Carvajal, Christian
Preferred name
Carvajal, Christian
Main Affiliation
Ambato
9 results
Now showing 1 - 9 of 9
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Item type:Publication, Real-Time Digital Twin Architecture for Immersive Industrial Automation Training(2026) ;Jessica S. Ortiz ;Víctor H. AndaluzIndustrial automation laboratories often face limitations related to restricted access to industrial equipment, safety constraints, and limited scalability for hands-on experimentation. To address these challenges, this work proposes a real-time multi-layer Digital Twin architecture integrating a physical Siemens S7-1500 PLC, an immersive Unity-based virtual environment, HMI supervision, and IoT-enabled remote monitoring within a unified communication framework. The architecture is structured into physical, digital, and integration layers, enabling modular scalability and bidirectional synchronization between the physical process and its virtual representation through Ethernet TCP/IP communication. System performance was evaluated using synchronization metrics including communication latency, jitter, deterministic timing deviation, and event synchronization accuracy. Experimental results demonstrated stable PLC–Digital Twin communication with average latencies below 15 ms and jitter below 0.5 ms, ensuring reliable real-time interaction during continuous operation. A comparative evaluation with engineering students also showed improved learning conditions, achieving high perceived usability (SUS = 86/100) and reduced cognitive workload (NASA-TLX = 34/100). These results confirm the effectiveness of the proposed architecture as a scalable platform for Industry 4.0 training environments.</jats:p>1 - Some of the metrics are blocked by yourconsent settings
Item type:Publication, Virtual Teleoperation System for Mobile Manipulator Robots Focused on Object Transport and Manipulation(2024) ;Fernando J. Pantusin; ;Jessica S. OrtizVíctor H. AndaluzThis work describes the development of a tool for the teleoperation of robots. The tool is developed in a virtual environment using the Unity graphics engine. For the development of the application, a kinematic model and a dynamic model of a mobile manipulator are used. The mobile manipulator robot consists of an omnidirectional platform and an anthropomorphic robotic arm with 4 degrees of freedom (4DOF). The model is essential to emulate the movements of the robot and to facilitate the immersion in the virtual environment. In addition, the control algorithms are established and developed in MATLAB 2020 software, which improves the acquisition of knowledge to teleoperate robots and execute tasks of manipulation and transport of objects. This methodology offers a cheaper and safer alternative to real physical systems, as it reduces both the costs and risks associated with using a real robot for training.21 - Some of the metrics are blocked by yourconsent settings
Item type:Publication, A hybrid bio-inspired visual servoing strategy for aerial grasping of static and moving targets(2026); ;Víctor H. Andaluz ;Flavio Roberti; Ricardo CarelliThis article presents a bio-inspired visual servo control scheme for aerial grasping of static and moving targets using aerial manipulators (AM). The proposed approach is based on a cascaded control architecture. The first control layer implements a bio-inspired hybrid visual servo strategy that combines Image Based Visual Servoing (IBVS) and Position Based Visual Servoing (PBVS), motivated by the prey capturing behavior of birds of prey. An Aerial-Eye-to-Hand visual configuration is introduced, in which an onboard camera mounted on the aerial platform is used to simultaneously regulate image plane features and spatial variables associated with the target. The grasping task is organized into four autonomous stages, enabling coordinated detection, approach, grasping, and transportation. Exploiting the redundancy of aerial manipulators, the proposed scheme allows the simultaneous fulfillment of multiple control objectives, including target visibility maintenance and accurate end effector positioning. The second control layer consists of a dynamic compensation controller formulated in terms of reference velocities, which facilitates its implementation on aerial platforms with embedded low level controllers. A formal stability and robustness analysis of the cascaded closed-loop system is provided. Experimental results, including real-world aerial grasping of moving ground targets in unstructured environments, demonstrate the effectiveness of the proposed approach. © 2026 The Author(s)1 - Some of the metrics are blocked by yourconsent settings
Item type:Publication, Technology-Mediated Collaborative Strategies Among Online University Students(2025); ; ; ;Orly Carvache-FrancoLidia MinchenkovaThis quasi-experimental study aimed to evaluate the effectiveness of collaborative teaching strategies mediated by digital technologies among online university students. The research was conducted with a sample of 256 participants, divided into an experimental group and a control group. While both groups used technological resources, only the experimental group engaged in structured collaborative strategies using tools such as Genially, Kahoot, Canva, Padlet, and Wordwall, within the framework of the Cátedra Integradora course. The results revealed a significant improvement in the academic performance of the experimental group, with an average increase of 27.4%, compared to 13.2% in the control group. Furthermore, the teacher's perception highlighted higher levels of student engagement, motivation, and collaboration among those who actively participated in the strategies. These findings demonstrate that the intentional use of educational technologies with a collaborative focus fosters active, participatory, and meaningful learning, while also strengthening socio-emotional skills and improving academic achievement in virtual higher education settings. © 2025 IEEE.23 - Some of the metrics are blocked by yourconsent settings
Item type:Publication, A Hardware‐in‐the‐Loop and 3D Simulation Framework for Active Learning in Engineering Education(2025) ;Jessica S. Ortiz ;Manuel A. Masapanta ;Víctor H. AndaluzThis paper describes the implementation of an industrial control system using the Hardware‐in‐the‐Loop (HIL) technique, integrating a Siemens S7‐1200 PLC with a virtual plant developed in Unity 3D, using the Modbus TCP communication protocol. This integration allows real‐time simulation of industrial processes in a safe, immersive and interactive environment, facilitating the design, testing and validation of control strategies without the need for a physical plant. As part of the study, usability tests were carried out to verify whether the proposed solution is suitable for use as a teaching resource by engineering students. The evaluation was applied to two groups of 20 students each, who interacted with the virtual environment and executed control and monitoring tasks of the simulated process. The results obtained show a satisfactory acceptance of the platform, highlighting its usefulness as a support tool for the understanding and manipulation of automated processes in a controlled environment. This approach proves to be an efficient, safe and scalable alternative for training in industrial automation, aligned with the principles of Industry 4.0.18 - Some of the metrics are blocked by yourconsent settings
Item type:Publication, Digital Twin Integration for Active Learning in Robotic Manipulator Control Within Engineering 4.0(2025) ;Fernando J. Pantusin ;Jessica S. Ortiz; ;Víctor H. AndaluzLenin G. YarRobotic systems play an increasingly significant role in both education and industry; however, access to physical robots remains a challenge due to high costs and operational risks. This work presents a training platform based on Digital Twins, aimed at active learning in the control of robotic manipulators, with a focus on the UFACTORY 850 arm. The proposed approach integrates mathematical modeling, interactive simulation, and experimental validation, enabling the implementation and testing of control strategies in three virtual scenarios that replicate real-world conditions: a laboratory, a service environment, and an industrial production line. The system relies on kinematic and dynamic models of the manipulator, using maneuverability velocities as input signals, and employs ROS as middleware to link the Unity 2022.2.14 graphics engine with the control algorithms developed in MATLAB R2022a. Experimental results demonstrate the accuracy of the implemented models and the effectiveness of the control algorithms, validating the usefulness of Digital Twins as a pedagogical tool to support safe, accessible, and innovative learning in robotic engineering.16 - Some of the metrics are blocked by yourconsent settings
Item type:Publication, Robust Visual Servoing for Quadruped Robots: ISS-Based Target Tracking With Secondary Formation Objectives(2026); ; ; ;Víctor H. AndaluzFlavio RobertiThis workpresents the design, implementation, and experimental validation of a visual servo control scheme formulated at the task-space level and applied to a quadruped robot equipped with an active two degree of freedom (2DoF) vision system for continuous tracking of moving targets. The proposed controller is based on a differential kinematic model that maps the robot's task-space velocity references to the kinematic evolution of the active vision system, incorporating a target velocity estimator that enables dynamic compensation of the target motion projected onto the image plane. The control architecture exploits the kinematic redundancy of the robotic system to simultaneously address multiple control objectives within a hierarchical framework. The primary task ensures target centering in the image plane, thereby maintaining visibility within the robot's field of view, while the secondary task regulates relative formation by controlling the distance and orientation between the robot and the target. Quadruped locomotion is handled by a low-level gait controller and is not modified by the proposed scheme. Closed-loop stability is rigorously analyzed using Lyapunov theory, demonstrating Input-to-State Stability properties in the presence of bounded disturbances. Simulation and real-world experimental results obtained with the Unitree Go2 robot confirm the robustness and stability of the proposed approach for dynamic visual tracking in realistic scenarios. © 2020 IEEE.2 - Some of the metrics are blocked by yourconsent settings
Item type:Publication, Bilateral Rate/Position Delayed Teleoperation Control for UAVs: A Performance Evaluation(2025); ;Emanuel Slawiñski ;Viviana Moya; This paper introduces a bilateral teleoperation system for UAVs that employs a hybrid control scheme combining rate and non-linear position modes. By continuously switching between these modes, the system achieves both agile manoeuvring and precise positioning under communication delays. Validation is carried out using a dynamic model for the master robot with a Novint Falcon haptic device and a simplified model for the slave robot in Gazebo-ROS2. Performance metrics including task completion time, mean squared error, and force feedback demonstrate enhanced stability and efficiency, suggesting promising applications in inspection, environmental monitoring and search and rescue18 - Some of the metrics are blocked by yourconsent settings
Item type:Publication, Experimental Validation of a Kinematic Control Strategy for Trajectory Tracking in Quadruped Robots(2025); ; ;Víctor H. Andaluz; This work presents a high-level control architecture for trajectory tracking in quadruped robots. The proposed controller is based on the motion kinematics of the robot's center of mass (CoM). The proposed strategy transforms planned trajectories in Cartesian space into motion velocity commands for the robot, using a differential kinematic model that relates the velocity of the robot's operational point to its velocity in the XY-plane. The control scheme is organized hierarchically, where the kinematic controller operates independently from the system dynamics, which are handled by low-level controllers. The proposed control architecture is experimentally validated using the Unitree Go2 quadruped robot, employing MATLAB and ROS2 tools. The results confirm the feasibility of using purely kinematic models for high-level locomotion task control under real-world operating conditions. © 2025 IEEE.11
