Difference between revisions of "User talk:RachelWinsor"

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m (update to communication device)
m (update to microphone information)
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'''Design Update (14/6/17):'''
 
'''Design Update (14/6/17):'''
  
Instead of using the XBee module, and building a shield from the open-source schematic (listed above), we have decided to take a simpler approach in using RF communication.  I will use one NRF24L01 chip on the subject, and one on the robot.  Through configuration, the subject will effectively be the "transmitter", and the robot will be the "receiver" of accelerometer data.
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*Instead of using the XBee module, and building a shield from the open-source schematic (listed above), we have decided to take a simpler approach in using RF communication.  I will use one NRF24L01 chip on the subject, and one on the robot.  Through configuration, the subject will effectively be the "transmitter", and the robot will be the "receiver" of accelerometer data.
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*For the microphone/audio input on the robot, I have considered three devices available in the lab. 
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The first is the MAX4466 Electret microphone. 
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This microphone comes on a breakout board, with an adjustable gain amplifier. 
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The specs for this board can be found [https://cdn-shop.adafruit.com/datasheets/MAX4465-MAX4469.pdf here]. 
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The second is the [https://datasheets.maximintegrated.com/en/ds/MAX9814.pdf MAX9814] electret microphone. 
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This microphone also comes with adjustable gain, though in this board it is automatic. 
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This is the device that will be used, for its automatic gain control, availability of online resources/similarity to MAX4466, and its range of noise detection.
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The final board is the LM393 comparator. 
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There is insufficient material online for this device, but it is generally accepted as a comparator.
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''This design change was discussed and approved by Prof Bonarini on 14/6''
 
''This design change was discussed and approved by Prof Bonarini on 14/6''

Revision as of 10:22, 14 June 2017

Design Consideration (13/6/17):

KROG Robot (sensors/modules)

  • Microphone + Gain amplifier => audio detection and preparation for filtering/analysis.

The particular module combines a simple microphone with a gain amplifier to make it easier to perform a frequency analysis on the input data. Our goal with this device is to detect the presence and frequency of an audio input (music) in order to tailor the "dancing" response of KROG.

  • Communication chip => communication between subject and robot.

For this communication chip, I propose using the XBee Pro S1 chip. I have more familiarity with ZigBee technology than with other communication technologies. The advantages of XBee include: low power consumption, sufficient range (up to 10m), closed network. I am open to learning other technologies, though I believe Bluetooth and WiFi would be impractical for this project (due to range and security protocols).

The communication module will be used to communicate the accelerometer/gyroscope information to the robot. This is to allow the robot to mimic the movements and speed of the user.

  • Custom Shield for Arduino Nano and XBee => Using the open-source Gravitech schematic, I will build the shield necessary to connect the Arduino with the XBee.

The most important aspect of this design is the power regulator to step down from +5V to +3.3V for the XBee input.

  • (potentially) Ultrasonic sensor => detect proximity of subject, objects, or Occupational Therapist (OT).

Subject (sensors/modules)

  • Communication chip => communication between subject and robot.
  • MPU 6050 Acclerometer/Gyroscope => detect movement of subject

This small device can be connected with the Arduino Nano in order to detect movement and rotation of the wearable device. This information will be communicated back to the robot, and then presumably mirrored.


Rachel and Prof Bonarini will meet at 10:00 on 14/6 to discuss this proposal



Design Update (14/6/17):

  • Instead of using the XBee module, and building a shield from the open-source schematic (listed above), we have decided to take a simpler approach in using RF communication. I will use one NRF24L01 chip on the subject, and one on the robot. Through configuration, the subject will effectively be the "transmitter", and the robot will be the "receiver" of accelerometer data.
  • For the microphone/audio input on the robot, I have considered three devices available in the lab.

The first is the MAX4466 Electret microphone. This microphone comes on a breakout board, with an adjustable gain amplifier. The specs for this board can be found here.

The second is the MAX9814 electret microphone. This microphone also comes with adjustable gain, though in this board it is automatic. This is the device that will be used, for its automatic gain control, availability of online resources/similarity to MAX4466, and its range of noise detection.

The final board is the LM393 comparator. There is insufficient material online for this device, but it is generally accepted as a comparator.


This design change was discussed and approved by Prof Bonarini on 14/6