Omron Robot Programming Tutorial

Omron Robot Programming Tutorial

What you'll learn
Using a flexpendant
Using a robot simulation
Using a robot programming
Using a controller
Requirements
to be learn robotic
Description
This series of "Robotics: Learn by building" modules has an end-goal focus on the diverse field of robotics. In module I we learned the basics of electricity and electronics. In this module II you further developed your knowledge and skills to include digital electronics and practice your skills on real-life digital components. In this third course you will learn physics principles (from simple to very complex) with a specific goal of understanding and even designing your own drive systems for robots. You will learn details about different robotic drive systems you will see in commercial, industrial robots like how timing belt drives work and why they are so important in robotics, as well as the more esoteric drives like the harmonic drive - what it is an how that amazing system works.

We will even look at a real-life case study as we design a submarine robot, remotely operated and able to withstand the bone-crushing operating depths of over 600 meters minimum. The unique challenges we will face will build up your knowledge so that you too can design sea-floor robots facing harsh environments to perform inspection, welding or maintenance on submarine pipes or cables.

This course is the prerequisite for the module IV course where you'll learn prototyping skills, and gain a wide variety of knowledge and skills so you can actually build your own robots and manufacture your own parts. In module IV, you'll culminate all you've learned so far as you build a 3D printer from scratch, hook it up to a desktop computer and make your own plastic parts. The 3D printer is, in effect, a robot which you can then use to make parts for your other robot designs. In module V you can take your robot design and construction skills to the next level with a hands-on approach to autonomous robotic systems: learning about various sensors to know where you are and what your robot is doing, GPS navigation, basic artificial intelligence, powerful microchips known as FPGA's where you literally design a custom circuit on the chip, vision systems and more.

Lesson overview

In this course we'll be covering

Simple machines (which all come into play in surprising ways you probably haven't seen before)

Designing an arm robot

The toggle mechanism (again, comes into play in a ridiculous number of surprising ways you probably haven't seen before)

harmonic drives, cycloidal drives, epicyclic drives, traction drives

strength of materials & construction challenge

case study: design challenges of a deep-submarine, remotely operated vehicle

hydraulics & pneumatics (including building your own)

air & hydraulic muscles, muscle wire

servos (speed, pressure, force, position, etc…)

DC motors, BLDC motors, BLDC servo motors, stepper motors, AC motors, AC servo motors, single and three phase power, electrical generation

frequency drives, PWM AC signal generation

regenerative / rheostatic / dynamic braking, looking at electric vehicle design and locomotive design

counter-force systems you will encounter in industrial robots

safety around robot systems, in industry and hobby

robot designs: articulated arm, gantry, spine, collaborative

case study: combat robots

Who this course is for
controller