1. Daniel Bressan David Tran Robbie Banks Amit Kapoor MACH 1/7

2. To build and design a fully functional, completely electric remote controlled car that will be able to reach speeds greater than a 100 miles per hour. David Tran

3.  Have a control system that ensures stability at high speeds.  Develop a power system to power all necessary components within the car.  To design a high performance chassis and shell.  Use an onboard microcontroller to integrate all the various systems within the car.  Integrate a RF system for communication between a laptop and the car. David Tran

5.  We will build a GUI interface to control the car.  Mouse  Keyboard  GUI will control speed and steering.  Debugging  Force Sensor  Optical Encoders  Battery Amit Kapoor

6.  Testing/Backup  2 Channel Pre-Built RF Radio  27 MHz  Testing/End User  Xtend-PKG  900 MHz  Via Serial Port  Size  Will go both ways  Display speed in GUI  Debugging Daniel Bressan

7.  MSP430-F2616  Cheap  Same Processor as Power Lab  Support  Control  Speed  Stability  Power  RF  Specs  JTAG  RISC  Low Power David Tran

8.  LiPo 3 cell Batteries  Quick Constant Power  High Amps  Supply Power to  Motors  CPU  Speed Encoders  Force Sensors  Gyroscope  RF Robbie Banks

9.  Three Phase Brushless Motors  Constant power supplied  Good torque at high speeds  Low Turn Motor for higher RPM  Programmable for high efficiency at low and high speeds  Need upwards of 10-15 thousand RPM  Possibly 2 for 4WD Robbie Banks

10.  The motors take three inputs, each is a sin wave 120 degrees out of phase with each other. Robbie Banks

11.  A three phase output is created by turning on and off the six transistors at a specific frequency and time.  We will need to regulate the frequency so that we get maximum acceleration Robbie Banks

12.  Speed Encoders  Relay speed to MCU for stability  Relay speed back to user  Sensors  Force Sensor  Anti-Lift  Inclinometer  Steering  Pre-Built  Stepper Motor  Gyroscope David Tran

13.  Create own starter kit for testing  Kitchen cutting board for chassis  Motors  Wheels  Axels/Gears  After electrical complete start:  Chassis (Aluminum)  Shell (Carbon Fiber) Robbie Banks

14. TaskAmitDanielDavidRobbie Electrical Control Systems xx Power Systems xxx Populate PCB xxxx Mechanical Chassis xx Mounts xxxx Controls xx Software GUI xxxx Micro Controller xx Systems Integration xxxx Testing xxxx Documentationxxxx Amit Kapoor

16. ElectricalPriceQuantityTotal Price for Part Batteries$60.002$120.00 Micro Controller$20.001 Components$60.001 Gyroscope$40.001 Force Sensor$30.002$60.00 Shaft Encoder$100.001 PCB$130.001 Mechanical Motors$200.002$400.00 RC Starter Kit$100.001 Gyroscope$30.001 Chassis$100.001 Components$100.001 Miscellaneous Display Board$21$2.00 Presentation/Documentation$30.001 Shipping$30.001 Total $1,322.00 Amit Kapoor

17.  From our predictions this project is feasible!  Stay within Budget and Schedule  Finish Line RC  Budget  10% off  Accessibility to parts  Good allocation of tasks  Hard Work  Team Work  90% of Project Management is COMMUNICATION Daniel Bressan

18. RISKRECOVERY  Schedule  Big Project  Budget  Money for all needed parts  Knowledge  Learning software/components  Motors  Speed and cost  Weight  Breaking Car in Testing  Schedule  Replace pre-build products as needed to stay on schedule/testing  Budget  UROP  Out of pocket  10% off  Knowledge  Ask questions  Google  Data Sheets  Finish Line RC  Motors  Be specific  Talk to experts  Breaking Car in Testing  Be very very carful  Sensors  Kitchen cutting board Daniel Bressan