Headband Helper

From ESE205 Wiki
Jump to navigation Jump to search

Links

Headband_Helper_Log

Presentation [1]

GitHub Repository [2]

Accelerometer code [3]

Project Proposal

Overview

We hope to construct an accelerometer-based concussion monitoring system using a Raspberry Pi OW that can be contained within a headband. In addition, we will create a web interface that allows users to track their impact history. These two pieces (software and hardware) will communicate using an ad hoc IP network run by another Raspberry Pi.

Team Members

  • Jarrod Huther
  • Katy Mockett
  • TA: Ethan Shry
  • Professor: James Feher

Objectives

  • Create an accelerometer-based concussion monitoring system that can be contained within a headband
  • Create an ad hoc IP network using a master Raspberry Pi to collect data from the headbands
  • Ensure that the master Pi and web interface can successfully communicate so the web interface can display collected data about collisions

Challenges

  • We both have limited experience with circuitry
  • We both are comfortable working in Java but have never really used any languages beyond Java
  • No experience with sensor networks; creating a fully debugged network will be difficult

Budget

  • 2 accelerometers ($11.95 each, $23.90 total)[4]
    • Shipping (~$8.00)
  • 1 Amp battery & charger ($24.95)[5]
  • Raspberry Pi 0W- headband (free)
  • Raspberry Pi- master (free)
  • 3D box to contain tracking materials within headband (free)

Total Budget: $56.85

Gantt Chart

Gantt Chart

Design and Solutions

Module 1: Wiring Accelerometer to Pi 0

Module 1 of our project involves wiring the H3LIS331DL accelerometer to the Raspberry Pi 0, as well as implementing the code in python that executes the readings. This specific accelerometer is 3-axis, meaning it records data in the x, y, and z-planes, and can take readings up to +-400g's. We chose this board specifically because concussions occur at approximately 95g's, so we needed a sensor that was capable of sensing events of this magnitude and beyond. Once the sensor was wired to the pi, we had to code the pi to use the sensor, as well as transmit the data to the master pi, in order to read the data on another interface.

  • Step 1: Solder header pins onto both the accelerometer and the pi (if not already attached).
Accelerometer with Pins
Pi with Pins
  • Step 2: Wire the Pi to the accelerometer as shown in the following diagram. IMPORTANT: The shape of the accelerometer is slightly different, but the pins still go to the corresponding ports (e.g., GROUND will still to GPIO pin 9). Additionally, instead of VCC, connect to the 3.3v port on the accelerometer. Also ignore the LED, we will not be implementing it in our final product.
  • Wiring pi acc.jpeg
  • Full Wired System
  • Step 3: Code on Pi. Open up the Pi (either SSH or on a monitor) and use this link [6] to import code. Once a file with the code has been made, change the maxScale variable to 400, as well as every instance of 6, 12, and 24 to 100, 200, 400 (respectively). For example, if you see RANGE_6G = 0x00, change it to RANGE_100G = 0x00, and so on. Finally, ((((((TO-DO))))))(function to send data to server)
  • Step 4: Build case for pi-accelerometer system (((((TO-DO)))))))
  • Step 5: Place in headband (((((TO-DO)))))

Module 2: Build Ad Hoc Network

  • API Routes, Sending/receiving data, etc.

Module 3: Gather and Interpret Data

  • Once data is in the server, read results and draw conclusions

Results

Next Steps