- Email info@aibotxedu.com
- Phone +91 7259635336
Early Elementary
(Ages 5-7)
Introduce basic concepts of robotics through storytelling and interactive discussions.
Engage students in hands-on activities to build simple robots using pre-made kits or craft materials like cardboard, motors, and simple sensors.
Introduce fundamental programming concepts through visual coding tools like puzzle pieces or simple commands to control robot movements.
Upper Elementary
(Ages 8-10)
Introduce various sensors and actuators used in robotics, such as light sensors, proximity sensors, and servo motors, through interactive demonstrations and experiments.
Guide students in building more complex robots with multiple sensors and actuators, focusing on design principles, problem-solving, and teamwork.
Introduce block-based programming languages like Scratch or Blockly to create sequences of commands for robot control and simple behaviors.
Middle School
(Ages 11-13)
Explore deeper concepts such as robot mechanics, kinematics, and control systems through hands-on experiments, demonstrations, and interactive lessons.
Challenge students to design and build robots with more sophisticated functionalities, such as line-following robots, obstacle avoidance robots, or robotic arms, emphasizing design thinking and iterative prototyping.
Introduce text-based programming languages like Python or JavaScript for more precise control over robot behavior and advanced programming concepts such as loops, conditionals, and functions.
High School
(Ages 14-18)
Dive into advanced topics such as artificial intelligence, machine learning, computer vision, and autonomous navigation through lectures, workshops, and project-based learning.
Undertake challenging robotics projects involving complex mechanisms, advanced sensors, and autonomous capabilities, allowing for experimentation and innovation.
Develop proficiency in text-based programming languages and software development practices relevant to robotics applications, including algorithm design, data structures, and software architecture.
Additional Considerations
Provide opportunities for hands-on workshops, labs, and maker spaces where students can experiment, prototype, and collaborate on robotics projects.
Organize field trips to robotics labs, manufacturing facilities, or universities, and invite guest speakers from the industry to share their experiences and insights with students.
Encourage participation in robotics competitions, science fairs, and exhibitions to showcase students' projects and foster a spirit of competition, teamwork, and achievement.
Advance Robotics Courses: