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| Futurelabs Objectives |
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- To bridge the gap between institute curriculum and industry requirements by integrating trainees into Cybermotion’s R&D Projects (Live Projects).
- You will be trained by Industrial Embedded systems experts. Providing industry relevant, hands-on, state-of-art, Embedded as well as Software Development experience.
- Project based training:
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- It’s a unique programme where incoming engineers will work as interns doing our projects along side our R&D Team.
- Trainees work on our actual Embedded projects
- This is possible due to our 14 years of continuous R&D in the field of Embedded Systems, Mechatronics, Robotics, Weapons Systems, 3D Simulation and Control Software Development.
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Training Duration
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5 Months |
| Classes |
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5 Days/Week |
| Schedule / Day |
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2 Hours |
| Batch Size |
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20 Members |
| Training Fee |
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Rs.30,000/- Introductory Offer |
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| Training Methodology |
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| This is a 2 step process |
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| Step 1 : Theory & Lab: (Duration : 1½ Months) |
- Interactive classroom and lab
- Programming in C , C++ , UML
- Digital and Analog Electronics
- Networking
- Control Systems
- Digital Signal Processing
- Embedded System using AVR microcontrollers
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- Simulation
- Debugging
- Implementation on hardware
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- Circuit Schematics, Layout
- Soldering – Leaded components, SMD
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- Step 2: PROJECT BASED LEARNING: (Duration : 3½ Months)
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- Live project with our In-House R&D.
- DSP background : Texas Instruments 32 bit DSP TMS320F28xx
- ARM background : ARM7TDMI
- C++, OOPS, UML (Design Documentation), Design Patterns, 2D, 3D graphics: Software Development skills are essential to be a complete engineer.
- Implementing Industrial protocols like CAN, RS485, TCP/IP, SSI, I2C and RS232.
- Project Management and Quality Assurance System ( ISO 9001:2000)
- Placement Assistance
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| Syllabus |
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| Module 1: |
| C Programming |
| Data Types, Operators, Preprocessor directives, Bitwise operators, Sequence, Decision, Switch-Case, Loops, Arrays, Strings, Functions, Recursion, Storage Classes, Structures, Unions, Pointers basics, pointers advanced(i.e. related to arrays, functions, structures). |
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| Objectives: |
| In depth programming for Embedded Systems as well as PC. Latest Microcontrollers and DSP’s are ‘C’ optimized. |
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| Module 2: |
| C++ Programming |
| Procedural vs. OOPS, Data types, Control Instructions, Classes and Objects, Access Specifiers, Static Members, Inline Functions, This Pointer, Constructors, Destructors, Function Overloading, Operator Overloading, Friend Functions, Inheritance, Polymorphism, Virtual Functions, Templates, Exception Handling |
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| Objectives: |
| Most Embedded Systems need to be controlled, monitored, setup by PC with an in depth skill in C++. One can develop powerful object oriented applications. |
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| Module 3: Introduction to Embedded Systems & Microcontrollers. Atmel AVR ATmega32 |
| Introduction to ATMEGA32, PIN Configuration and description, Types of Memories , Instruction Set , internal EEPROM, GPIO, interfacing LED’s, Switch’s, Motor, Stepper Motor, AC load, UART , LCD Analog to Digital Converter, Pulse Width Modulation, I2C and SPI Protocols, Mini Project. |
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| Objectives: |
| This powerful but simple microcontroller introduces the engineer to Embedded Systems. The architecture, Peripherals and Programming of this microcontroller is similar to more powerful processors such as ARM and DSP’s. |
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| Module 4: (ARM LPC2129 & 38) |
| Introduction to ARM and ARM family, Introduction to 7TDMI core, Introduction to LPC2129 & LPC2138, Pin description, Brief discussion about GPIO in LPC2129, How to interface LCD with LPC2129, Brief discussion about UART in LPC2129, Pulse Width Modulation. |
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| Objectives: |
| This microcontroller is state –of – art and the most popular through out the world. |
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| Module: 5 (DSP) |
Basic idea of DSP and DSC. Implementing FFT, IIR and FIR in Digital Signal Processing. Digital Signal Processor Description (TMS320F2812)Architecture, Block diagram, Features, Pin Description, Instructions Set, Interrupts Handling Techniques, Sensors (Encoder, Magnetic encoder, Hall Sensors, Temperature) UART, Analog to Digital converter, Pulse Width Modulation, Analog Signal Conditioning, LCD and SPI.
Lab hardware set-up, Creating projects programming and Debugging DSP. |
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| Objective: |
| Most of the industrial applications can be vastly improved by implemting them on a powerful 32 bit DSP. |
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| Module 6: PROJECT |
| One of our Current R&D Projects |
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| Objective: |
| The most important part of FutureLabs where you work on one of our current R&D Projects. Lot of scope for accelerated learning and innovation. |
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