Difference between revisions of "F14: Collision Avoidance Car"

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(Introduction)
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'''Eduardo Espericueta''' - Lidar Unit Integration<br><br>
 
'''Eduardo Espericueta''' - Lidar Unit Integration<br><br>
 
'''Sanjay Maharaj''' - Motor Integration & System Wiring<br><br>
 
'''Sanjay Maharaj''' - Motor Integration & System Wiring<br><br>
'''George Sebastian''' - Blue-tooth Integration & Lidar<br><br>
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'''George Sebastian''' - Software Infrastructure (tasks / movement logic) & Bluetooth Integration & Lidar<br><br>
  
 
==Introduction==
 
==Introduction==
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==System Integration==
 
==System Integration==
 
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[[image:CMPE146 F14 LidarGroup Hardware.jpg]]
 
==Verification==
 
==Verification==
 
==Technical Challenges==
 
==Technical Challenges==

Revision as of 00:34, 22 December 2014

Collision Avoidance Car

PICTURE HERE

Abstract

The inspiration behind the Collision Avoidance Car project comes from the state-of-the-art field of self-driving cars. All major automotive companies are investing heavily in autonomous car technology. One of the more prominent autonomous cars being developed is the Google Car, which features Lidar and photo-imaging technology to implement autonomy. The goal of the self-driving car is to reduce gridlock, eliminate traffic fatalities, and most importantly, to eliminate the monotony of driving. This project will explore the fundamentals of Lidar, and how this technology is being used for cutting-edge products, such as the Google Car.

Objective & Scope

The project objective was to implement Lidar(laser-based device for measuring distance) technology, coupled with a toy car, to autonomously detect and avoid obstacles. The car operates in two modes: automatic and manual. In the automatic mode, the car maneuvers around autonomously, avoiding obstacles to the front, rear, and sides. Whenever an obstacle is detected, the car maneuvers in the opposite direction, as long as that direction is also free of obstacles. In the manual mode, the car's movements are controlled via a Bluetooth connection. In addition to direction controls, a user is able to adjust the speed of the car and to adjust the distance at which obstacles are avoided.

Team Members & Roles

Eduardo Espericueta - Lidar Unit Integration

Sanjay Maharaj - Motor Integration & System Wiring

George Sebastian - Software Infrastructure (tasks / movement logic) & Bluetooth Integration & Lidar

Introduction

Design Implementation

CMPE146 F14 LidarGroup SoftwareStateMachine2.png

System Integration

CMPE146 F14 LidarGroup Hardware.jpg

Verification

Technical Challenges

Future Enhancements

Conclusion

References