERIOT-WATT UNIVERSITY
Objectives
The aim of this project was to build a robot which was able to detect object, organise the search operation (to detect object) and create an on-screen map. A controlling computer (an IBM PC + serial I/O + ZComm) was used to connect to the vehicle via an umbilical cable.
Approach
Integrate reflective object sensors to detect wheel position and to provide position sensing
Write an algorithm to organise the search operation
Program the controlling computer to send and receive data from the robot and to create an on-screen map
Testing/Debugging
Technical Environment
C programming, MPLAB IDE
Borland C++ Builder 6.0
Microcontroller: PIC 18F452 (Microchip)
RS232C
05.02 – 06.02 BENG COURSEWORK: LOCAL AREA NETWORK (LAN) – UNIVERSITY OF BRIGHTON
Objectives
The aims were to design a microprocessor-based system. The objectives was to design, built, test and commission a 68HC001 microprocessor-based system, to manage a small team, plan a medium size team project, write an appropriate system software in 68HC001 assembly language and use appropriate test equipment.
The network was intended to represent part of a car management unit, the system comprised three nodes and the data was to be transferred around the network from one node to the next node using asynchronous serial communications. This project was undertaken in a group of three students.
Approach
My responsibilities were to:
Design/Build the serial communication board
Write the appropriate software for reception and transmission of the data
Program in VHDL the PLD (Programmable Logic Device)
Test the serial communication board with the memory and interface boards
Technical Environment
Assembler
6850 ACIA (Asynchronous Communication Interface Adapter)
RS232C
ASIC device, BRG (Baud Rate Generator)
Electronics components such as 74LS93 and 74LS157, Oscilloscope
VHDL
PLD 16V8
1. COMPETENCES
Gained my PhD in Microsystems and my Master of Science (MSc) in Embedded Systems with high honours. Strong development skill in C++ C, high analytical capability and can grasp new topics quickly. Eager to obtain knowledge and gain skill. Experience in Software Engineering, testing/debugging, microcontrollers, modelling Micro-Electro-Mechanical Systems (MEMS) and knowledge in TCP/IP.
Multidisciplinary skills combined with high level of devotion and team spirit.
1. SECTORS
Embedded systems
Human-Computer Interaction (HCI) & Haptic sensing technology
TCP/IP and networking
Electronics
MEMS modelling
2. SKILLS Management
Project management
Team Coordination
Coaching
3. Functional
Requirement specification analysis
Market research study
Design study
Technical
Languages : C++, C, Assembler
OS :Windows, Solaris, Fedora, Red Hat
Tools : Microsoft Visual Studio .NET 2003, Borland C++ Builder 6.0, OpenGL (GLUI & GLUT), Fortran, The OpenHaptics Toolkit (SensAble), MPLAB IDE (Microchip), OrCad, Multisim, Proteus, Texas Instruments - Code Composer Studio IDE, Quartus II (Altera), Finite Element Method Magnetics (FEMM), ANSYS, Maple 10.
Microsoft Office: Project, Word, Excel, Front Page, PowerPoint, Visio
Modelling: UML
Interface/Protocols: TCP/IP, IP routing protocols, RS232, CAN, I2C, SPI
Network: Self-study Cisco Certified Network Associate (CCNA)
4. LANGUAGE SKILLS
Language Written Reading Conversation
French Native Native Native
English Excellent Excellent Fluent
Turkish Intermediate Native Native
5. PERSONALIA
Nationality: French
Living in Brussels
Born on 04/01/1981
Single
2. EDUCATION & TRAINING
Jan. 2005 – Nov. 2007: Doctor of Philosophy (PhD) in Microsystems
Heriot-Watt University, Edinburgh, UK.
Thesis: Haptic sensing technologies for MEMS design and manufacture
PhD fully funded by the Engineering and Physical Sciences Research Council (EPSRC).
2003 – 2004: Master of Science (MSc) in Embedded Systems Engineering Heriot-Watt University-Ranking: High Honours, one of the top students.
MSc fully funded by ESF.
2001 – 2003: Bachelor of Engineering (BEng) Honours in Electronic and Computer Engineering.
University of Brighton, UK.
2001 – 2002: Diplôme Universitaire d’Etudes Technologiques Internationales (D.U.E.T.I), Université Joseph Fourier (Grenoble, France) and University of Brighton.
1999 – 2001: Diplôme Universitaire de Technologie (D.U.T), Génie Electrique et Informatique Industrielle (GEII).
Université Joseph Fourier – Grenoble.
1999: Baccalauréat Scientifique
Additional Training:
• Training regarding Enhanced Telecom Operation Map (eTOM) at Altran Europe, Brussels – Belgium.
• 15/03/2005 - 16/03/2005: Training about Application Programming Interface (API) at Reachin, Stockholm – Sweden.
• 30/04/2001 – 07/07/2001: Training Placement at Renault Trucks, Design and Test of an automatic control valve E.G.R (Exhaust Gas Recirculation). St Priest – France.