Difference between revisions of "BOARDLOCK"

From ESE205 Wiki
Jump to navigation Jump to search
Line 206: Line 206:
  
  
GOALS:
+
<big>GOALS: </big>
 
 
  
 
1) Get the Pi and ESC to communicate for Locking Mechanism (handheld remote already controls the motor's speed)
 
1) Get the Pi and ESC to communicate for Locking Mechanism (handheld remote already controls the motor's speed)

Revision as of 23:25, 30 October 2018


Link to Project: [[1]]

Week 1: September 3rd- September 7th

1. Brainstorming project ideas

- Inspired by the convenience of BIRD and LimeBike, we hoped to recreate this idea in a longboard rather than bikes and scooters


2. Decided on BOARDLOCK, envisioning a single-motor mappable electric longboard with manual locking ability (from iPhone)


Week 2: September 10th- September 14th

1. Max: Research/Acquiring materials (1.5 hours)

- Found optimal longboard size (33 inches), brushless motor, ESC, E-Longboard Assembly Kit, 2x Lipo Batteries


2. Sept 13: All 3 of us met with Jim and our TA to finalize BOARDLOCK idea, make a plan (1 hour)

- Got idea approved :), decided to focus on building GPS using Raspberry Pi

- Discarded building an app (not enough knowledge/would take too long)

- Debating how to manually increase/decrease motor speed (remote control vs wire connection?)

- Debating whether to use Bluetooth to detects user's proximity to longboard

- Debating best way to manually lock/unlock wheels (RFID key card?)


3. TA provided us with materials (Night Light, Raspberry Pi) and locker number


Week 3: September 17th - September 21st

1. Amin, Isa, Max: set up Night Light (2 hours)

- Built and tested the circuit on a breadboard, got it to work

- Designed a case for project (dimensions in millimeters: 50 x 24 x 80)

- Holding off on soldering -- need to show TA case design


2. Max and Isa: (unsuccessful) attempt to set up Raspberry Pi (1 hour)


3. Sept 21: Group meeting with Jim and TA (1 hour)

- Discuss progress and next steps

- Decide on budget, have materials approved in order to purchase them

- Set goals for next week


Week 4: September 24th - September 28th

GOALS:

a) Group: Finalize budget/Receive materials

c) Max: Set up Raspberry Pi, get GPS working

d) Amin: 3D print Night Light design

e) Isa: Understand basics of Bluetooth interface, finish Gantt chart/Presentation slides


1. Max:

- Met with Jim, got a new Raspberry Pi, set up to his computer (2 hours)

- Assembled Longboard (30 min)


2. Amin:

-Learned how to use Tinkercad and designed night light box (2 hours)


3. Isa:

- Set up Bluetooth connection to Raspberry Pi (1 hour)

- Finalized Gantt Chart/Presentation slides (30 min)


Week 5: October 1st - October 5th

1. Max and Isa: attempted to email Pi's IP address to ourselves (1 hour)


2. Max, Amin, Isa: successfully soldered components for Night Light onto Perfboard (30 min)


3. Amin: 3D printed Night Light design


Week 6: October 8th - October 12th

GOALS:

- Learn Python

- Power Pi with Lipo Battery, connect to ESC to Brushless Motor

- Program the Pi, test Bluetooth connection

- Attach motor to Longboard

- *Establish a Bluetooth connection from phone to Pi, be able to give commands


1. Isa:

- downloaded, familiarized with Python

- Start building plan to program Pi GPS


Week 7: October 15th - October 19th

GOALS:

- be able to communicate between the Pi and ESC

- secure Bluetooth connection: Can we give the board commands from a phone?

- Draw connections sketch!

- Program Pi using Python


1. Max: made Longboard electric! (in total ~ 24 hours)

2. Isa: lit up LED light on Breadboard using Pi/programmed in Python (1.5 hours)

3. Amin: researched the best way to get GPS coordinates from pi and plot them on a map. Figured out that the best way to do so would be to write from the pi to a usb or sd card, and program a script that plots those coordinates on a map. (1.5 hours)

Sketch
LED
Wire Connections from Pi to ESC

Retrieved from: https://www.instructables.com/id/Driving-an-ESCBrushless-Motor-Using-Raspberry-Pi/

Week 8: October 22nd - October 26th

GOALS:

- Locking mechanism: Figure out how it will work -- is there a way we can power it using Bluetooth?

  • IDEA: Manual Clamp - similar to a boot design for a car


https://www.amazon.com/uxcell%C2%AE-Electric-Positions-Keylock-Switch/dp/B007QAJ2Q0

https://en.wikipedia.org/wiki/Wheel_clamp

https://www.autoanything.com/wheels-rims/what-are-wheel-locks

https://www.amazon.com/IZTOSS-SLIVER-Mini-Bicycle-Brake/dp/B01M22PNF7/ref=sr_1_12_sspa?s=hi&ie=UTF8&qid=1540407785&sr=1-12-spons&keywords=longboard+wheel+lock&psc=1


- Finish assembling Longboard (encase battery)


- Send GPS coordinates from Pi --> USB, write program that used these coordinates to map BOARDLOCK's location


1.) Amin: Made a python script that sends information to usb flash drive from raspberry pi (2 hrs)


2) Max: Designed a case for battery (1 hour)

  • Dimensions:
        130mm*155mm*65mm


3) Isa: sketch design and research logistics for locking clamp (1.5 hr)

https://pinout.xyz/

- Using Pi's GPIO pins: lock/unlock wheels based on Bluetooth connection:

  • Read INPUT pin that the switch is connected to, send OUTPUT to another pin -- powered by Pi
  • If in close proximity of board -- assume strong Bluetooth connection -- switch ON (1) --> high voltage
  • If far from board, assuming Bluetooth is disconnected, switch OFF (0) --> low voltage


Week 9: October 29th - November 2nd

GOALS:

1) Get the Pi and ESC to communicate for Locking Mechanism (handheld remote already controls the motor's speed)

  • HOW? Wiring from the pins on the Pi to those on the ESC
  • Then, run a program in Python that will allow the Pi to control the motor through the ESC — allow it to move forward or not through different outputs of voltage
  • This way, when BOARDLOCK is "Locked" = no voltage being passed to the motor, unable to move


2) Establish Bluetooth Connection with Pi, be able to give commands

  • Bluetooth connection (ON vs OFF) --> Raspberry Pi (GPIO pins) --> ESC (powered by LiPo batteries) --> Motor


3) Get the GPS Chip and the Pi to communicate in order to display/map BOARDLOCK's coordinates in real time

- Manually connecting the chip to the Pi, connecting the Pi to a monitor, passing appropriate commands on Terminal

- Once this works, write a Python script that will parse useful data that we will use to map coordinates.


USEFUL TUTORIALS:

https://learn.adafruit.com/adafruit-ultimate-gps-on-the-raspberry-pi/setting-everything-up

https://www.youtube.com/watch?v=LVRXa8pX0Oc

https://www.piddlerintheroot.com/gps/


  • CHALLENGES TO DISCUSS AT GROUP MEETING ON 10/31:

- Pi is extremely unreliable, connects to some monitors only, others say "No Signal"

- Limited by only having tested the GPS inside (Do we need an open space?)