Difference between revisions of "2020FallTeam1"

From MAE/ECE 148 - Introduction to Autonomous Vehicles
Jump to: navigation, search
(Future Suggestions)
(Project Overview)
Line 11: Line 11:
  
 
Initially the goal of our project was to design an autonomous vehicle that would utilize DonkeyAI framework, open CV, and sensors to detect and gather tennis balls in one area to facilitate collecting them after each set. Due to COVID-19, the scope of our project was pivoted to create a ROS package that enables the RoboCar to use images taken through its external camera to be processed through a mask and proportional-integral-derivative tuning  
 
Initially the goal of our project was to design an autonomous vehicle that would utilize DonkeyAI framework, open CV, and sensors to detect and gather tennis balls in one area to facilitate collecting them after each set. Due to COVID-19, the scope of our project was pivoted to create a ROS package that enables the RoboCar to use images taken through its external camera to be processed through a mask and proportional-integral-derivative tuning  
in order to read the yellow lines on the racetrack and drive autonomously.
+
in order to read the yellow lines on the external track and drive autonomously.
  
 
== Hardware ==
 
== Hardware ==

Revision as of 21:46, 16 December 2020

Team Members

Electrical Engineers
Benjamin Crawford
Heather Huntley
Joshua Orozco
Mechanical Engineers
Peggy Tran

Project Overview

Initially the goal of our project was to design an autonomous vehicle that would utilize DonkeyAI framework, open CV, and sensors to detect and gather tennis balls in one area to facilitate collecting them after each set. Due to COVID-19, the scope of our project was pivoted to create a ROS package that enables the RoboCar to use images taken through its external camera to be processed through a mask and proportional-integral-derivative tuning in order to read the yellow lines on the external track and drive autonomously.

Hardware

Mechanical Design

Camera Mount

Cam mount one.JPG

Base Plate

Team one base plate.JPG

This base plate was printed on .25 inch acrylic and was used to hold all electrical components of the RoboCar.

Electronic Components

Jetson Nano Developer Kit
Adafruit PCA9685
16bit PWM controller
USB webcam
High power LEDs
11.1V 3S LiPo battery
Battery voltage sensor
433MHz remote relay
12V-5V DC-DC voltage converter

The car our team used is built around a Traxxas Ford Fiesta chassis containing a DC motor, electronic speed controller and servo motor. The following diagram shows how all of the electronics are wired.

Electronic Wiring Schematic

ECE148 Wiring.png

Software

We set up a GitHub repository where the code used by the vehicle is stored. The repository contains an ROS package which is designed to be used with our car. The following diagram displays the overall structure of the out ROS package, Autonomous_ROS_Racer.

ROS graphic.png

Milestones

DonkeyCar

Using the donkeycar framework and the UCSD GPU cluster to speed up the behavioral modeling process we were able to do five autonomous laps on an outdoor track. As you can see in the video below:
Template:Video goes here

ROS Package

With the ROS package that we developed we completed five laps (with a little help) on the track in the Warren tents. Here is a video of that:
Template:Video goes here

Future Suggestions

For software focused members, it's important to brush up on any python skills during the former half of the quarter to prepare for the latter half when you are coding your own RoboCar. For hardware focused members, they should brush up on relevant tolerance standards in order to minimize the amount of material they use when designing the baseplate and cam mount. For all members, they should retain as much as they can on ROS ignite and collaborate on the topics/concepts in order to consolidate their knowledge.

Acknowledgements

We would like to thank Professors Jack Silberman and Mauricio de Oliveira for their help throughout the quarter and consistent work in keeping the course engaging and relevant throughout the difficulties imposed by the COVID pandemic. We would also like to recognize the hard work put in by the TA's Haoru and Leeor.

References