Bio Robotics : Arduino Workshop

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    Butterfly Assembly Version.3dm
    Flaytrap Venus Assembly.3dm
    image_2025-01-21_153634727.png
    Elephant Assembly Model.3dm

    The Cheetah Project

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    1 / 8
    leen.ino
    leen__1_.ino

    The Cheetah Project captures the speed and elegance of nature’s fastest animal through a kinetic robotic model. Powered by Arduino, mini servos, and a scissor-lift mechanism, the design recreates the cheetah’s leaping motion, merging biomechanics, engineering, and creativity in an educational exploration of biorobotics.

    Show Case & Wrap-Up

    Kardelen Cici

    Click here and make your Robotics Gif

    1 / 7

    The Butterfly Project imitates the graceful wing movements of butterflies through biomimetic robotics. Built with Arduino Uno, Mini Servo, Breadboard, and DC Motor, it transforms natural elegance into mechanical motion, blending engineering and art to create an educational, interactive design.

    Show Case & Wrap-Up

    Kardelen Cici and 2 OthersFeda'a Najjar
    Joudi Abu Kalam

    Click here and make your Robotics Gif

    1 / 7

    The Butterfly Project imitates the graceful wing movements of butterflies through biomimetic robotics. Built with Arduino Uno, Mini Servo, Breadboard, and DC Motor, it transforms natural elegance into mechanical motion, blending engineering and art to create an educational, interactive design.

    Show Case & Wrap-Up

    Kardelen Cici and 2 OthersShahd Arab
    Abdulaziz aldaqqaq
    1 / 8

    The Butterfly Project imitates the graceful wing movements of butterflies through biomimetic robotics. Built with Arduino Uno, Mini Servo, Breadboard, and DC Motor, it transforms natural elegance into mechanical motion, blending engineering and art to create an educational, interactive design.

    Show Case & Wrap-Up

    Kardelen Cici
    1 / 8

    The Butterfly Project imitates the graceful wing movements of butterflies through biomimetic robotics. Built with Arduino Uno, Mini Servo, Breadboard, and DC Motor, it transforms natural elegance into mechanical motion, blending engineering and art to create an educational, interactive design.

    Show Case & Wrap-Up

    Kardelen Cici
    1 / 8

    The Flytrap Project draws inspiration from the Venus flytrap, a plant that blurs the line between flora and predator. Using a single ultrasonic sensor and a servo motor controlled by Arduino, the model mimics the rapid snapping motion of the trap. With 3D-printed components and sensor-driven interactivity, the project highlights the fascinating intersection of nature’s mechanisms and robotics, offering a playful yet educational look into responsive bio-inspired design.

    Show Case & Wrap-Up

    Kardelen Cici
    1 / 8

    The Flytrap Project draws inspiration from the Venus flytrap, a plant that blurs the line between flora and predator. Using a single ultrasonic sensor and a servo motor controlled by Arduino, the model mimics the rapid snapping motion of the trap. With 3D-printed components and sensor-driven interactivity, the project highlights the fascinating intersection of nature’s mechanisms and robotics, offering a playful yet educational look into responsive bio-inspired design.

    Show Case & Wrap-Up

    Kardelen Cici
    1 / 8

    The Flytrap Project draws inspiration from the Venus flytrap, a plant that blurs the line between flora and predator. Using a single ultrasonic sensor and a servo motor controlled by Arduino, the model mimics the rapid snapping motion of the trap. With 3D-printed components and sensor-driven interactivity, the project highlights the fascinating intersection of nature’s mechanisms and robotics, offering a playful yet educational look into responsive bio-inspired design.

    Show Case & Wrap-Up

    Kardelen Cici
    1 / 8

    The Flytrap Project draws inspiration from the Venus flytrap, a plant that blurs the line between flora and predator. Using a single ultrasonic sensor and a servo motor controlled by Arduino, the model mimics the rapid snapping motion of the trap. With 3D-printed components and sensor-driven interactivity, the project highlights the fascinating intersection of nature’s mechanisms and robotics, offering a playful yet educational look into responsive bio-inspired design.