CRIS
Permanent URI for this communityhttps://scripta.up.edu.mx/handle/20.500.12552/1
Browse
3 results
Search Results
Now showing 1 - 3 of 3
- Some of the metrics are blocked by yourconsent settings
Item type:Publication, GABOT: Garbage Autonomous Collector for Indoors at Low Cost(2019) ;Mayorga, Carlos ;Gómez, Cristina ;Díaz Ramos, Gabriel ;Vázquez, CarlosKobayashi, RafaelThe constant raise in the levels of garbage in our city contributes to the worldwide pollution nowadays and this becoming a health issue for the entire world. Another problem is to avoid more garbage collectors get ill because of the exposure they have to solid wastes that can make them have health issues. This lead us to design a garbage collector that can move around looking for garbage and can store it in a specific container. It will have a manipulator that will be moving thanks to a vehicle that can avoid obstacles. A camera will detect the garbage whenever it is in front of it and the manipulator will take it. In this work we propose a proof of concept of a mechatronic system that can detect and pick up garbage on a zone using a camera and sensors. © 2019 IEEE.Scopus© Citations 2 15 2 - Some of the metrics are blocked by yourconsent settings
Item type:Publication, Modeling and simulation for designing a line walking chameleon-like legged robot(2022); ; ; ;Díaz Ramos, GabrielMayorga Acosta, CarlosLegged robots have been developed to move on uneven terrains. They can move smoother and step over obstacles easily, and they are more versatile in various environmental scenarios. These features make them desirable for maintenance and/or search-and-rescue tasks where mobility is restricted on these complex terrains. A problem arises when legged robots are required to walk on the top of narrow support, e.g. thin beams or tubes. In this work, we present the design of a line walking legged robot for narrowed support. To achieve this goal, we get inspiration from the chameleon locomotion. From these observations, we simulate the robot, design an intelligent control strategy for self-balancing and walking, and we implement a robot prototype. The experimental results show that the balance controller provides a tilt angle of 2.24±2.21∘, while the robot walks in a straight line with a maximum offset of 3.0 cm and with a walking velocity of 0.2 cm/s. Our results demonstrate that the robot can move on narrowed support lines. We anticipate that the design of legged robots inspired by the chameleon locomotion might open wider possibilities for rescue and maintenance missions. © 2022 Elsevier B.V.Scopus© Citations 4 16 1 - Some of the metrics are blocked by yourconsent settings
Item type:Publication, Modeling and Control Balance Design for a New Bio-inspired Four-Legged Robot(2019); ; ; ;Mayorga-Acosta, CarlosDíaz Ramos, GabrielBio-inspired robots have chosen to propose novel developments aiming to inhabit and interact complex and dynamic environments. Bio-inspired four-legged robots, typically inspired on animal locomotion, provide advantages on mobility, obstacle avoidance, energy efficiency and others. Balancing is a major challenge when legged robots require to move over uncertain and sharp terrains. It becomes of particular importance to solve other locomotion tasks such as walking, running or jumping. In this paper, we present a preliminary study on the modeling and control balance design of a bio-inspired four-legged robot for standing on its aligned legs in a straight line. The proposed robot is loosely inspired on the bio-mechanics of the chameleon. Thus, a mathematical modeling, simulation, intelligent control strategy, prototype implementation and preliminary results of control balance in our robot are presented and discussed. © Springer Nature Switzerland AG 2019.Scopus© Citations 4 18 2
