Autonomous Metal Detector Vehicle (AMDV) Jared Speer Lamar Williams Jr. Nathan Stephan University of Central Oklahoma Department of Engineering and Physics.

Slides:

Advertisements

Similar presentations

1. Instrument Clusters Theory Support Automotive – Displays & Accessories 1 of 13 Instrument Clusters Topics covered in this presentation: Analog Instrument.

Advertisements

Auto Parallel Parking Car. We created a Car that can identify a parking space and parallel park by itself. The Car drives down a street searching for.

Programming Logic Controllers

Autonomous Sensor and Control Platform Rover Tae Lee Josh Reitsema Scott Zhong Mike Chao Mark Winter.

Team Spot Cooperative Light Finding Robots A Robotics Academy Project Louise Flannery, Laurel Hesch, Emily Mower, and Adeline Sutphen Under the direction.

SOUTHEASTCON I KARMA ECE IEEE SoutheastCon Hardware Competition Must build an autonomous robot that can –Start at rest at the Starting Station.

Gesture Controlled Car (GCC) By: Ashwaq Alkailany Reema Abubaker Supervised by: Dr. Luia Malhis.

PHY 235 Robotics Workshop Day 6 DC Motors, H-Bridge Board, Simple Lego/Boe Bot.

1 PACE LITES PRESENTATION Advisor: Professor Sahakian Andrew Dai Lenore Kaplan Benjamin Mattson Nikhil Sethi.

Autonomous Metal Detector Vehicle (AMDV)

Wireless Controller Steven Mays Faculty Advisor: Frank Hludik Start Date: 10/27/09 End Date: May 2010.

Wireless Ethernet AT-Rover Group 1 Beau Cook, Barry Greenwood, Danny Martin, Matt Patella, Ian Petrie.

October 21, 2003 ECE Senior Design1 Autonomous GPS-BOT Preliminary Design Review by Kery Hardwick, Yevgeniy Khasanov, Naoya Kinuta, Zhe Chuan Luo.

Team BAKE Bryan Schoen Ashish Bablani Kelby Penney Evan Schurr

Field Navigational GPS Robot Final Presentation & Review Chris Foley, Kris Horn, Richard Neil Pittman, Michael Willis.

KTD Micromouse Overview Team Goals Approach Outstanding Problems Future Solutions Final Status.

The Enforcer Laura Celentano Glenn Ramsey Michael Szalkowski.

Autonomous Dual Navigation System Vehicle Dmitriy Bekker Sergei Kunsevich Computer Engineering Rochester Institute of Technology December 1, 2005 Advisor:

Senior Design Project Fall, 2007 Michael Garrity, Peter Nahas, Cory Haflett Objective: The Autonomous Mail Deliver System (AMDS) was designed for use in.

Deon Blaauw Modular Robot Design University of Stellenbosch Department of Electric and Electronic Engineering.

R3R3 Ethan Hall Michael Kelton Greg Wegman Vashisht Lakhmani.

Introduction to Robotics Electronics and Robotics Club.

Module 2: Hardware and Terminology

Design and Implementation of Metallic Waste Collection Robot

Power Generation for the Better Water Maker: Subsystems Design Review October 29, 2013.

Introduction to Robotics Principles of Robotics. What is a robot? The word robot comes from the Czech word for forced labor, or serf. It was introduced.

Design Design Circuit diagrams were created by researching effective circuits from various sources. Multisim virtual circuit modeling software was used.

OPTICAL FLOW The optical flow is a measure of the change in an image from one frame to the next. It is displayed using a vector field where each vector.

Sensors Material taken from Robotics with the Boe-Bot.

Concept Design Review THE DUKES OF HAZARD CAMILLE LEGAULT, NEIL KENNEDY, OMAR ROJAS, FERNANDO QUIJANO, AND JIMMY BUFFI April 24, 2008.

Microcontroller Hands-on Workshop #3 Ahmad Manshad New Mexico State University Institute of Electrical and Electronics Engineers November 7, 2009.

May Team Information Client Department of Electrical and Computer Engineering, Iowa State University Faculty Advisor Professor Gary Tuttle Team Members.

PING))) Ultrasonic Distance Sensor living with the lab ultrasonic pressure waves from PING))) speaker The PING))) sensor emits short bursts of sound and.

Why do robots need to move?

Ruslan Masinjila Aida Militaru.  Nature of the Problem  Our Solution: The Roaming Security Robot  Functionalities  General System View  System Design.

MICRO CONTROLLER MODULE 1. Learning Objectives Name some gadgets that use microcontrollers. Define a microcontroller. Differentiate between a computer.

The SFA Rover Team Project. The SFA Rover  Must be demonstrated at the beginning of the last lab of the semester, Dec 11 th.  Teams can work on this.

Team 4 Shane Sunada – Project Leader Malcolm Menor – Project Manager Nathan Umeda – Technical Supervisor Joseph Longhi – Documentation Final Presentation.

Smart Plant Robot Prepared by Haya De’bas Jumanah Salhab Supervisor Dr. Ra’ed Al-Qadi.

DETACHABLE POTHOLE DETECTION AND WARNING SYSTEM

By: 1- Aws Al-Nabulsi 2- Ibrahim Wahbeh 3- Odai Abdallah Supervised by: Dr. Kamel Saleh.

Multi-Vehicles Formation Control Exploring a Scalar Field Polytechnic University Department of Mechanical, Aerospace, and Manufacturing Engineering Polytechnic.

Wall Climber Project Kevin Kauffman Eric Hall. Objectives Remotely control the climber, with visual feedback Remote driving Camera functionality Feedback.

Phong Le (EE) Josh Haley (CPE) Brandon Reeves (EE) Jerard Jose (EE)

ECE 477 Final Presentation Team 14  Spring 2013 Paste a photo of team members with completed project here. Annotate this photo with names of team members.

Team: CHEE WHOOO Spring 08. The Team Mitchell La Puente-Project Leader Josh Miyamoto-Software Richard Ordonez-Hardware.

Daredevil Robot Direction Module (DRDM) Senior Design II Midterm Presentation.

Basic Stamp OEM module By Wilmer Arellano. 2  The BASIC Stamp 2 OEM is a discreet component version of the BS2 which may be purchased in kit form. 

ECE 477 FINAL PRESENTATION TEAM 6  SPRING OUTLINE  Project overview  Block diagram  Design challenges  Individual contributions  Project demonstration.

Robot Project by Ahmad Shtaiyat Supervised by Dr. Salem Al-Agtash.

Group Members: Dan Brownlee Sean Harriman Andrew Robison James Evans Joshua Doores.

BLDC Motor Speed Control with RPM Display. Introduction BLDC Motor Speed Control with RPM Display  The main objective of this.

 Many people use pedometers when they walk or run  These shoes would have pedometers built in that calculate steps, distances, and calories burned 

INTRODUCTION TO ROBOTICS Part 3: Propulsion System Robotics and Automation Copyright © Texas Education Agency, All rights reserved. 1.

Forward Until Near Stop when near a wall.

Introduction to VEX® components

ADVANCED WATER LEVEL CONTROLLER

The entire system was tested in a small swimming pool. The fully constructed submarine is shown in Fig. 14. The only hardware that was not on the submarine.

Instrument Clusters Topics covered in this presentation:

ECE 477 Design Review Team 13  Spring 2007

Dynamic Ferrofluid Lamp Team 59

CSU-Pueblo Team: Paul Rael, Shae Anderson, Atilla Turkoz, Yudhi Paudel

WALL DETECTOR ROBOT VEHICLE

DC MOTOR SPEED CONTROL 1. Introduction

Presenter: Peachanok Lertkajornkitti

Presentation of Robotics (3)

Bluetooth operated Arduino Controlled Car

Karl Jean-Francois-James Madison H.S. & Eldiquen Mangubat-IS 232

AN INEXPENSIVE ROBOTIC KIT FOR CHILDREN EDUCATION

Presentation transcript:

Autonomous Metal Detector Vehicle (AMDV) Jared Speer Lamar Williams Jr. Nathan Stephan University of Central Oklahoma Department of Engineering and Physics Fall 2011

Design Outline Brainstorm Research Feasibility assessment Conceptualization Establishing the design requirements Preliminary design Detailed design Production planning and tool design Production

Brainstorm As an team deciding the actual project was an project of itself Other ideas included: – War Robot – Remote controlled car – Underwater boat (Submarine) – LCD display – Autonomous Metal Detector

Brainstorm As a team we decided that the AMDV sounded the most interesting and rewarding project, but it also sounded the most intimidating project To verify the project was feasible, we had to conduct research

Design Outline Brainstorm Research Feasibility assessment Conceptualization Establishing the design requirements Preliminary design Detailed design Production planning and tool design Production

Research We performed research on an myraid of different aspects of the AMDV Aspects of the AMDV included – Hall Effect sensor – Parallax PING Ultrasonic Sensor – Vehicle Body Chassis Body Suspension – Microcontroller Basic Stamp 2sx – Sensor Parallax Ultrasonic Ping Sensor Metal Detector – Design of the Sensor – Understanding of Sensor – Programming Synching all of the different aspects of the AMDV to work coherently

Design Outline Brainstorm Research Feasibility assessment Conceptualization Establishing the design requirements Preliminary design Final design Cost

Feasibility assessment After research, we deduced that this will be a challenging but achievable project Since the AMDV idea was seemed so interesting, we decided that pursuing this project would be the best route to take.

Design Outline Brainstorm Research Feasibility assessment Conceptualization Establishing the design requirements Preliminary design Detailed design Production planning and tool design Production

Conceptualization (Preliminary Design)

Schematic of the *final* preliminary design If we proceed in this design, it would not be autonomous

Conceptualization That design was our final design that was in line with our feasibility requirement. We needed to make sure that it met the design requirements of the professor outlined in his project requirement list.

Design Outline Brainstorm Research Feasibility assessment Conceptualization Establishing the design requirements Preliminary design Detailed design Production planning and tool design Production

Establishing the design requirements Dr. Baha and Mr. Richard gave us specific requirements for us to abide by We covered all of the requirements given in the Term Project Guidelines as shown in a list in the following slide

Establishing the design requirements Output Display – Parallax Serial LCD Audio Output Device – Speaker with 5ohm 4watt specs Manual Data Input – On/ Off Switch – Timer to shutdown once metal is detected, automatically switches off Automatic Sensor Input – Parallax PING Ultrasonic sensor – Metal detecting sensor Actuators, Mechanisms, and Hardware – DC motor – Stepper motor – Suspension System – RC servo motor Logic, Processing, and Control – Basic Stamp 2SX – Programmed Logic

Design Outline Brainstorm Research Feasibility assessment Conceptualization Establishing the design requirements Preliminary design Detailed design Production planning and tool design Production

Preliminary design If we proceed in this design, it would not be autonomous

Preliminary design Due to time constraints, we realized that building a chassis, suspension system for various terrain, and space for the circuits we had to outsource the body We reversed engineered a RC car from New Bright.

Preliminary design By using this car, we already had the suspension, chassis and space for all of our circuits.

Preliminary Design (Metal Detector) The original design that we used was going to be the use of the hall effect sensors Even though we thought that it would be an feasible venture, it would not be feasible with the time constraint

Preliminary Design (Metal Detector) The design that we decided to use was the much simpler BFO (beat frequency operation) This design had to be modified to fit our specific parts.

Preliminary Design (Testing and Debugging)

Our team actually burned the motor driver L293D due to insufficient knowledge of how much voltage was needed to go in.

Preliminary Design (Testing and Debugging) So we built an voltage regulator. This was the schematic of the voltage regulator. It regulates the voltage that goes into the motor driver (L293D).

Preliminary Design (Testing and Debugging) Our team was obtaining inconsistent readings from our metal detector. We realized that our speaker was very close to the circuitry and metal detector.

Preliminary Design (Testing and Debugging) Since the magnet within the speaker produces an magnetic field, it was causing interference in the reading we obtained. We rectified this problem by moving the speaker away from the circuitry.

Preliminary Design (Components) We used the Parallax Servo Motor to steer the AMDV either left or right The Parallax sensor worked great in this project

Preliminary Design (Components) We used the Parallax Ultrasonic Distance sensor for the AMDV to avoid collisions It used short ultrasonic burst to and provides an output pulse that corresponds to the time required for the burst echo to return to the sensor By measuring the echo pulse width, the distance to target can easily be calculated

Preliminary Design (Components) This is the DC motor that provides the rear wheel drive acceleration to the motor We switched motors due to the first motor we used was malfunctioning

Preliminary Design (Components) We went through the trouble of trying to figure out exactly the best coil possible. 24 gauge copper wire and wrapped it 70 times with an inner diameter with an inductance 1.25 mH.

Preliminary Design (Components) The LCD is integrated into the AMDV to communicate to the user what it sees. It tells you the intensity of the magnetic field and to reset it to find metal.

Design Outline Brainstorm Research Feasibility assessment Conceptualization Establishing the design requirements Preliminary design Final design Cost

Final Design (Pictures)

Final Design (Schematic)

Final Design (Pictures)

Estimated Cost Output Display – Parallax Serial LCD = $ 40 Audio Output Device – Speaker with 5ohm 4watt specs = $25 Manual Data Input – On/ Off Switch = $2 Automatic Sensor Input – Parallax PING Ultrasonic sensor = $20 – Metal detecting sensor = $20 Actuators, Mechanisms, and Hardware – DC motor = $20 – Suspension System = Donation – RC servo motor = $40 Logic, Processing, and Control – Basic Stamp 2SX = $60 Total Cost = $