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Search Results (23)

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Keywords = bipedal walking mechanism

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27 pages, 8168 KB  
Article
Flexipede: A Bio-Inspired, Modular Myriapod Robot for Rough-Terrain Traversal
by Samudra Jit Saha, Md. Abid Chowdhury, Sayma Islam, Shamim Ahmed Deowan, Shifat E. Arman and Abhishek K. Ghosh
Robotics 2026, 15(7), 129; https://doi.org/10.3390/robotics15070129 - 1 Jul 2026
Viewed by 265
Abstract
Rough-terrain exploration is critical for applications ranging from post-disaster search-and-rescue to planetary exploration. While conventional wheeled or bipedal robots often struggle in these environments, biological organisms like myriapods demonstrate superior adaptability. Inspired by this, we present Flexipede—a compact, modular robotic system that employs [...] Read more.
Rough-terrain exploration is critical for applications ranging from post-disaster search-and-rescue to planetary exploration. While conventional wheeled or bipedal robots often struggle in these environments, biological organisms like myriapods demonstrate superior adaptability. Inspired by this, we present Flexipede—a compact, modular robotic system that employs a hybrid actuation architecture, wherein each module integrates a single actuator for propulsive gait generation and a secondary actuator to enable distributed yaw control. The platform is fully 3D-printable and cost-effective, with a fabrication cost of approximately $58 for the primary unit and $10 per additional module. Analytical kinematic modeling was employed to optimize linkage trajectories, with experimental results validating the system across six modular configurations and three distinct environments, including flat, rough, and inclined terrains. The platform achieved locomotion speeds up to 9 cm/s and navigated obstacles up to 32 mm high, while linkage path deviations remained functionally negligible (mean deviation of 3.24%) compared to analytical prediction. Turning performance converged with theoretical predictions as modular scaling increased, reaching a minimum deviation of 4.51% for the five-module configuration. Across all terrains, the system maintained a competitive average Cost of Transportation (CoT) of 18.01, with stair climbing requiring a relatively higher CoT due to the elevated torque demands associated with vertical displacement. These results establish Flexipede as a high-performance benchmark for modular myriapod systems with significant potential for adaptive morphological research. Full article
(This article belongs to the Section Intelligent Robots and Mechatronics)
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20 pages, 12597 KB  
Article
Performance Evaluation of Biped Unit in LARMbot HumanoidV.3
by Alexandra Leonova, Matteo Russo, Cuauhtemoc Morales-Cruz and Marco Ceccarelli
Designs 2026, 10(2), 35; https://doi.org/10.3390/designs10020035 - 18 Mar 2026
Viewed by 648
Abstract
This paper presents the mechanical design and experimental evaluation of the biped unit of LARMbot V.3—a compact low-cost humanoid robot for educational and research purposes. The biped unit features a modular architecture with a parallel leg mechanism for bipedal locomotion. The mechanical configuration [...] Read more.
This paper presents the mechanical design and experimental evaluation of the biped unit of LARMbot V.3—a compact low-cost humanoid robot for educational and research purposes. The biped unit features a modular architecture with a parallel leg mechanism for bipedal locomotion. The mechanical configuration of the unit is introduced, highlighting improvements on previous versions in terms of compactness and operating efficiency. A functional prototype is developed and described with detailed specifications of its actuation and transmission systems. To evaluate the performance of the proposed design, experimental tests were conducted both in-air and on-ground, demonstrating the robot’s ability to perform repeatable walking cycles. The results confirm the feasibility of the design and its potential as a platform for further developments in humanoid locomotion. Full article
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22 pages, 8638 KB  
Article
Design and Experimental Study of Octopus-Inspired Soft Underwater Robot with Integrated Walking and Swimming Modes
by Xudong Dai, Xiaoni Chi, Liwei Pan, Hongkun Zhou, Qiuxuan Wu, Zhiyuan Hu and Jian Wang
Biomimetics 2026, 11(1), 59; https://doi.org/10.3390/biomimetics11010059 - 9 Jan 2026
Cited by 2 | Viewed by 1663
Abstract
To enhance the flexibility and adaptability of underwater robots in complex environments, this paper designs an octopus-inspired soft underwater robot capable of both bipedal walking and multi-arm swimming. The robot features a rigid–flexible coupling structure consisting of a head module and eight rope-driven [...] Read more.
To enhance the flexibility and adaptability of underwater robots in complex environments, this paper designs an octopus-inspired soft underwater robot capable of both bipedal walking and multi-arm swimming. The robot features a rigid–flexible coupling structure consisting of a head module and eight rope-driven soft tentacles and integrates buoyancy adjustment and center-of-gravity balancing systems to achieve stable posture control in both motion modes. Based on the octopus’s bipedal walking and multi-arm swimming mechanisms, this study formulates gait generation strategies for each mode. In walking mode, the robot achieves underwater linear movement, turning, and in-place rotation through coordinated tentacle actuation; in swimming mode, flexible three-dimensional propulsion is realized via synchronous undulatory gaits. Experimental results demonstrate the robot’s peak thrust of 14.1 N, average swimming speed of 8.6 cm/s, and maximum speed of 15.1 cm/s, validating the effectiveness of the proposed structure and motion control strategies. This research platform offers a promising solution for adaptive movement and exploration in unstructured underwater environments. Full article
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18 pages, 3719 KB  
Article
Energy-Efficient Bipedal Locomotion Through Parallel Actuation of Hip and Ankle Joints
by Prabhu Manoharan and Karthikeyan Palanisamy
Symmetry 2025, 17(7), 1110; https://doi.org/10.3390/sym17071110 - 10 Jul 2025
Cited by 4 | Viewed by 2221
Abstract
Achieving energy-efficient, human-like gait remains a major challenge in bipedal humanoid robotics, as traditional serial actuation architectures often lead to high instantaneous power peaks and uneven load distribution. This study addresses the lack of research on how mechanical symmetry, achieved through parallel actuation, [...] Read more.
Achieving energy-efficient, human-like gait remains a major challenge in bipedal humanoid robotics, as traditional serial actuation architectures often lead to high instantaneous power peaks and uneven load distribution. This study addresses the lack of research on how mechanical symmetry, achieved through parallel actuation, can improve power management in lower-limb joints. We developed a 14-degree-of-freedom (DOF) hip-sized bipedal robot model and conducted simulations comparing a conventional serial configuration—using single-DOF rotary actuators—with a novel parallel configuration that employs paired linear actuators at the hip pitch, hip roll, ankle pitch, and ankle roll joints. Simulation results over a standardized walking cycle show that the parallel configuration reduces peak hip-pitch power by 80.4% and peak ankle-pitch power by 53.5%. These findings demonstrate that incorporating actuator symmetry through parallel joint design significantly reduces actuator stress, improves load sharing, and enhances overall energy efficiency in bipedal locomotion. Full article
(This article belongs to the Section Engineering and Materials)
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22 pages, 9133 KB  
Article
A Robust Disturbance Rejection Whole-Body Control Framework for Bipedal Robots Using a Momentum-Based Observer
by Shuai Heng, Xizhe Zang, Yan Liu, Chao Song, Boyang Chen, Yue Zhang, Yanhe Zhu and Jie Zhao
Biomimetics 2025, 10(3), 189; https://doi.org/10.3390/biomimetics10030189 - 19 Mar 2025
Cited by 3 | Viewed by 2848
Abstract
This paper presents a complete planner and controller scheme for bipedal robots, designed to enhance robustness against external disturbances. The high-level planner utilizes model predictive control (MPC) to optimize both the foothold location and step duration based on the divergent component of motion [...] Read more.
This paper presents a complete planner and controller scheme for bipedal robots, designed to enhance robustness against external disturbances. The high-level planner utilizes model predictive control (MPC) to optimize both the foothold location and step duration based on the divergent component of motion (DCM) to increase the robustness of generated gaits. For low-level control, we employ a momentum-based observer capable of estimating external forces acting on both stance and swing legs. The full-body dynamics, incorporating estimated disturbances, are integrated into a weighted whole-body control (WBC) to obtain more accurate ground reaction forces needed by the momentum-based observer. This approach eliminates the dependency on foot-mounted sensors for ground reaction force measurement, distinguishing our method from other disturbance estimation methods that rely on direct sensor measurements. Additionally, the controller incorporates trajectory compensation mechanisms to mitigate the effects of external disturbances. The effectiveness of the proposed framework is validated through comprehensive simulations and experimental evaluations conducted on BRUCE, a miniature bipedal robot developed by Westwood Robotics (Los Angeles, CA, USA). These tests include walking under swing leg disturbances, traversing uneven terrain, and simultaneously resisting upper-body pushes. Full article
(This article belongs to the Special Issue Recent Advances in Robotics and Biomimetics)
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20 pages, 14331 KB  
Article
Stable Walking of a Biped Robot Controlled by Central Pattern Generator Using Multivariate Linear Mapping
by Yao Wu, Biao Tang, Jiawei Tang, Shuo Qiao, Xiaobing Pang and Lei Guo
Biomimetics 2024, 9(10), 626; https://doi.org/10.3390/biomimetics9100626 - 15 Oct 2024
Cited by 5 | Viewed by 3177
Abstract
In order to improve the walking stability of a biped robot in multiple scenarios and reduce the complexity of the Central Pattern Generator (CPG) model, a new CPG walking controller based on multivariate linear mapping was proposed. At first, in order to establish [...] Read more.
In order to improve the walking stability of a biped robot in multiple scenarios and reduce the complexity of the Central Pattern Generator (CPG) model, a new CPG walking controller based on multivariate linear mapping was proposed. At first, in order to establish a dynamics model, the lower limb mechanical structure of the biped robot was designed. According to the Lagrange and angular momentum conservation method, the hybrid dynamic model of the biped robot was established. The initial value of the robot’s passive walking was found by means of Poincaré mapping and cell mapping methods. Then, a multivariate linear mapping model was established to form a new lightweight CPG model based on a Hopf oscillator. According to the parameter distribution of the new CPG model, a preliminary parameter-tuning idea was proposed. At last, the joint simulation of MATLAB and V-REP shows that the biped robot based on the new CPG control has a stable periodic gait in flat and uphill scenes. The proposed method could improve the stability and versatility of bipedal walking in various environments and can provide general CPG generation and a tuning method reference for robotics scholars. Full article
(This article belongs to the Section Locomotion and Bioinspired Robotics)
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21 pages, 7966 KB  
Article
Stable Rapid Sagittal Walking Control for Bipedal Robot Using Passive Tendon
by Haibo Gao, Shengjun Wang, Kaizheng Shan, Changxi Mu, Xin Wang, Bo Su and Haitao Yu
Actuators 2024, 13(7), 240; https://doi.org/10.3390/act13070240 - 26 Jun 2024
Cited by 2 | Viewed by 3297
Abstract
This paper presents the development, control, and experimental validation of a novel bipedal robot with a passive tendon. The robot, featuring foldable legs, coaxial actuation, and compact folded size, is endowed with a leg configuration with a five-bar mechanism. Based on biological observations [...] Read more.
This paper presents the development, control, and experimental validation of a novel bipedal robot with a passive tendon. The robot, featuring foldable legs, coaxial actuation, and compact folded size, is endowed with a leg configuration with a five-bar mechanism. Based on biological observations of human walking, a passive artificial tendon made of emulsion is fabricated to work in conjunction with a tensioning device, providing adaptive heel touchdown and toe push-off in sync with single-leg movement. The tailored control framework for the bipedal robot is further established with the double-layer architecture. The regulation layer employs the linear inverted pendulum (LIP) model to generate reference trajectory of the center of mass (CoM) with a dead-beat style of parameter adjustment. An inverse-dynamics-based whole-body controller (WBC) is applied to enforce the full-order dynamics of the bipedal robot to reproduce the LIP model’s behavior. We carry out the experiments on the physical prototype to evaluate the walking performance of the developed bipedal robot. The results show that the robot achieves stable walking at the speed of 0.8 m/s (almost twice the leg length/s) and exhibits robustness to external push disturbance. Full article
(This article belongs to the Section Actuators for Robotics)
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20 pages, 2353 KB  
Article
Design of Low-Cost Modular Bio-Inspired Electric–Pneumatic Actuator (EPA)-Driven Legged Robots
by Alessandro Brugnera Silva, Marc Murcia, Omid Mohseni, Ryu Takahashi, Arturo Forner-Cordero, Andre Seyfarth, Koh Hosoda and Maziar Ahmad Sharbafi
Biomimetics 2024, 9(3), 164; https://doi.org/10.3390/biomimetics9030164 - 7 Mar 2024
Cited by 5 | Viewed by 5926
Abstract
Exploring the fundamental mechanisms of locomotion extends beyond mere simulation and modeling. It necessitates the utilization of physical test benches to validate hypotheses regarding real-world applications of locomotion. This study introduces cost-effective modular robotic platforms designed specifically for investigating the intricacies of locomotion [...] Read more.
Exploring the fundamental mechanisms of locomotion extends beyond mere simulation and modeling. It necessitates the utilization of physical test benches to validate hypotheses regarding real-world applications of locomotion. This study introduces cost-effective modular robotic platforms designed specifically for investigating the intricacies of locomotion and control strategies. Expanding upon our prior research in electric–pneumatic actuation (EPA), we present the mechanical and electrical designs of the latest developments in the EPA robot series. These include EPA Jumper, a human-sized segmented monoped robot, and its extension EPA Walker, a human-sized bipedal robot. Both replicate the human weight and inertia distributions, featuring co-actuation through electrical motors and pneumatic artificial muscles. These low-cost modular platforms, with considerations for degrees of freedom and redundant actuation, (1) provide opportunities to study different locomotor subfunctions—stance, swing, and balance; (2) help investigate the role of actuation schemes in tasks such as hopping and walking; and (3) allow testing hypotheses regarding biological locomotors in real-world physical test benches. Full article
(This article belongs to the Special Issue Bio-Inspired Locomotion and Manipulation of Legged Robot)
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19 pages, 6218 KB  
Article
A Multi-Agent Reinforcement Learning Method for Omnidirectional Walking of Bipedal Robots
by Haiming Mou, Jie Xue, Jian Liu, Zhen Feng, Qingdu Li and Jianwei Zhang
Biomimetics 2023, 8(8), 616; https://doi.org/10.3390/biomimetics8080616 - 16 Dec 2023
Cited by 3 | Viewed by 5391
Abstract
Achieving omnidirectional walking for bipedal robots is considered one of the most challenging tasks in robotics technology. Reinforcement learning (RL) methods have proved effective in bipedal walking tasks. However, most existing methods use state machines to switch between multiple policies and achieve omnidirectional [...] Read more.
Achieving omnidirectional walking for bipedal robots is considered one of the most challenging tasks in robotics technology. Reinforcement learning (RL) methods have proved effective in bipedal walking tasks. However, most existing methods use state machines to switch between multiple policies and achieve omnidirectional gait, which results in shaking during the policy switching process for bipedal robots. To achieve a seamless transition between omnidirectional gait and transient motion for full-size bipedal robots, we propose a novel multi-agent RL method. Firstly, a multi-agent RL algorithm based on the actor–critic framework is designed, and policy entropy is introduced to improve exploration efficiency. By learning agents with parallel initial state distributions, we minimize reliance on gait planner effectiveness in the Robot Operating System (ROS). Additionally, we design a novel heterogeneous policy experience replay mechanism based on Euclidean distance. Secondly, considering the periodicity of bipedal robot walking, we develop a new periodic gait function. Including periodic objectives in the policy can accelerate the convergence speed of training periodic gait functions. Finally, to enhance the robustness of the policy, we construct a novel curriculum learning method by discretizing Gaussian distribution and incorporate it into the robot’s training task. Our method is validated in a simulation environment, and the results show that our method can achieve multiple gaits through a policy network and achieve smooth transitions between different gaits. Full article
(This article belongs to the Special Issue Bio-Inspired Locomotion and Manipulation of Legged Robot)
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23 pages, 9279 KB  
Article
Dynamic Optimization of Mechanism Parameters of Bipedal Robot Considering Full-Range Walking Energy Efficiency
by Ziyu Chen, Kang An, Zibo Wang, Tiantian Miao, Yaqing Song and Qianqian Shangguan
Appl. Sci. 2023, 13(19), 10791; https://doi.org/10.3390/app131910791 - 28 Sep 2023
Cited by 7 | Viewed by 4839
Abstract
Mechanism parameters of bipedal robots are crucial for achieving efficient locomotion in complex environments. Inspired by the human energy-efficient walking style, this paper proposes a novel concept of full-range walking energy efficiency and explores the optimal linkage mechanism within certain ranges of step [...] Read more.
Mechanism parameters of bipedal robots are crucial for achieving efficient locomotion in complex environments. Inspired by the human energy-efficient walking style, this paper proposes a novel concept of full-range walking energy efficiency and explores the optimal linkage mechanism within certain ranges of step length and walking speed for bipedal robots. First, a bipedal model incorporating an upper body is established for dynamic analysis. Next, an optimal walking gait subject to walking constraints is solved by considering the full-range energy efficiency. Further, an optimal linkage mechanism is investigated, and the influence of dynamic parameters on energy efficiency is analyzed. Finally, the push-off impulse, minimum ground support force, and walking torque features are discussed. It shows that the full-range walking energy efficiency can be lowered by reducing the ratio of leg mass, concentrating mass at the hip joint, decreasing the length of the upper body, or increasing the center of mass of the leg. In addition, efficient walking motion can be achieved by designing the coordination of positive hip joint torque and push-off impulse at the ankle. This paper can be used to guide the mechanism parameter optimization and efficient walking gait design of bipedal robots. Full article
(This article belongs to the Section Mechanical Engineering)
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22 pages, 41837 KB  
Article
Design, Control, and Validation of a Symmetrical Hip and Straight-Legged Vertically-Compliant Bipedal Robot
by Jun Tang, Yudi Zhu, Wencong Gan, Haiming Mou, Jie Leng, Qingdu Li, Zhiqiang Yu and Jianwei Zhang
Biomimetics 2023, 8(4), 340; https://doi.org/10.3390/biomimetics8040340 - 1 Aug 2023
Cited by 5 | Viewed by 4362
Abstract
This paper presents the development, modeling, and control of L03, an underactuated 3D bipedal robot with symmetrical hips and straight legs. This innovative design requires only five actuators, two for the legs and three for the hips. This paper is divided into three [...] Read more.
This paper presents the development, modeling, and control of L03, an underactuated 3D bipedal robot with symmetrical hips and straight legs. This innovative design requires only five actuators, two for the legs and three for the hips. This paper is divided into three parts: (1) mechanism design and kinematic analysis; (2) trajectory planning for the center of mass and foot landing points based on the Divergent Component of Motion (DCM), enabling lateral and forward walking capabilities for the robot; and (3) gait stability analysis through prototype experiments. The primary focus of this study is to explore the application of underactuated symmetrical designs and determine the number of motors required to achieve omnidirectional movement of a bipedal robot. Our simulation and experimental results demonstrate that L03 achieves simple walking with a stable and consistent gait. Due to its lightweight construction, low leg inertia, and straight-legged design, L03 can achieve ground perception and gentle ground contact without the need for force sensors. Compared to existing bipedal robots, L03 closely adheres to the characteristics of the linear inverted pendulum model, making it an invaluable platform for future algorithm research. Full article
(This article belongs to the Special Issue Biologically Inspired Design and Control of Robots)
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15 pages, 6185 KB  
Article
Research on Walking Gait Planning and Simulation of a Novel Hybrid Biped Robot
by Peng Sun, Yunfei Gu, Haoyu Mao, Zhao Chen and Yanbiao Li
Biomimetics 2023, 8(2), 258; https://doi.org/10.3390/biomimetics8020258 - 15 Jun 2023
Cited by 16 | Viewed by 3696
Abstract
A kinematics analysis of a new hybrid mechanical leg suitable for bipedal robots was carried out and the gait of the robot walking on flat ground was planned. Firstly, the kinematics of the hybrid mechanical leg were analyzed and the applicable relevant models [...] Read more.
A kinematics analysis of a new hybrid mechanical leg suitable for bipedal robots was carried out and the gait of the robot walking on flat ground was planned. Firstly, the kinematics of the hybrid mechanical leg were analyzed and the applicable relevant models were established. Secondly, based on the preliminary motion requirements, the inverted pendulum model was used to divide the robot walking into three stages for gait planning: mid-step, start and stop. In the three stages of robot walking, the forward and lateral robot centroid motion trajectories and the swinging leg joint trajectories were calculated. Finally, dynamic simulation software was used to simulate the virtual prototype of the robot, achieving its stable walking on flat ground in the virtual environment, and verifying the feasibility of the mechanism design and gait planning. This study provides a reference for the gait planning of hybrid mechanical legged bipedal robots and lays the foundation for further research on the robots involved in this thesis. Full article
(This article belongs to the Special Issue Design and Control of a Bio-Inspired Robot)
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30 pages, 5202 KB  
Review
The Impact of Activity-Based Interventions on Neuropathic Pain in Experimental Spinal Cord Injury
by Jing Chen, Norbert Weidner and Radhika Puttagunta
Cells 2022, 11(19), 3087; https://doi.org/10.3390/cells11193087 - 30 Sep 2022
Cited by 13 | Viewed by 4001
Abstract
Physical activity-based rehabilitative interventions represent the main treatment concept for people suffering from spinal cord injury (SCI). The role such interventions play in the relief of neuropathic pain (NP) states is emerging, along with underlying mechanisms resulting in SCI-induced NP (SCI-NP). Animal models [...] Read more.
Physical activity-based rehabilitative interventions represent the main treatment concept for people suffering from spinal cord injury (SCI). The role such interventions play in the relief of neuropathic pain (NP) states is emerging, along with underlying mechanisms resulting in SCI-induced NP (SCI-NP). Animal models have been used to investigate the benefits of activity-based interventions (ABI), such as treadmill training, wheel running, walking, swimming, and bipedal standing. These activity-based paradigms have been shown to modulate inflammatory-related alterations as well as induce functional and structural changes in the spinal cord gray matter circuitry correlated with pain behaviors. Thus far, the research available provides an incomplete picture of the cellular and molecular pathways involved in this beneficial effect. Continued research is essential for understanding how such interventions benefit SCI patients suffering from NP and allow the development of individualized rehabilitative therapies. This article reviews preclinical studies on this specific topic, goes over mechanisms involved in SCI-NP in relation to ABI, and then discusses the effectiveness of different activity-based paradigms as they relate to different forms, intensity, initiation times, and duration of ABI. This article also summarizes the mechanisms of respective interventions to ameliorate NP after SCI and provides suggestions for future research directions. Full article
(This article belongs to the Special Issue Cellular and Molecular Mechanisms Underlying Pain Chronicity)
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17 pages, 7985 KB  
Article
Research on Vibration Control Technology of Robot Motion Based on Magnetorheological Elastomer
by Xuegong Huang, Yutong Zhai and Guisong He
Materials 2022, 15(18), 6479; https://doi.org/10.3390/ma15186479 - 18 Sep 2022
Cited by 7 | Viewed by 3272
Abstract
The vibration and impact of a humanoid bipedal robot during movements such as walking, running and jumping may cause potential damage to the robot’s mechanical joints and electrical systems. In this paper, a composite bidirectional vibration isolator based on magnetorheological elastomer (MRE) is [...] Read more.
The vibration and impact of a humanoid bipedal robot during movements such as walking, running and jumping may cause potential damage to the robot’s mechanical joints and electrical systems. In this paper, a composite bidirectional vibration isolator based on magnetorheological elastomer (MRE) is designed for the cushioning and damping of a humanoid bipedal robot under foot contact forces. In addition, the vibration isolation performance of the vibration isolator was tested experimentally, and then, a vibration isolator dynamics model was developed. For the bipedal robot foot impact, based on the vibration isolator model, three vibration reduction control algorithms are simulated, and the results show that the vibration damping effect can reach 85%. Finally, the MRE vibration isolator hardware-in-the-loop-simulation experiment platform based on dSPACE has been built to verify the vibration reduction control effect of the fuzzy PID algorithm. The result shows the vibration amplitude attenuates significantly, and this verifies the effectiveness of the fuzzy PID damping control algorithm. Full article
(This article belongs to the Special Issue Advances in Smart Materials and Structures)
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5 pages, 1577 KB  
Proceeding Paper
Walking Algorithm Using Gait Analysis for Humanoid Robot
by Hasnain Ali Poonja, Muhammad Soleman Ali Shah, Riaz Uddin, Syed Murtaza Hassan Kazmi, Humayun Khan, Abdullah Haider Ali and Muhammad Ayaz Shirazi
Eng. Proc. 2022, 20(1), 35; https://doi.org/10.3390/engproc2022020035 - 4 Aug 2022
Cited by 1 | Viewed by 6940
Abstract
People have been fascinated with humanoid robots for over two decades. They are expected to assist and collaborate with humans in the future. However, due to the limitations and complications of bipedal humanoids’ walking mechanisms, this goal is still a long way off. [...] Read more.
People have been fascinated with humanoid robots for over two decades. They are expected to assist and collaborate with humans in the future. However, due to the limitations and complications of bipedal humanoids’ walking mechanisms, this goal is still a long way off. In this paper, we have presented a walking mechanism algorithm using gait analysis to mimic the human walking pattern and applied that knowledge to enable the 17-DoF bipedal humanoid robot to walk in a constraint environment. The basic sequence of stance and swing phases of human locomotion is studied and used to control servo motors to perform the walking action of the robot. These robots can be useful for social interaction and collaborative tasks in the near future. Full article
(This article belongs to the Proceedings of The 7th International Electrical Engineering Conference)
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