Tiger Scramble Robot Design Hannah Hoppenstedt Josh Nelson

1. Tiger ScrambleRobot DesignHannah HoppenstedtJosh Nelson

2. Presentation Outline • Major Component Connections • Operations • Subsystems and Components • Requirements • Component Specifications • Budget

3. Major Component Connections Communication Ball Control RF Receiver Servo Brains BS2 BS2p 40 Bumper Switch Locomotion MMC Motor Motor

4. Operations • Find closest ball to goal • Travel to and capture ball • Put ball in goal • Avoid opponent robot

5. Subsystems and Components • Microcontrollers • Locomotion • Motors • Wheels • Ball-Control Apparatus • Battery • Chassis

6. Communication Requirements • Receive data from vision system • Want to receive every packet • Do not want BS2p40 tied up for 33 ms per packet

7. Basic Stamp 2 • Receives info from the vision system • Sends the data to the BS2p 40 for calculations • At the maximum flow control baud rate of 19.2k, it takes 3.75 ms to send 9 bytes • BS2 to BS2p Connection (4 I/O pins) • One pin for serial data transfer • One pin for flow control • Two pins for handshaking

8. AI Requirements • Calculations on vision system information • Distance • Angle • Integer Comparison • Interpret commands from Vision System • Execute all functions between packets • 100 ms between first bits of two consecutive packets • Memory • 53 Bytes

9. Basic Stamp 2p 40 AI Requirements

10. Control RequirementsComponent Connection • Sufficient number of I/O pins • Control servo (1) • Bumper switch (1) • Motor Mind C (2) • Fill registers on MMC to control speed and direction • BS2 (4) • Need 8 I/O pins

11. Basic Stamp 2p 40 AI

12. Connection Need 8 I/O pins BS2p 40-pin module has 32 general purpose I/O pins Memory Need 53 bytes BS2p has 128 bytes of scratch pad RAM and 26 bytes of variable RAM Basic Stamp 2p 40 AI

13. Locomotion Requirements • Motor Control • Motors • Motor Mounts • Wheels • Wheel hubs

14. Motor Control Requirements • Generate pulse width modulation • Speed control • Provide adequate current to motors

15. Motor Mind C • Generate pulse width modulation • Duty cycle of PWM varied according to register value in serial mode • Includes 2 H-Bridges • Current control • Connected to each motor with three output lines

16. Motor Requirements • Sufficiently low stall current • 1.5 A • Lightweight • Speed • 0.5 m/s • Torque • Minimum 18.08 oz-in

17. Copal Gearmotor 60:1

18. Motor Mount • Lexan • Light weight • 4 grams • Simple assembly

19. Wheel Requirements • Provide adequate ground clearance • Minimum of 2 cm • Shock absorbent for motors

20. Lite Flite Wheels • Foam • Light weight • 11.3 g each • Shock Absorbent • Ground Clearance • 6.35 cm diameter wheels • 3 cm

21. Ball-Control Apparatus • Gripper • Simple design • Detect Ball Capture • Bumper Switch • Ball Capture • Servo and armature

22. Detect Ball Capture SPDT Switch SL-2NW1 Ball Capture Servo and armature Futaba Continous Rotation Servo Ball-Control Apparatus

23. Battery Requirements • 12 V • Speed control flexibility • Withstand 15 minute rounds • 0.3 AH at 12 V

24. Battery Usage Capacity = Total Power / 12V * (15 / 60) = 0.3 AH

25. 12-V 500 mAH NiMh Brick AntPack • 0.5 AH exceeds required 0.3 AH • Meets 12 V requirement • Run Time = 25 mins.

26. Chassis Requirements • Space availability • Allow easy access to parts • Flat black top • Flat front for ball control apparatus • Lightweight • Durable

27. Expanded PVC • Weight • 450 g with standoffs • Weight Limit • 4 kg • Need 750 g • Easy to design and build a robot out of this material • Easy to implement multiple decks

28. Battery Bottom Chassis layer

29. Middle Chassis layer Bumper Switch Servo Receiver BS2 BS2p MMC

30. Top Chassis Layer

31. Budget Revision 2

33. Conclusion • Simple design • Meets requirements • Speed • Microcontroller capabilities • Ball control • Within budget

34. Questions or comments?