From the series: MATLAB and Simulink Robotics Arena
Sergio Biagioni, MathWorks
Learn how to perform Buoy Detection using Simulink® in this episode of the MATLAB® and Simulink Video Series for Unmanned Vehicle Systems.
Buoy Detection is used, for example, to design robust computer vision algorithms. As a result, although Buoy Detection is a task found in the RoboBoat, RoboSub, and RobotX competitions, this content is applicable to all AUVSI Foundation competitions.
This video includes demonstrations and explanations to show you how to:
*This video shows how to use a custom app found on File Exchange. As of R2014a, there is a built-in app called the Color Thresholder app which you can use instead.
Download the code used in this video, along with a helpful guide to get started, from File Exchange.
Introduction to Robotic Systems Meet MATLAB and Simulink Robotics Arena team members, Sebastian Castro and Connell D’Souza, as they discuss designing a robotic system and the support provided to robotics student competition teams.
Introduction to Contact Modeling, Part 1 Sebastian Castro and Ed Marquez Brunal introduce the fundamentals of mechanical contact modeling and simulation with Simulink, as well as show examples for automotive and robotics applications.
Introduction to Contact Modeling, Part 2 Sebastian Castro and Ed Marquez Brunal discuss various approaches and online resources for modeling mechanical contact and friction forces using Simulink, Simscape, and Simscape Multibody.
Direction of Arrival with MATLAB Stephen Cronin from the Robotics Association at Embry-Riddle Aeronautical University demonstrates how to detect the direction of arrival of an underwater acoustic signal using MATLAB.
Walking Robots, Part 1: Modeling and Simulation Join Sebastian Castro as he shows you how to model a two-legged walking robot, including joint motion actuation and contact forces, using Simscape Multibody.
Walking Robots, Part 2: Actuation and Control Join Sebastian Castro as he shows you how you can use Simulink and the Simscape product family to connect a walking robot model to detailed actuator models with motion planning and control algorithms.
Walking Robots, Part 3: Trajectory Optimization Join Sebastian Castro as he shows you how you can use MATLAB and the Global Optimization Toolbox to find optimal motion trajectories for a Simulink model of a walking robot.
Real-Time Beat Tracking Challenge Jeremy Bell, Angus Keatinge, and James Wagner of The University of New South Wales (UNSW Sydney) discuss their team’s winning entry to the IEEE Signal Processing Cup 2017.
Getting Started with MATLAB and ROS Join Sebastian Castro and Pulkit Kapur as they show how Robotics System Toolbox can help you connect MATLAB and the Robot Operating System (ROS).
Getting Started with Simulink and ROS Join Sebastian Castro and Pulkit Kapur as they show how Robotics System Toolbox can help you connect Simulink and the Robot Operating System (ROS).
Deploying Algorithms to ROS Join Sebastian Castro and Pulkit Kapur as they show how automatic code generation tools can help you deploy algorithms developed in MATLAB and Simulink to run in the Robot Operating System (ROS).
Building Interactive Design Tools Build interactive tools design tools to reduce development time. Zachary Leitzau from Embry-Riddle Aeronautical University demonstrates the use of a self-built app to help design a model airplane.
Simulating Quadcopter Missions Simulation is a great way to test and tune control algorithms for quadcopters. Julien Cassette talks about using Simulink, Robotics Operating System (ROS), and Gazebo to simulate quadcopter missions from student competitions.
Optimizing Airframe Sizing Follow Joshua Williams from Cornell University Unmanned Air Systems (CUAir) as he demonstrates the use of a genetic algorithm to optimize airframe sizing for model airplanes.
Buoy Detection Using Simulink In this video, we will demonstrate how to perform Buoy Detection using Simulink. This video has been designed for use in the AUVSI RoboBoat and RoboSub competitions.
Ball Tracking with a Desktop Computer In this session you’ll learn how to deploy MATLAB® and Simulink® onto a desktop computer for the purpose of controlling an Unmanned Vehicle System in student competitions.
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