S15: Vision RC Car

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Revision as of 22:38, 23 May 2015 by Proj user3 (talk | contribs) (Software Design)

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Grading Criteria

  • How well is Software & Hardware Design described?
  • How well can this report be used to reproduce this project?
  • Code Quality
  • Overall Report Quality:
    • Software Block Diagrams
    • Hardware Block Diagrams
      Schematic Quality
    • Quality of technical challenges and solutions adopted.

Vision RC Car

Abstract

The Vision RC Car will provide a video feed and controls to a user through a web-based GUI, with the goal of being able to roam wherever a network may be available.

The goal of the Vision RC Car is to be able to roam wherever a WiFi network is present. A user will utilize a web-based GUI to view a video-feed from the platform, and in turn control the vehicle from the GUI.

Objectives & Introduction

The Vision RC Car, here on out known as the system, was initially designed to spy on people. A user will have the ability to access a video-feed from the system, in addition to the ability to control the speed and direction of the system through the web-based GUI. It was determined that in addition to any nefarious activities that could be conducted with the system, a user could also utilize the system to make deliveries of small packages, to explore spaces inaccessible to humans, and for hobbyist purposes.

The system is composed of a gutted RC car, a dual-bridge motor controller, the SJSU One microcontroller, the Intel Edison microcontroller, and a webcam. At the center of the system is the Edison, which runs a lightweight Linux distro known as Yocto. The Edison is WiFi capable and will serve as the system bridge to wireless networks. The Edison will run a Node.js server that will host the system GUI. The webcam is interfaced with the Edison, and the video-feed is presented on the GUI. The system will utilize JavaScript to read commands from the user, and redirect the commands received to the SJSU One.

The SJSU One and Edison communicate through UART at a baud rate of 115200. The SJSU One will control the speed and direction of the system by interfacing with the dual-bridge motor-controller, which in turn drives the two-motors of the system. One of the motors is responsible for forward and backward movements, while the other motor is responsible for steering.

Team Members & Responsibilities

  • Team Member 1
    • Jonathon Hongpananon - Web Server
  • Team Member 2
    • Eduardo Espericueta - Motor Control
  • Team Member 3
    • Shangming Wang - IP Camera Support

Schedule

Show a simple table or figures that show your scheduled as planned before you started working on the project. Then in another table column, write down the actual schedule so that readers can see the planned vs. actual goals. The point of the schedule is for readers to assess how to pace themselves if they are doing a similar project.

Week# Start Date End Date Task Status Actual Completion Date
1 4/14/2015 4/20/2015 Ed: Attach prototyping board to the RC car. Interface the SJSU One and the motor controller. Test the motor tasks, and verify that steering and drive work as expected.

Jon: Research setting up server on Edison. Flash OS onto the Intel Edison. Solder header pins onto the Edison mini breakout board.

Eric: Research streaming camera feed. Create system layout diagram.

Complete - Motors respond to 'a', 'w', 's', & 'd' terminal commands. Front wheels turn left and right. 4/20/15
2 4/21/2015 4/27/2015 Ed: Modify the Edison’s web page to form a first draft of what UI will look like. Write JavaScript for UI that will detect a user’s keyboard input.

Jon: Setup node.js server from Edison. Attempt first draft webserver implementation.

Eric: Setup streaming camera feed to browser - Part 1

Complete - Node.js server is setup and tested. Javascript page is able to echo key commands to console. 4/27/15
3 4/28/2015 5/4/2015 Ed: Integrate the Edison and the SJSU One. Write code to transfer command input from UI to the SJSU One.

Jon: Continuation of node.js server. Expand UI aesthetics and functionality.

Eric: Setup streaming camera feed to browser - Part 2

Complete 5/19/15
4 5/5/2015 5/11/2015 Ed: Integration on RC car platform, more specifically wiring layout, color, and verification of connections.

Jon: Integration on RC car platform (power supply)

Eric: Integration on RC car platform (mounting)

Complete 5/21/15
5 5/12/2015 5/18/2015 Ed: Test motor controls from web GUI.

Jon: Test accessibility and physical range.

Eric: Test webcam at distance.

Ongoing N/A
6 5/19/2015 5/22/2015 Ed: Finish details. Work on Wiki.

Jon: Finish details. Work on Wiki.

Eric: Finish details. Work on Wiki

Ongoing N/A

Parts List & Cost

Qty Description Manufacturer Part Number Total Cost
100 Jumper Wires $6.99
1 DC Stepper Motor $6.43
40 Male to Female Jumper Wires $4.99
10 PCB Board Pin Headers $5.74
200 Cable Ties Turnigy $6.31
10 PCB Female Pin Headers $5.29
1 Remote Control Car $59.99
1 SJOne Board $80.00
1 Intel Edison Intel $60.00
Total Cost (excluding shipping and taxes) $235.74

Design & Implementation

Hardware Design

The hardware consists of several different types of hardware devices. The Vision RC car uses a 12V battery pack to power both the SJSU One board, the motor controller, and the Intel Edison. The 12V battery pack is connected to a power circuit which uses a LM7805 5 Volt regulator to control the voltage supply to the devices. The SJSU One board communicates to the dual-bridge motor controller using pulse width modulation (PWM) signals. The signals are decoded by the motor controller, which in turn controls the spinning rate of the motors. The web cam is connected to the Intel Edison and transfers the user input commands to the SJSU One board.

S15 244 G8 newHW.jpg

Hardware Interface

S15 244 G8 pwm.gif

UART - Client Side commands from the web-browser are sent to the server-side of the Intel Edison. The server on the Intel Edison outputs serial commands through the UART bus to the SJSU One board.

Pulse Width Modulation (PWM) - The SJSU One board outputs 1ms to 2ms wide pulse signals to the motor controller. The motor controller controls the speed of the motors based upon the duty cycle of the signals. The duty cycles are from 0% to 100%.

Software Design

S15 244 G8 softwaredesign1.jpg

The primary component used in this project is the Intel Edison, since it acts as the web server which the user can connect to via web browser and internet. The Edison is highly connected and enabled with built-in Wifi and network capabilities. The Edison runs a web server and contains an html page which can be accessed locally. The contents of the html page utilizes NoseJS and javascript based framework. The NodeJS creates the html page, sends it over the network, and the user browser connected displays the result. The client and server communication requires a communication protocol so we opted for socket.io to direct the keyboard commands from the client browser to the Edison server. The Edison interfaced with the SJSU One board sends the resulting commands to control the speed of the motors. The end result is an IoT (Internet of Things) connected device on a network that can be controlled remotely.

Implementation

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Server Communication

  1. Start up web server to display html page
  2. Activate yaler for user to connect to specific URL.
  3. Listen for 'w', 'a', 's', & 'd' letters using javascript and socket.io.
  4. Output resulting command to UART of SJSU One.

SJSU One Board Initialization

  1. Start tasks, set priority levels, and initialize task scheduler.
  2. Initialize UART driver.
  3. Listen for 'w', 'a', 's', & 'd' commands from UART.
  4. Set PWM output for motor controller from specific commands.

Testing & Technical Challenges

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My Issue #1

Discuss the issue and resolution.

Conclusion

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Project Video

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Project Source Code

References

Acknowledgement

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References Used

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Appendix

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