Project Title
<Nimble>
Abstract
<2-3 sentence abstract>
Introduction
The project was divided into N modules:
- Sensor ...
- Motor..
- ...
- Android
Team Members & Responsibilities
<Team Picture>
Gitlab Project Link - [1]
<Provide ECU names and members responsible>
- Tanmay Chandavarkar <Master, Sensors>
- Yuming Cheng < Master, GPS, Motor >
- Ellis Makwana <Master, Sensors>
- Naeem Mannan <Master, Mobile Application, To be determined>
- Francesco Vescio <To be determined>
- Lawrence Wan <Master, GPS, Motor, Sensors>
- Sensor
- Link to Gitlab user1
- Link to Gitlab user2
- Motor
- Link to Gitlab user1
- Link to Gitlab user2
- Geographical
- Link to Gitlab user1
- Link to Gitlab user2
- Communication Bridge Controller & LCD
- Link to Gitlab user1
- Link to Gitlab user2
- Android Application
- Link to Gitlab user1
- Link to Gitlab user2
- Testing Team
- Link to Gitlab user1
- Link to Gitlab user2
Team Deliverables Schedule
| WEEK
|
START DATE
|
END DATE
|
TASK DETAILS
|
STATUS
|
| 1 |
Feb 2020 |
4 March 2020 |
- Create and establish GitLab repository
- Establish slack channel and invite Preet
- Look through previous years projects and study it
- Distribute major roles among team members
|
Completed
Completed
Completed
Completed
|
| 2 |
05 March 2020 |
12 March 2020 |
- Create a Bill of Materials.
- Select and order an RC car.
- Make Repo on Gitlab for all modules - Follow Naming Convention.
|
In Progress
Completed
In Progress
|
| 3 |
13 March 2020 |
19 March 2020 |
- Select Part Number for Sensors (Tanmay, Ellis)
- Designing and deciding PCB tool(Lawrence)
- Finalizing GPS module by doing some research (Yuming)
- Finalize and order LCD ()
- Finalize Motor and Order it (Lawrence , Yuming )
- Environmental setup of Android ( )
|
In Progress
Not Started Yet
Completed
In Progress
In Progress
In Progress
|
| 4 |
20 March 2020 |
26 March 2020 |
- Understand DBC and implement the DBC file compatible with all the controllers.
- Test motor driving in different situations, begin to listen to CAN for controls.
- Establish communication across all the CAN controllers over CAN bus based on the DBC file.
- Verify the power-up interactions and configurations between Master and the other controllers.
- 03/26/2020 DBC File
- 03/26/2020 DEMO: CAN communication between controllers.
|
In Progress
Not Started Yet
Not Started Yet
Not Started Yet
Not Started Yet
Not Started Yet
|
| 5 |
27 March 2019 |
09 April 2019 |
- // Temporary schedule below
- Check and Resolve power issue for RC Car.
- Finalize high-level system block diagram and control scheme.
- Circuit Simulation in Diptrace Tool.
- PCB Layout Design in Diptrace Tool.
- Finalize Components placement on PCB.
- Establish a connection over Bluetooth and Android app.
- Establish a communication between Bluetooth devices.
- Interfacing of ultrasonic sensors to the SJOne board and check for basic functionality.
- Interface and get the reading of Lidar sensor with SJOne over UART.
- Chalk out the Message IDs based on the priority of the messages and the data to be sent across nodes.
- Interface of Servo & DC motor to the SJOne board and check for basic functionality.
- Interface Compass module with SJOne board using I2C serial bus.
- Interface bluetooth HC-05 module with SJOne board using serial Communication.
- Configure bluetooth HC-05 module name as Tech Savy using HC-05 Communication Mode.
- Explore UI designing of LCD.
- Finish motor controller API. Test motor driving in different situations, begin to listen to CAN for controls.
- Add a TextView for displaying the Bluetooth connection status in Android App.
|
Not Started Yet
Not Started Yet
Not Started Yet
Not Started Yet
Not Started Yet
Not Started Yet
Not Started Yet
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Not Started Yet
Not Started Yet
Not Started Yet
Not Started Yet
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Not Started Yet
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Not Started Yet
Not Started Yet
|
| 6 |
10 April 2020 |
16 April 2020 |
- Parse data of Lidar Sensor depending on distance and angle and send it to master using dbc.
- Implement basic obstacle avoidance algorithm based on sensor data and test the same.
- Continue testing motor driver via commands from CAN bus.
- Build in speed steps to reverse motor for reverse to work correctly.
- Mount all the sensors and test for any dead band and modify their positions for maximum coverage.
- Integrate the fusion of LIDAR and Ultrasound sensor to get overall feedback from all the directions.
- Develop algorithm to avoid obstacles and plan the car's further navigation path.
- Complete final prototype of the obstacle avoidance feature.
- Calibrate Compass Module. Develop code for Compass module communication over CAN.
- 16 April 2019 DEMO: Motors driven by wheel feedback and sensors, Basic obstacle avoidance.
- Final Wiki Schedule.
|
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
|
| 7 |
17 April 2020 |
23 April 2020 |
- Configure GPS device baud rate and interface it with SJOne board using UART.
- Send and receive current location, destination and checkpoint coordinates to and from App and Geo module via BRIDGE.
- Calibrate sensors readings and work on filtering algorithm with Master & Sensor
- Begin work on LCD to show vehicle live status(speed, fuel-status, obstacles, distance to destination etc.) in a GUI.
- Finish implementing speed control on motor (to make sure requested speed is met based on RPM read).
- Work on Car reversing using Motor Controllers.
- Integrate all modules with the Master to test the data flow.
- Validation & Verification of obstacle avoidance, steering logic with rear sensor inputs and reversing.
- Start incorporating GEO Controller information to Master module Steering logic.
- Decide, implement and test data exchange between Geo Controller and BRIDGE.
- Calculate and send simple bearing angle and destination status on CAN to figure out initial challenges.
- Add a Google Map for setting the car's destination.
- Send car location to app and check points received to Geo module.
- Verify the stringent requirement of Start-up Sync, Periodic heart-beat messages.
- Update Wiki Schedule with Test Reports.
|
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
In Progress
Completed
Completed
|
| 8 |
24 April 2020 |
30 April 2020 |
- Testing & Validation of the LCD UI and display run time vehicle status and looking forward for feedback from team if any.
- Improve & Validate Navigation logic with multiple checkpoints, bearing angle and destination information.
- Identify and mitigate GPS locking, Location Accuracy and Number of Satellite-In-View coming.
- Validate Accuracy of Compass Calibration with iPhone Compass.
- Determine and add DBC Changes and finalized.
- Implement the steering logic with bearing angle and status provided by GEO-Module.
- Consistently Communicate current car location to App, get check points from App and relay them to Geo module.
- Send additional vehicle status information from can bus to the App for display.
- Send the request to Google for getting the checkpoints(use the Google Maps Directions API).
- Field test and check for obvious issues in obstacle avoidance, navigation, maintaining speed (up/down hill).
- Provide feed backs to each team on identified short comings.
- Update Wiki with new details and information.
- DEMO: GPS driving
|
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
Completed
|
| 9 |
1 May 2020 |
7 May 2020 |
- FIELD TESTING - CRITICAL WEEK
- Implement turning indicators, break lights and head light.
- Check for Corner cases for steering logic under various conditions and locations.
- Analyse field test results for GPS and CMPS and work on it if required.
- Test the accuracy of check-points from the Blue-tooth controller, location data from the Geo-controller sensor and Navigation Algorithm.
- Check overall robustness of the complete system.
- Establish complete connection on PCB
- Update wiki with details.
|
Completed
Completed
Completed
Completed
Completed
Completed
Completed
|
| 10 |
8 May 2020 |
21 May 2020 |
- All hands on testing and final bug fixes.
- Check for tuning or calibration of modules if required.
- Complete end-to-end testing for various scenarios and conditions.
- Create the semester long project activity video and upload to YouTube.
- Update and finalize wiki.
|
Completed
Completed
Completed
Completed
Completed
|
| 11 |
22 May 2020 |
|
- DEMO: Final Project
- SUBMISSION: Final Project Wiki
|
Completed
Completed
|
Parts List & Cost
| Item#
|
Part Desciption
|
Vendor
|
Qty
|
Cost
|
| 1
|
RC Car
|
Traxxas
|
1
|
$250.00
|
| 2
|
CAN Transceivers MCP2551-I/P
|
Microchip [2]
|
8
|
Free Samples
|
Printed Circuit Board
<Picture and information, including links to your PCB>
CAN Communication
<Talk about your message IDs or communication strategy, such as periodic transmission, MIA management etc.>
Hardware Design
<Show your CAN bus hardware design>
DBC File
<Gitlab link to your DBC file>
<You can optionally use an inline image>
Sensor ECU
<Picture and link to Gitlab>
Hardware Design
Software Design
<List the code modules that are being called periodically.>
Technical Challenges
< List of problems and their detailed resolutions>
Motor ECU
<Picture and link to Gitlab>
Hardware Design
Software Design
<List the code modules that are being called periodically.>
Technical Challenges
< List of problems and their detailed resolutions>
Geographical Controller
<Picture and link to Gitlab>
Hardware Design
Software Design
<List the code modules that are being called periodically.>
Technical Challenges
< List of problems and their detailed resolutions>
Communication Bridge Controller & LCD
<Picture and link to Gitlab>
Hardware Design
Software Design
<List the code modules that are being called periodically.>
Technical Challenges
< List of problems and their detailed resolutions>
Master Module
<Picture and link to Gitlab>
Hardware Design
Software Design
<List the code modules that are being called periodically.>
Technical Challenges
< List of problems and their detailed resolutions>
Mobile Application
<Picture and link to Gitlab>
Hardware Design
Software Design
<List the code modules that are being called periodically.>
Technical Challenges
< List of problems and their detailed resolutions>
Conclusion
<Organized summary of the project>
<What did you learn?>
Project Video
Project Source Code
Advise for Future Students
<Bullet points and discussion>
Acknowledgement
References
