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Hand Gesture Remote Control

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Justin Johnson, Joe Pommier, Mike Wang A consumer device that just works Consists of a single box that can be plugged in, easily configured for your television ... – PowerPoint PPT presentation

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Title: Hand Gesture Remote Control


1
Hand Gesture Remote Control
  • Justin Johnson, Joe Pommier, Mike Wang

2
Overview
  • A consumer device that just works
  • Consists of a single box that can be plugged in,
    easily configured for your television, and will
    work reliably indefinitely
  • Works with already functional infrared remote
    control receivers built into most television sets
  • Uses infrared light to track movements

3
Camera Module
  • Encompasses camera, clock generation, and logic
    level translation circuitry
  • Camera is a Pixart infrared sensitive digital
    camera with onboard digital signal processing

4
Camera Module
  • Use a crystal oscillator and double inverters to
    create 25MHz clock
  • Using an LTC4301 I2C bus buffer chip, perform
    logic level translations between 5V on the
    Arduino side and 3.3V on the camera side
  • With properly written software, communication
    with the camera was successful

5
Camera Module Testing and Construction
  • Laid out circuit in Eagle and ordered a PCB
  • About to solder on the camera and realized the
    pins were reversed
  • Had to re-layout the PCB
  • Tested the clock circuit by plotting the waveform
    on an oscilloscope
  • While the clock wasnt close to a perfect square
    wave, the rise and fall was fast enough (lt2ms)
  • Once software was written, the I2C signals were
    able to be seen on an oscilliscope

6
Infrared Transmitter
  • Simply an infrared LED modulated at 36KHz
  • Turned on and off 67 times for various times,
    specified in milliseconds
  • Tested by writing a simple program to loop
    through various remote control codes that were
    recorded
  • Verified that TV reacted in the way expected

7
LED Array and Constant Current Source
  • Infrared 20x10 LEDs for releasing Infrared light
    flood
  • 1.7 V, 50mA DC voltage and current through each
    LED

8
LED Array and Constant Current Source
  • Power Supply a 36V AC/DC Voltage Converter
    (Input 110V AC, Output 36V DC)
  • Constant current source is made of 10 LM317
    Voltage Regulator and 10 100ohm resistors
  • Each LM317 with a 100ohm resistor with it is
    connected in series with each row of LEDs
  • Input Voltage for each row of LEDs 36V
  • Input Current for each row of LEDs 5055mA
  • System Power Consumption 20 Watts

9
Constant Current Source
10
Constant Current Source Development and Testing
  • Initially we used Current Mirrors for making
    constant current, including 11 NPN BJT
    transistors successfully simulated, inconsistent
    at proto-type performance
  • We upgraded Current Mirrors to Wilson Current
    Mirrors by adding extra transistors to the
    mirrors in order to stabilize the outputs
    successful at supporting a single row of LEDs,
    unsuccessful at supporting multi rows of LEDs
  • We also thought of using Op-Amps, but its not
    cost-effective and it is hard to get Op-Amps with
    36V tolerance.

11
Final Design Reasoning
  • Why we chose LM317 circuit plan
  • Initially we chose Current Mirrors for
    lowering manufacturing cost, but neither Wilson
    Current Mirrors nor Op-Amp costs less than LM317.
  • All other plans result over-heating problems
    for resistors as well as large power consumption

12
Final Development and Testing
  • Current Measurements our final design shows that
    there is a current between 52.153.1 mA DC
    current through each row of LEDs with consistent
    performance
  • LEDs have been on duty without a single failure
    for more than 45 minutes of testing since the
    completion of the LED Array.
  • Temperature of resistors in the current source
    circuit has been significantly lowered.

Row Current (mA)
1 52.3
2 52.5
3 52.5
4 52.1
5 53.1
6 52.6
7 52.8
8 52.9
9 52.4
10 52.8




















13
Gesture Recognition Software
  • Initializes and samples coordinate data from the
    Pixart camera via I2C.
  • Stores and operates on the data received from the
    camera.
  • Upon successful recognition of a gesture, outputs
    the corresponding signal to the television.

14
Software Development
  • At first, wanted to have a sliding window of
    received coordinates with constant comparisons to
    an accepted gesture for all four of the available
    points given by the camera.
  • Due to the severe limitations of our
    microcontroller, the gesture software had to be
    toned down.
  • We decided to operate only on most prominent
    received point, and only detect the most
    rudimentary (straight line) gestures.

15
Software Implementation
  • The recognizing algorithm stores (x,y) data into
    arrays. Upon seeing blank frames, or after one
    second data storage, it sends this data to a
    function that looks for a gesture.
  • To find a gesture, we first find the distance the
    point moved in both the x and y directions. We
    then check direction of movement, and distance of
    movement to determine whether or not we can
    consider the data to contain a gesture.
  • If a gesture is detected, we send a series of
    pulses to the IR transmitter to control the
    television.

16
Software Testing
  • The first version of the software that we used to
    test simply relayed what the camera saw to a
    computer desktop. This was used extensively in
    debugging the later code and the hardware.
  • The final software had to go through a couple
    iterations as we did not know the capacity of the
    Arduino, and so we had to compensate for a low
    memory, low processor situation.
  • The software was then calibrated for minimum
    pixel movement to help filter out small movements
    as gestures.

17
Final Testing
  • Once all the components were assembled, we
    addressed fine-tuning issues
  • We were unable to get enough infrared light to be
    reflected off our fingers
  • We tried using aluminum foil to reflect more
    light
  • This provided more reflection, but the useful
    range was limited to about one foot
  • Assembled a small LED pen in order to provide a
    single point source of light for the infrared
    camera

18
Final Testing
  • With this point source of light, we were able to
    exceed 6 feet of range
  • Having overhead lights on interfered only if the
    lights were in the line of sight

19
Future Improvement Solutions
  • To find better reflection material in order to
    increase remote range and efficiency
  • To use stronger and fewer infrared LEDs for
    better performance and lowering manufacturing
    cost
  • To use more advanced cameras to increase
    gesture detection ability

20
Adaptability and Marketability
  • Low Cost Analysis
  • Proposed Manufacturing Cost
  • Camera 35
  • Microcontroller 1015
  • LM317 x10 35
  • LEDs and other minor components lt 5
  • Total lt 30

Prototype Cost 144.47 Development cost for
Natal ???
Whats the price you are expecting from our
potential competitor Natal? 100? 200? or 300?
21
Adaptability and Marketability
  • Fields which this low-cost gesture remote system
    can be applied at
  • Basic TV Remote
  • Projector
  • Active Video Game Devices
  • Confidential Access Devices
  • Dancing and Other Entertainment Devices

22
  • THANK YOU FOR COMING TO OUR PRESENTATION!
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