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Institute for Personal Robots in Education Kickoff Meeting, September 15, 2006 Hardware Professor Tucker Balch Keith O’H

Institute for Personal Robots in Education Kickoff Meeting, September 15, 2006 Hardware Professor Tucker Balch Keith O’Hara Dan Walker Ben Axelrod Hai Dai Can Envarli. Off-the-shelf Candidates. Lego Mindstorm NXT ($300) Parallax Scribbler ($80) Parallax Boebot ($150)

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Institute for Personal Robots in Education Kickoff Meeting, September 15, 2006 Hardware Professor Tucker Balch Keith O’H

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  1. Institute for Personal Robots in Education Kickoff Meeting, September 15, 2006 Hardware Professor Tucker Balch Keith O’Hara Dan Walker Ben Axelrod Hai Dai Can Envarli Georgia Institute of Technology

  2. Off-the-shelf Candidates • Lego Mindstorm NXT ($300) • Parallax Scribbler ($80) • Parallax Boebot ($150) • Parallax Crawlers ($400-600) • Palm Pilot Robot Kit ($300) • Lego Mindstorm ($200) • Handyboard ($300-400) • Handyboard Cricket ($59-$100) • iRobot Roomba ($200-350) • Khepera ($2000) • TERK • Humanoids • AIBO Georgia Institute of Technology

  3. Some Details • Lego Mindstorms NXT ($300) • 32-bit ARM7; 64Kb RAM; bluetooth; USB • 3 servos (built in rotation sensors) • Ultrasonic, Sound, light and touch sensors (digital wire interface) • Microsoft robotics studio • Palm Pilot Robot Kit (Acroname $300) • (IR rangers, omni-directional wheels) • Body-less Handyboard Cricket ($59) • Two sensors, Two Motors, IR communication • Programmed in Logo (4k external memory) • Expansion ports for mores sensors and motors Georgia Institute of Technology

  4. iRobot Roomba • Roomba ($150-250) • 2 bump sensors • Odometery • IR wall sensor on right side • Cliff/pickup sensors • Virtual wall infrared sensor • Remote control infrared sensor • Vacuum and motor control • Serial interface • Roombadevtools Bluetooth Interface ($100) Georgia Institute of Technology

  5. Scribbler • Scribbler ($80) • Sensors • IR “ranger”; 2 receivers and emitter • Stall sensor • 3 light • 2 “line” (IR pairs) • 2 DC motors • Programmed in PBasic • Serial communication (up to 38400 baud) • SD202 Bluetooth adapter ($100) • Serial emulation • Class 1 Georgia Institute of Technology

  6. Brain-less Bluetooth Robots? • 2 Windows XP SP2 dell laptops • 2 Cellink Bluetooth 2.0 USB Dongles • Measure latency of varying size forward packets and 1 byte reply • 3 different conditions • 5 ft. separation • 30 ft. separation • Background 802.11b flood ping • 10,000 samples Georgia Institute of Technology

  7. Bluetooth Latency Georgia Institute of Technology

  8. Bluetooth Throughput Georgia Institute of Technology

  9. Scribbler Results • Latency histogram • (1 byte roundtrip) • Limited by serial baud-rate and basic stamp not bluetooth • Interference and retransmissions could have effect Georgia Institute of Technology

  10. Locomotion • Holonomic design • Arbitrary robot translation / rotation • No caster needed • Three wheel drive is complex • Wheels are difficult to make • Differential drive • Point turn Georgia Institute of Technology

  11. Processor Options • Philips 32bit ARM $7.58 • 60MHz 46 GPIO • 16 kB RAM, 256 kB program memory (32x GNAT) • Philips 32bit ARM $10.09 • 60MHz 81 GPIO • 64 kB RAM, 1000 kB program memory (128x GNAT) • BGA package complicates routing • Philips 32bit ARM $15.18 • 60MHz • 512 kB RAM, 8000 kB program memory (1000x GNAT) • External memory (program flash, RAM) • Sharp 32bit ARM $26.49 • 77MHz • 8000 kB RAM, 8000 kB program memory (1000x GNAT) • External memory (program flash + SDRAM) • Includes Memory Management Unit (Fully linux capable) Georgia Institute of Technology

  12. Wireless Options • Custom protocol 400MHz 64 kbps $5.04 • Zigbee 900MHz 250 kbps $7.14 • Bluetooth module 2.4GHz 3Mbps $23.00 • Bluetooth chip 2.4GHz 3Mbps $5.52 Georgia Institute of Technology

  13. Bluetooth Options • Serial Port Module • Expensive • Chip • Cheaper • More flexible • Not limited to serial port style • Use “headset” audio features • CSR • External flash memory allows custom programming • Onboard micro can run upper Bluetooth stack or our own applications • Reduced datarate and total connections • GaTech (Thad) already has purchased development kit • Interface: serial port profile (high level), RFCOMM, L2CAP (low level) Georgia Institute of Technology

  14. First Tier Sensors • Lidar laser range finder / bar code reader • One spinning mirror, laser and detector for both technologies • 640x480 color CMOS camera with lense (OV7649) • Coprocessor for color segmentation, background subtraction • $18 • Dual axis magnetometer (HMC1052) • Non-line-of-sight bearing to magnetic beacon, compass • $5.50 • Microphones for sound localization • Are dual microphones worth cost & processing? • Dual piezoelectric vibration detector • $0.49 • Temperature Georgia Institute of Technology

  15. Second Tier Sensors • Photoresistor, solar cell, phototransistor ambient light detector • Hall-effect magnetic sensor • IR line detector, obstacle detector, Sharp rangers • IR reflective grid for localization • Bump switches • Accelerometer for motion detection, bump sense ($5.51) • Ultrasonic • Capacitive electric field sensing (touch, proximity) • Passive IR motion detector (burglar alarm) • Optical computer mouse sensor for odometry • Metal detector • Thermopile non-contact temperature sensing Georgia Institute of Technology

  16. Lidar Circuit • -126 dB laser power return over 10m w/ 1” receiver lense • 1mW laser -> 0.3 nA photocurrent Georgia Institute of Technology

  17. Lidar Spice Simulation • Phase detector compares received signal with reference signal • Robust to the presence of noise • Output is DC signal - sensor bandwidth determined by output filter • Output is logarithmically amplified to increase dynamic range Georgia Institute of Technology

  18. Motor Options – DC Gearhead • DC Gearhead Pros • Widely available • Simple driver electronics • Medium efficiency • Brushes automatically adjust speed and current draw to match requested torque • Current draw is a good indicator of requested torque – “stall sensor” • DC Gearhead Cons • The gears are more expensive than the motor • Poor reliability in our price range – plastic parts, brushes, bad bearings, etc • No encoder and expensive to add encoder • Brushes cause high electromagnetic noise levels which interfere with other electronics, especially sensors • Acoustically noisy Georgia Institute of Technology

  19. Motor Options – Stepper Motor • Stepper Motor Pros • Naturally low speed, high torque – no gears necessary • Controllable in precise rotational increments – no encoder necessary • High reliability – metal construction, ball bearings, no brushes to wear out • Motor bearing can be wheel bearing • No brushes means low electromagnetic noise • Higher power (RPM or torque) than DC gearhead • Stepper Motor Cons • Low efficiency • Heavy • More complex electronics • Electrically commutated – software must do the job of brushes in the DC gearhead • Motor cannot deliver high torque at high RPM so software must slow motor if high torque is required • Hard to predict torque Georgia Institute of Technology

  20. Power Options – Alkaline, Tether • Alkaline Pros • Medium power density • Medium energy density • Student purchasable • Not including rechargable batteries reduces price of robot for us • Alkaline Cons • Not rechargable • ~ 10K batteries landfilled per year • Only available in common form factors (AA, AAA, etc) • Tethered Pros • Medium power density • Infinite energy density • Cheapest solution • Most reliable communications • Tethered Cons • Tether interferes with robot operation • Tether annoyance increases with number of robots deployed Georgia Institute of Technology

  21. Power Options – NiMH, NiCd, Lithium • NiMH, NiCd Pros • Cheapest rechargeable option • NiMH, NiCd Cons • Low power density • Low energy density • Lithium Pros • High energy density • Least weight • Lithium Cons • Expensive • Low power density • Complicated charging Georgia Institute of Technology

  22. Battery Options – Lead Acid • Lead Acid Pros • Highest power density • Low internal resistance means less motor generated electromagnetic interference • High energy density • Lead Acid Cons • Heavy • Must not be allowed to completely discharge or battery capacity will suffer • Will retain charge for 2 years Georgia Institute of Technology

  23. Example Budget • Processing: $15.18 • Wireless: $13.30 • 3 Motors & motor drivers: $33.35 • Lidar: $20.68 • Camera: $9.43 • Additional sensors: $8.94 • Battery: $14.01 • Manufacturing: $20.00 • Total: $134.89 Georgia Institute of Technology

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