Close
Main Categories
    Filters
    Preferences
    Search
    RSS

    2024, September

    0 WorldSkills Lyon Autonomous Mobile Robotics Competition Results

    We are thrilled to share the results from the WorldSkills Lyon 2024 Autonomous Mobile Robotics (AMR) Competition! Before diving into the details, we want to give a big shout-out to WorldSkills, the competitors, volunteers, and everyone who made this incredible event possible. This competition wasn’t just a showcase of skills, it was a celebration of how robotics is shaping our future. And, of course, we were especially excited to see our favorite skill, Autonomous Mobile Robotics, take the spotlight! It was amazing to watch these AMR competitors in action, demonstrating how robotics can revolutionize agriculture. They designed, built, and maintained robots while solving real-world problems on the fly. The challenge? Finding ways to boost farm production using robotics to increase efficiency and safety.

    WorldSkills Lyon AMR Winners

    Before we dive into the results, let's take a moment to celebrate every team and competitor. These teams truly raised the bar! Your dedication and skill were truly remarkable, and we deeply appreciate all your hard work. Now, let’s reveal the results of Skill 23, Autonomous Mobile Robotics, from WorldSkills Lyon 2024!

    Gold Medal Winners We had a tie for the top spot! Congratulations to both Team China and Team Korea for an incredible performance!

    • Team China: Canhao Fang and Jiajun Jiang – 763 points
    • Team Korea: Gyeomon Gim and Yonghyeon Kim – 763 points
    Team China WorldSkills Lyon 2024Team Korea WorldSkills AMR

    Bronze Medal           

    • Team Chinese Taipei: Ming-Che Wu and Yuan-Chen Chiang – 738 points

    Medallion for Excellence Recipients Teams that scored 700 or more points and achieved an exceptional level of excellence receive the Medallion for Excellence:

    • Team Macao, China: Kin Hang Lai and Ka Wai Tou – 721 points
    • Team Japan: Kentaro Toribami and Saya Sugimoto – 720 points
    • Team Austria: Jan Trummer and Simon Stoisser – 713 points
    • Team Indonesia: Denny Syahrul Arfiansyah and Ahmad Yogi Fernanda – 711 points
    • Team Kazakhstan: Elnar Zhuasbayev and Timur Babenko – 710 points
    • Team Singapore: Genisa Gabrielle Lee and Gan Kah Kheng – 710 points
    • Team United Arab Emirates: Yahya Alzaabi and Bader Bin Rabaa – 704 points
    • Team Brazil: Matheus Maus Gassen and Matheus Eichherr – 700 points
    • Team Colombia: Juan Sebastian Ospina Manrique and Miguel Angel Quiza Neuto – 700 points

    Honorable Mentions A special shout-out to all the other teams who competed and brought their best to the Autonomous Mobile Robotics competition, including Team Vietnam, Team Croatia, Team India, Team Thailand, Team France, Team Jamaica, Team Hong Kong, China, Team Saudi Arabia, Team Mexico, and Team Iran.

    WorldSkills Lyon Robots in Agriculture 1WorldSkills Lyon Robots in Agriculture 2

    About this Year's AMR Competition

    The WorldSkills 2024 Lyon Autonomous Mobile Robotics competition highlighted the vital role robotics plays in agriculture, where automation is rapidly transforming the industry. Participants will design and build Mobile Robots capable of collecting environmental data. This data is then used to guide both their mobility and object-handling capabilities. In the agriculture sector, robots are used for automating complex tasks, driving the demand for skilled AMR Technicians and Engineers. At WorldSkills, competitors demonstrated key skills, including autonomous navigation in unfamiliar environments and object manipulation. Their robots will handle and transport items of various sizes and weights, all while adapting to real-world challenges. The focus areas of this competition included:

    • Prototyping: Competitors must build innovative solutions from scratch. The prototypes they create must solve specific problems.
    • Navigation and Localization: Robots must navigate unknown environments, which is crucial for real-world applications.
    • Vision: Competitors will create machine vision algorithms to detect and analyze objects. While using a robot is not mandatory in this module, it can be beneficial.
    • Interaction: Robots must be able to work with the delicate precision of a human touch. This is important for handling fragile objects, like in the case of gathering eggs.
    • Testing and Fault-Finding: Competitors must diagnose and fix issues of faulty equipment using provided datasheets.

    The competition culminated in the final challenge where robots must perform autonomous tasks on a defined course. View the complete competition details. The equipment required for this event included the WorldSkills Lyon 2024 Mobile Robotics Collection. There are over 1,600 robotic components included in this kit. WorldSkills Lyon 2024 Competition Field

    The Growing Importance of Robotics in Agriculture

    As the agricultural workforce ages and immigration policies shift, farm labor shortages are becoming a pressing issue. Robots offer a game-changing solution. By automating repetitive, time-consuming tasks, new opportunities emerge in areas like management, programming, and robot maintenance—opening doors to higher-paying, innovative careers. The potential is massive! The global agricultural robotics market is currently valued at $13.5 billion, and it's only growing from here. The future of farming is automated, and we are excited to see where it leads! The world of agriculture is evolving, and robots are leading the way. This competition highlighted this exciting future!

    Studica Robotics has been proudly supporting WorldSkills since 2014, and we're excited to take it to the next level! A Global Partner and the exclusive product supplier for the WorldSkills Mobile Robotics Competition, we are honored to have played our part in WorldSkills Lyon 2024.  We can't wait for Shanghai 2026! The Studica Robotics building system offers everything from controllers and sensors to mechanical structure components and electronics, powering students, and competitors worldwide. With strong, affordable, and compatible parts, Studica Robotics allows you to Build Better Robots®. See you in Shanghai in 2026!
    WorldSkills Lyon Robots in Agriculture 3WorldSkills Lyon Robots in Agriculture 4
    0 Exploring INTO THE DEEP℠ from FIRST® Tech Challenge
    The 2024-2025 FIRST Tech Challenge season, INTO THE DEEP℠ presented by RTX! challenges robots to dive into the ocean’s depths.
    0 How is Odometry Used in FTC Robotics Competitions?

    In the deep-diving world of FTC robotics, precision is everything. One of the key techniques that can give your team the edge is odometry—a method that uses data from motion sensors to track your robot’s position with pinpoint accuracy. This method is beneficial for autonomous mobile robots in circumstances where executing complex tasks requires the robot's precise positioning. Implementing odometry in robotics competitions, such as the FIRST® Tech Challenge (FTC), significantly enhances the performance and reliability of your robot during autonomous operations. Odometry will help your robot navigate when it travels INTO THE DEEPSM this season!

    Navigating FTC with Odometry

    Odometry helps robots navigate the FTC game field, particularly during the autonomous period, by estimating their position relative to their starting point. This positioning makes it easier to execute tasks on the game field. There are several methods for using odometry in FTC, each has pros and cons. Let's explore the two most common methods:

    Drive Encoder Localization ExampleDrive Encoder Localization

    The Drive Encoder Localization method is a straightforward approach. By attaching encoders to the robot's drive motors, teams can estimate their robot's position by monitoring the rotation of motor shafts.

    Advantages:

    • Cost-effective.
    • Easy to set up.
    • No extra hardware required.

    Considerations:

    • Not fully reliable.
    • Factors like wheel slippage, especially with Mecanum wheels, can lead to inaccuracies due to drifting or inconsistent traction.

    Odometry Pods/Dead Wheels

    Odometry Pod ExampleMecanum drivebases, popular in FTC, often struggle with traction on the game field particularly at high speeds. This can cause robots to drift, leading to inaccuracies in positioning. Even minor collisions or bumps during a match can increase these errors, which can accumulate and negatively affect performance. Odometry Pods utilize small, unpowered wheels connected to external encoders, reducing the risk of slippage inaccuracies, and providing more reliable tracking.

    Odometry pods with dead wheels can better track a robot's movement because they are designed to maintain constant contact with the ground, ensuring more accurate positioning throughout the match. Typically, 2-3 small omni wheels are used. In a two-wheel system, one wheel tracks movement in the x-direction and the other in the y-direction. A three-wheel system has two wheels parallel to each other and one perpendicular. While two-wheel systems are cheaper, they tend to drift more than three-wheel systems.

    Advantages:

    • More precise.
    • Greater accuracy over short distances.

    Considerations:

    • Additional costs involved.
    • Requires extra components.
    • It is more complex to design.
    • The wheels must stay in constant contact with the ground for accurate tracking.

    Odometry Pod Assembly

    Dillan from Rust Belt Robotics generously shared his design for an odometry pod he created integrating the Cypher MAX Encoder and the 38mm Omni Wheel into a single, compact casing. The wheel shaft passes through the Cypher MAX, which counts the rotations to determine the distance traveled from the robot’s starting position. The pod is designed to fit seamlessly into a robot's drivebase without occupying excessive space, ensuring the omni wheel remains in constant contact with the field surface for accurate data collection. Odometry Pod Assembly

    Odometry Solutions from Studica Robotics

    Cypher Max Through Bore EncoderTo implement precise odometry, Studica Robotics offers cutting-edge odometry tools like the Cypher MAX Through Bore Encoder, which delivers accuracy for your FTC robot. This powerful sensor combines absolute and incremental encoder technologies into one convenient solution. With 2048 counts per revolution, it provides precise relative and absolute position data. The Cypher MAX operates smoothly at either 3.3V or 5V, making it adaptable to various power setups. You can easily convert a 3/8-inch Hex to a 6mm D-Shaft bore, 5mm Hex, or 7 mm Hex, providing you with flexibility for your application needs. It is a versatile advanced sensor for enhanced localization and control. 38mm Omni Wheel

    Designed for odometry systems and to complement the Cypher MAX, Studica Robotics offers the 38mm Omni Wheel.  This small, yet powerful wheel, when paired with the Cypher MAX, creates a robust solution for tracking and control during autonomous periods. This Omni wheel fits the need for a small and compact dead wheel for tracking. Combined with the Cypher MAX, the 38mm Omni-wheel creates a robust odometry solution for tracking and control during autonomous periods.  

     

    Odometry enables robots to accurately track their position while diving INTO THE DEEP, or navigating the game field, during autonomous periods. Methods like Drive Encoder Localization and Odometry Pods, allow teams to enhance their robots’ navigation and task execution. Each approach has advantages and considerations, but the goal remains improving a robot's ability to understand and respond to its environment. Consider both options when designing your robot to determine the solution that best meets your needs. Odometry tools, such as those offered by Studica Robotics, make it easier for FTC teams to achieve the best performance possible for their autonomous strategies. At Studica Robotics, we're here to provide the advanced tools you need to build accurate and reliable odometry systems.