ABB IRB 2600ID Robot Operation and Programming Training Course

Drones and photogrammetry have become indispensable tools for delivering high-precision infrastructure supervision. By leveraging advanced geodesy principles, real-time modeling, and high-accuracy drone mapping, professionals can gain deeper insights, improve accuracy, and boost productivity within construction environments.

This instructor-led live training, available both online and onsite, targets intermediate to advanced professionals eager to apply sophisticated drone and photogrammetry workflows. The curriculum covers geodetic controls and high-precision mapping techniques specifically applied to complex infrastructure projects.

Upon completing this training, participants will be able to:

• Implement advanced photogrammetric methods, such as RTK/PPK workflows and ground control calibration.
• Integrate geodetic reference systems and projections for large-scale infrastructure sites.
• Design precision flight missions customized for complex terrain and infrastructure geometry.
• Analyze photogrammetry data using GIS software to monitor structural health, deformation, and compliance.

Course Format

• Interactive lectures and discussions.
• Advanced exercises and real-world case studies.
• Hands-on implementation with drone data and modeling tools.

Course Customization Options

• To request customized training for this course, please contact us to arrange.

This instructor-led live training in Mexico (online or onsite) is designed for engineers and developers who want to design, develop, and test aerial vehicles by exploring various aerial robotics concepts and tools.

By the end of this training, participants will be able to:

• Grasp the fundamentals of aerial robotics.
• Model and design UAVs and quadrotors.
• Gain knowledge of flight control and motion planning basics.
• Utilize various simulation tools specific to aerial robotics.

In this instructor-led live training, attendees will acquire the skills necessary to build a robot utilizing Arduino hardware and the Arduino (C/C++) programming language.

Upon completion of this training, participants will be capable of:

• Building and operating a robotic system that integrates both software and hardware elements
• Gaining a solid understanding of the fundamental concepts underlying robotic technologies
• Assembling motors, sensors, and microcontrollers to create a functional robot
• Designing the mechanical framework of a robot

Audience

• Developers
• Engineers
• Hobbyists

Course Format

• A combination of lectures, discussions, exercises, and extensive hands-on practice

Important Note

• The instructor will specify the hardware kits required before the training begins. These kits will generally include the following components:
• Arduino board
• Motor controller
• Distance sensor
• Bluetooth slave module
• Prototyping board and connecting cables
• USB cable
• Vehicle chassis kit
• Participants are responsible for purchasing their own hardware.
• For those interested in customizing this training, please reach out to us to make arrangements.

This instructor-led, live training in Mexico (online or onsite) is aimed at anyone who wishes to understand the basics of UAS and apply drone technology in planning, operations, management, and analysis for various industries.

By the end of this training, participants will be able to:

• Gain fundamental knowledge of UAVs and drones.
• Learn about drone classifications and uses to find suitable UAVs that address different needs.
• Evaluate delivery options and regulations for the convenient operation of drones.
• Understand the risks and ethics of using drone technology.
• Explore future uses and capabilities of UAVs including integration with other technologies.

This instructor-led, live training in Mexico (online or onsite) is designed for beginner to intermediate-level participants who wish to learn how to apply drone and photogrammetry techniques for infrastructure oversight in construction projects.

Upon completion of this training, participants will be able to:

• Grasp the core principles of drones and photogrammetry.
• Create and execute drone flight plans tailored for construction sites.
• Conduct photogrammetry tracking to produce detailed maps and 3D models.
• Leverage photogrammetry data for infrastructure oversight and identifying issues.
• Utilize drone technology to enhance safety and efficiency on construction sites.

This instructor-led, live training in Mexico (online or onsite) is designed for agricultural technicians, researchers, and engineers who wish to apply aerial robotics to optimize data collection and analysis for agriculture.

By the end of this training, participants will be able to:

• Understand drone technology and the associated regulations.
• Deploy drones to acquire, process, and analyze crop data to improve farming and agricultural methods.

The Evo Max 4T is a professional-grade drone designed for advanced aerial operations, inspections, and data collection.

This instructor-led, live training (online or onsite) is aimed at beginner-level to intermediate-level operators who wish to safely and effectively use the Evo Max 4T for professional applications and prepare for official certification.

By the end of this training, participants will be able to:

• Understand the technical specifications and operation of the Evo Max 4T drone.
• Apply operational safety procedures in aerial activities.
• Comply with current AAC and local drone regulations.
• Implement best practices for efficient and safe drone operations.
• Prepare for certification/licensing through theoretical and practical training.

Format of the Course

• Interactive lecture and discussion.
• Hands-on practice with drone equipment and simulators.
• Practical exercises and real flight scenarios.

Course Customization Options

• To request a customized training for this course, please contact us to arrange.

This instructor-led, live training in Mexico (online or onsite) is aimed at intermediate-level to advanced-level engineers and technicians who wish to learn how to program, operate, and optimize Fanuc and Epson robotic systems for industrial applications.

By the end of this training, participants will be able to:

• Understand the architecture and functionalities of Fanuc and Epson robots.
• Program robot movements, logic, and sensor integrations.
• Implement safety protocols and troubleshooting techniques.
• Optimize robotic workflows for improved efficiency.

The FIFISH V6 Expert is a professional-grade underwater remotely operated vehicle (ROV) built for inspection, exploration, and the assessment of submerged structures.

This instructor-led live training, available online or onsite, targets intermediate-level technical personnel who want to safely and effectively operate and maneuver the FIFISH V6 Expert during underwater inspections.

Upon completion of this training, participants will be able to:

• Configure, calibrate, and maintain the FIFISH V6 Expert system.
• Pilot the ROV in both open water and confined underwater spaces.
• Perform submerged structural inspection tasks using onboard sensors and tools.
• Capture, manage, and analyze underwater video and data.

Course Format

• Instructor-guided demonstrations and practical briefings.
• Hands-on exercises using actual equipment or simulator environments.
• Field operation practice with supervised piloting scenarios.

Customization Options

• Training content can be tailored to specific inspection environments, mission profiles, or operator competency requirements.

Natural Language Processing turns raw text into actionable intelligence, allowing machines to understand human communication. The course covers fundamental techniques such as corpus analysis, sentence structure parsing, text preprocessing pipelines, and dimensionality reduction using SVD and NMF methods. Participants will engage in practical implementations of document clustering, topic modeling, sentiment analysis, named entity recognition, and Latent Dirichlet Allocation using Python. The program equips professionals to build intelligent text analytics systems for automated content classification and search.

This practical course on Rapid Prototyping for Robotics with ROS 2 & Docker is designed to equip developers with the skills to efficiently build, test, and deploy robotic applications. Participants will gain expertise in containerizing robotics environments, integrating ROS 2 packages, and creating modular robotic systems using Docker to ensure reproducibility and scalability. The curriculum focuses on agile methodologies, version control, and collaborative best practices tailored for innovation teams in the early stages of development.

Delivered as instructor-led live training (available online or onsite), this program targets beginner to intermediate-level participants seeking to accelerate their robotics development workflows through the combined power of ROS 2 and Docker.

Upon completion, participants will be able to:

• Configure a ROS 2 development environment within Docker containers.
• Develop and test robotic prototypes using modular and reproducible setups.
• Leverage simulation tools to validate system behavior prior to hardware deployment.
• Foster effective collaboration through containerized robotics projects.
• Implement continuous integration and deployment principles in robotics pipelines.

Course Format

• Interactive lectures paired with live demonstrations.
• Practical exercises involving ROS 2 and Docker environments.
• Mini-projects centered on real-world robotic applications.

Customization Options

• For teams interested in a tailored training experience, please reach out to us to arrange a customized session.

In this instructor-led live training in Mexico, participants will learn how to start using ROS for their robotics projects through the use of robotics visualization and simulation tools.

By the end of this training, participants will be able to:

• Understand the basics of ROS.
• Learn how to create a basic robotics project using ROS.
• Learn how to use different tools for robotics including simulation and visualization tools.

ROS-Industrial (ROS-I) is an open-source initiative built upon ROS, extending its capabilities to the fields of manufacturing automation and robotics.

In this instructor-led live training, attendees will learn the fundamentals of beginning development with ROS-Industrial.

Upon completing this training, participants will be able to:

• Install and configure ROS-Industrial
• Implement motion and path planning on ROS-I using tools like MoveIt! and Descartes
• Develop simple ROS-I applications
• Build, test, deploy, and troubleshoot new robots using ROS-I

Target Audience

• Programmers
• Developers
• Engineers

Course Format

• A blend of lectures, discussions, exercises, and extensive hands-on practice

Note

• To request customized training for this course, please contact us to arrange.

This instructor-led, live training in Mexico (online or onsite) is designed for robotics developers at beginner to intermediate levels, potentially extending to advanced practitioners who wish to learn how to program mobile robots using ROS and Python.

By the conclusion of this training, participants will be able to:

• Set up a development environment that includes ROS, Python, and a mobile robot platform.
• Create and run ROS nodes, topics, services, and actions using Python.
• Use ROS tools and utilities to monitor and debug ROS applications.
• Use ROS packages and libraries to perform common tasks for mobile robots.
• Integrate ROS with other frameworks and tools.
• Troubleshoot and debug ROS applications.

This instructor-led, live training in Mexico (online or onsite) is designed for beginner to intermediate-level marine engineers, technicians, and offshore operations staff who aim to master the operation and maintenance of ROVs for underwater tasks.

Upon completing this training, participants will be able to:

• Grasp the history, types, and applications of ROVs.
• Identify and describe the components and systems of an ROV.
• Effectively navigate and communicate with ROVs underwater.
• Pilot ROVs with precision across various underwater scenarios.
• Carry out routine maintenance and troubleshoot common issues.
• Implement safety protocols during underwater operations.