S15: Hand Gesture Recognition using IR Sensors

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Abstract

The aim of the project is to develop hand gesture recognition system using grid of IR proximity sensors. Hand gestures like pan, thumbs-up, moving hand back and forth, up and down or left and right can be recognized. These gestures can be used to control different devices or can be used in various applications.The system will recognize different hand gestures based on the IR proximity sensor values.

Objectives & Introduction

The idea is to make a 3x3 grid of using IR proximity sensors, and connect them via analog multiplexers to the ADC pins on SJONE board. As we move our hand in front of the sensor grid, the corresponding values of the sensors will change in a specific pattern. We will map this specific change in values to a gesture. Similarly we will be able to map gestures such as swipe left, swipe right, swipe up and swipe down.


IR Sensors- For the project we are using sensors manufactured by Sharp to determine distance from the objects. The sensors have a range from 10 to 80 cm. The analog voltage output varies with the distance of the object, it is 3 Volts when an object is 10 cm away while it is 0.4v when object is 80 cm away. The ideal operating voltage for the sensor is 4.5 to 5.5 volts.


Analog Multiplexers- We are also using 3 Analog 4:1 multiplexers. This is because SJONE board only has 3 ADC pins where as our sensor grid consists of 9 sensors. The GPIO pins of SJONE board will act as select lines to the multiplexers. The select lines will be common to all multiplexers.

Team Members & Responsibilities

  • Harita Parekh
    • Implementing algorithm for gesture recognition
    • Implementation of sensor data filters
  • Shruti Rao
    • Implementing algorithm for gesture recognition
    • Interfacing of sensors, multiplexers and controller
  • Sushant Potdar
    • Implementation of final sensor grid
    • Development of the application module

Schedule

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Week# Start Date End Date Task Status Actual Completion Date
1 3/22/2015 3/28/2015 Research on the sensors, order sensors and multiplexers Completed 3/28/2015
2 3/29/2015 4/4/2015 Read the data sheet for sensors and understand its working. Test multiplexers Completed 4/4/2015
3 4/5/2015 4/11/2015 Interfacing of sensors, multiplexers and controller Completed 4/15/2015
4 4/12/2015 4/18/2015
  • Implementation of sensor data filters
  • Implement algorithm to recognize left-to-right movement
Ongoing
5 4/19/2015 4/25/2015
  • Implementation of final sensor grid
  • Implement algorithm to recognize up-to-down movement
  • Implement algorithm to recognize right-to-left movement
Scheduled
6 4/26/2015 5/2/2015
  • Implement algorithm to recognize pan movement
  • Implement algorithm to recognize down-to-up movement
  • Develop the application module
Scheduled
7 5/3/2015 5/9/2015 Testing and bug fixes Scheduled
8 5/10/2015 5/16/2015 Testing and final touches Scheduled
9 5/25/2015 5/25/2015 Final demo Scheduled

Parts List & Cost

Design & Implementation

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Hardware Design

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Hardware Interface

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Software Design

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Implementation

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Testing & Technical Challenges

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My Issue #1

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Conclusion

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Project Video

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Project Source Code

References

Acknowledgement

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References Used

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Appendix

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SR# Component Name Quantity Price per component Total Price
1 Sharp Distance Measuring Sensor Unit (GP2Y0A21YK0F) 9 $14.95 $134.55
2 STMicroelectronics Dual 4-Channel Analog Multiplexer/Demultiplexer (M74HC4052) 3 $ $
3 SJ-One Board 1 $80 $80