Artificial Intelligence (AI) for Robotics Training Course

In this instructor-led, live training in Romania (online or onsite), participants will learn the different technologies, frameworks and techniques for programming different types of robots to be used in the field of nuclear technology and environmental systems.

The 6-week course is held 5 days a week. Each day is 4-hours long and consists of lectures, discussions, and hands-on robot development in a live lab environment. Participants will complete various real-world projects applicable to their work in order to practice their acquired knowledge.

The target hardware for this course will be simulated in 3D through simulation software. The ROS (Robot Operating System) open-source framework, C++ and Python will be used for programming the robots.

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

• Understand the key concepts used in robotic technologies.
• Understand and manage the interaction between software and hardware in a robotic system.
• Understand and implement the software components that underpin robotics.
• Build and operate a simulated mechanical robot that can see, sense, process, navigate, and interact with humans through voice.
• Understand the necessary elements of artificial intelligence (machine learning, deep learning, etc.) applicable to building a smart robot.
• Implement filters (Kalman and Particle) to enable the robot to locate moving objects in its environment.
• Implement search algorithms and motion planning.
• Implement PID controls to regulate a robot's movement within an environment.
• Implement SLAM algorithms to enable a robot to map out an unknown environment.
• Extend a robot's ability to perform complex tasks through Deep Learning.
• Test and troubleshoot a robot in realistic scenarios.

In this instructor-led live training available in Romania (online or onsite), participants will learn the technologies, frameworks, and techniques required to program different types of robots for use in nuclear technology and environmental systems.

The four-week course meets five days a week. Each day consists of four hours of lectures, discussions, and hands-on robot development in a live lab environment. Participants will work on practical projects applicable to their work to practice their new skills.

The target hardware for this course is simulated in 3D via simulation software. Code is then loaded onto physical hardware (such as Arduino) for final deployment testing. The ROS (Robot Operating System) open-source framework, C++, and Python are used for programming the robots.

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

• Understand the key concepts used in robotic technologies.
• Understand and manage the interaction between software and hardware in a robotic system.
• Understand and implement the software components that underpin robotics.
• Build and operate a simulated mechanical robot that can see, sense, process, navigate, and interact with humans through voice.
• Understand the necessary elements of artificial intelligence (machine learning, deep learning, etc.) applicable to building a smart robot.
• Implement filters (Kalman and Particle) to enable the robot to locate moving objects in its environment.
• Implement search algorithms and motion planning.
• Implement PID controls to regulate a robot's movement within an environment.
• Implement SLAM algorithms to enable a robot to map out an unknown environment.
• Test and troubleshoot a robot in realistic scenarios.

ROS 2 (Robot Operating System 2) is an open-source framework designed to facilitate the development of complex and scalable robotic applications.

This instructor-led, live training (available online or onsite) is tailored for intermediate-level robotics engineers and developers who aim to implement autonomous navigation and SLAM (Simultaneous Localization and Mapping) using ROS 2.

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

• Configure and set up ROS 2 for autonomous navigation applications.
• Deploy SLAM algorithms for mapping and localization tasks.
• Integrate sensors, such as LiDAR and cameras, with ROS 2.
• Simulate and test autonomous navigation capabilities within Gazebo.
• Deploy navigation stacks onto physical robots.

Course Format

• Interactive lectures and discussions.
• Hands-on practice utilizing ROS 2 tools and simulation environments.
• Live laboratory implementation and testing on virtual or physical robots.

Customization Options

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

Azure Bot Service integrates the capabilities of the Microsoft Bot Framework and Azure Functions, offering a robust platform for rapidly developing intelligent bots.

During this instructor-led live training, attendees will examine methods for efficiently creating intelligent bots within the Microsoft Azure ecosystem.

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

Grasping the fundamental principles behind intelligent bots.

Constructing intelligent bots using cloud-based applications.

Acquiring practical expertise in the Microsoft Bot Framework, the Bot Builder SDK, and Azure Bot Service.

Implementing established bot design patterns in real-world scenarios.

Developing and deploying their initial intelligent bot using Microsoft Azure.

Target Audience

This course is tailored for developers, hobbyists, engineers, and IT professionals who are interested in bot development.

Course Format

The training blends lectures and discussions with exercises, placing a strong emphasis on hands-on practice.

OpenCV is an open-source computer vision library that enables real-time image processing, while deep learning frameworks such as TensorFlow provide the tools for intelligent perception and decision-making in robotic systems.

This instructor-led, live training (online or onsite) is aimed at intermediate-level robotics engineers, computer vision practitioners, and machine learning engineers who wish to apply computer vision and deep learning techniques for robotic perception and autonomy.

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

• Implement computer vision pipelines using OpenCV.
• Integrate deep learning models for object detection and recognition.
• Use vision-based data for robotic control and navigation.
• Combine classical vision algorithms with deep neural networks.
• Deploy computer vision systems on embedded and robotic platforms.

Format of the Course

• Interactive lecture and discussion.
• Hands-on practice using OpenCV and TensorFlow.
• Live-lab implementation on simulated or physical robotic systems.

Course Customization Options

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

A bot, or chatbot, functions like a digital assistant designed to automate user interactions across various messaging platforms, enabling quicker task completion without requiring direct human intervention.

In this instructor-led live training, participants will learn how to begin developing bots by walking through the creation of sample chatbots using dedicated bot development tools and frameworks.

Upon completing this training, participants will be able to:

• Understand the various uses and applications of bots
• Grasp the complete bot development lifecycle
• Explore the diverse tools and platforms used in bot construction
• Construct a sample chatbot for Facebook Messenger
• Build a sample chatbot utilizing the Microsoft Bot Framework

Audience

• Developers interested in creating their own bots

Course Format

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

Edge AI allows artificial intelligence models to execute directly on embedded or resource-limited devices, thereby lowering latency and power usage while boosting autonomy and privacy in robotic applications.

This instructor-led, live training (available online or onsite) is designed for intermediate-level embedded developers and robotics engineers who aim to implement machine learning inference and optimization techniques directly on robotic hardware using TinyML and edge AI frameworks.

Upon completing this training, participants will be capable of:

• Grasping the core concepts of TinyML and edge AI in robotics.
• Converting and deploying AI models for on-device inference.
• Optimizing models for speed, size, and energy efficiency.
• Integrating edge AI systems into robotic control architectures.
• Evaluating performance and accuracy in real-world scenarios.

Course Format

• Interactive lectures and discussions.
• Hands-on exercises utilizing TinyML and edge AI toolchains.
• Practical work on embedded and robotic hardware platforms.

Customization Options

• For customized training requests, please reach out to us to arrange.

This instructor-led, live training in Romania (online or on-site) is designed for intermediate-level participants who want to investigate the role of collaborative robots (cobots) and other human-centric AI systems in modern workplaces.

Upon completing this training, participants will be able to:

• Grasp the core principles of Human-Centric Physical AI and their practical applications.
• Examine how collaborative robots contribute to improved workplace efficiency.
• Recognize and resolve challenges associated with human-machine interactions.
• Create workflows that enhance collaboration between humans and AI-powered systems.
• Foster a culture of innovation and adaptability in organizations utilizing AI.

Human-Robot Interaction (HRI): Voice, Gesture & Collaborative Control is a practical course aimed at introducing participants to the design and implementation of intuitive interfaces for human–robot communication. This training blends theoretical concepts, design principles, and programming practice to help build natural and responsive interaction systems using speech, gesture, and shared control techniques. Participants will learn how to integrate perception modules, develop multimodal input systems, and design robots that can safely collaborate with humans.

This instructor-led, live training (available online or onsite) is targeted at beginner to intermediate-level participants who wish to design and implement human–robot interaction systems that improve usability, safety, and overall user experience.

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

• Grasp the foundational concepts and design principles of human–robot interaction.
• Create voice-based control and response mechanisms for robots.
• Implement gesture recognition using computer vision techniques.
• Design collaborative control systems that enable safe and shared autonomy.
• Evaluate HRI systems based on usability, safety, and human factors.

Course Format

• Interactive lectures and demonstrations.
• Practical coding and design exercises.
• Hands-on experiments in simulation or real robotic environments.

Customization Options

• To request a customized version of this course, please contact us to arrange.

Industrial Robotics Automation: ROS-PLC Integration & Digital Twins is a practical, hands-on course designed to bridge the gap between industrial automation and modern robotics frameworks. Participants will learn how to integrate ROS-based robotic systems with PLCs for synchronized operations, while exploring digital twin environments to simulate, monitor, and optimize production processes. The course places a strong emphasis on interoperability, real-time control, and predictive analysis using digital replicas of physical systems.

Delivered as instructor-led live training (available online or onsite), this program targets intermediate-level professionals eager to develop practical skills in connecting ROS-controlled robots with PLC environments and implementing digital twins for automation and manufacturing optimization.

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

• Grasp the communication protocols used between ROS and PLC systems.
• Execute real-time data exchange between robots and industrial controllers.
• Create digital twins for monitoring, testing, and simulating processes.
• Integrate sensors, actuators, and robotic manipulators into industrial workflows.
• Design and validate industrial automation systems using hybrid simulation environments.

Course Format

• Interactive lectures and architecture walkthroughs.
• Hands-on exercises focusing on integrating ROS and PLC systems.
• Implementation of simulation and digital twin projects.

Course Customization Options

• For customized training requests for this course, please contact us to make arrangements.

This instructor-led live training in Romania (online or onsite) is designed for engineers who want to explore the application of artificial intelligence to mechatronic systems.

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

• Gain a broad overview of artificial intelligence, machine learning, and computational intelligence.
• Understand the core concepts of neural networks and various learning methods.
• Select the most effective artificial intelligence approaches for solving real-world problems.
• Implement AI applications in the field of mechatronic engineering.

The 'Multi-Robot Systems and Swarm Intelligence' advanced training course delves into the design, coordination, and control of robotic teams, drawing inspiration from biological swarm behaviors. Participants will acquire the skills to model interactions, implement distributed decision-making processes, and optimize collaboration among multiple agents. By blending theoretical knowledge with practical simulation exercises, the course prepares learners for real-world applications in logistics, defense, search and rescue operations, and autonomous exploration.

This instructor-led live training, available online or onsite, is designed for advanced-level professionals aiming to design, simulate, and deploy multi-robot and swarm-based systems using open-source frameworks and algorithms.

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

• Grasp the principles and dynamics of swarm intelligence and cooperative robotics.
• Design communication and coordination strategies tailored for multi-robot systems.
• Implement distributed decision-making and consensus algorithms.
• Simulate collective behaviors, including formation control, flocking, and coverage.
• Apply swarm-based techniques to real-world scenarios and optimization challenges.

Format of the Course

• Advanced lectures featuring deep dives into algorithms.
• Hands-on coding and simulation exercises using ROS 2 and Gazebo.
• A collaborative project focused on applying swarm intelligence principles.

Course Customization Options

• To request a customized training session for this course, please contact us to make arrangements.

This instructor-led training in Romania (online or onsite) is designed for advanced robotics engineers and AI researchers looking to leverage Multimodal AI. The goal is to integrate diverse sensory data to build more autonomous and efficient robots that can see, hear, and touch.

Upon completion, participants will be able to:

• Implement multimodal sensing in robotic systems.
• Develop AI algorithms for sensor fusion and decision-making.
• Create robots that can perform complex tasks in dynamic environments.
• Address challenges in real-time data processing and actuation.

A Smart Robot is an Artificial Intelligence (AI) system capable of learning from its environment and past experiences, thereby expanding its capabilities based on acquired knowledge. These robots can collaborate with humans, working alongside them and learning from their behaviors. Beyond performing manual labor, they are equipped to handle cognitive tasks. In addition to physical hardware, Smart Robots can also exist as purely software-based applications within a computer, operating without moving parts or direct physical interaction with the world.

In this instructor-led live training, participants will explore the technologies, frameworks, and techniques required to program various types of mechanical Smart Robots, applying this knowledge to complete their own Smart Robot projects.

The course is structured into 4 sections, each spanning three days of lectures, discussions, and hands-on robot development in a live lab environment. Each section concludes with a practical project, allowing participants to practice and demonstrate their newly acquired skills.

The target hardware for this course will be simulated in 3D using simulation software. Programming the robots will utilize the ROS (Robot Operating System) open-source framework, along with C++ and Python.

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

• Grasp the key concepts underlying robotic technologies
• Understand and manage the interaction between software and hardware in robotic systems
• Understand and implement the software components that form the foundation of Smart Robots
• Build and operate a simulated mechanical Smart Robot capable of seeing, sensing, processing, grasping, navigating, and interacting with humans via voice
• Enhance a Smart Robot's ability to perform complex tasks through Deep Learning
• Test and troubleshoot Smart Robots in realistic scenarios

Audience

• Developers
• Engineers

Format of the course

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

Note

• To customize any aspect of this course (such as programming language or robot model), please contact us to arrange.

Smart Robotics involves combining artificial intelligence with robotic systems to enhance perception, decision-making, and autonomous control.

This guided live training (available online or on-site) is designed for advanced robotics engineers, systems integrators, and automation leads who want to apply AI-driven perception, planning, and control in smart manufacturing settings.

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

• Understand and apply AI techniques for robotic perception and sensor fusion.
• Develop motion planning algorithms for collaborative and industrial robots.
• Deploy learning-based control strategies for real-time decision making.
• Integrate intelligent robotic systems into smart factory workflows.

Format of the Course

• Interactive lecture and discussion.
• Lots of exercises and practice.
• Hands-on implementation in a live-lab environment.

Course Customization Options

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