Your search keyword '"Neural Control"' showing total 2,785 results

1. Neural Chaotic Dynamics for Adaptive Exploration Control of an Autonomous Flying Robot

Author

Jaiton, Vatsanai, Manoonpong, Poramate, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Brock, Oliver, editor, and Krichmar, Jeffrey, editor

Published

2025

2. Computationally Efficient Inference via Time-Aware Modular Control Systems.

Author

Shchyrba, Dmytro and Zarzycki, Hubert

Abstract

Control in multi-agent decision-making systems is an important issue with a wide variety of existing approaches. In this work, we offer a new comprehensive framework for distributed control. The main contributions of this paper are summarized as follows. First, we propose PHIMEC (physics-informed meta control)—an architecture for learning optimal control by employing a physics-informed neural network when the state space is too large for reward-based learning. Second, we offer a way to leverage impulse response as a tool for system modeling and control. We propose IMPULSTM, a novel approach for incorporating time awareness into recurrent neural networks designed to accommodate irregular sampling rates in the signal. Third, we propose DIMAS, a modular approach to increasing computational efficiency in distributed control systems via domain-knowledge integration. We analyze the performance of the first two contributions on a set of corresponding benchmarks and then showcase their combined performance as a domain-informed distributed control system. The proposed approaches show satisfactory performance both individually in their respective applications and as a connected system. [ABSTRACT FROM AUTHOR]

Published

2024

3. POMA: Propagation-Based Obstacle Negotiation Control for Multi-segmented Robot Adaptation

Author

Nantareekurn, Worameth, Leung, Binggwong, Srisuchinnawong, Arthicha, Homchanthanakul, Jettanan, Pewkliang, Suppachai, Manoonpong, Poramate, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Berns, Karsten, editor, Tokhi, Mohammad Osman, editor, Roennau, Arne, editor, Silva, Manuel F., editor, and Dillmann, Rüdiger, editor

Published

2024

4. FreeLander: A Versatile, Modular, Multi-legged Robot Platform for Complex Terrains

Author

Chuthong, Thirawat, Homchanthanakul, Jettanan, Leung, Binggwong, Pewkliang, Suppachai, Manoonpong, Poramate, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Youssef, Ebrahim Samer El, editor, Tokhi, Mohammad Osman, editor, Silva, Manuel F., editor, and Rincon, Leonardo Mejia, editor

Published

2024

5. Neural Control and Learning of a Gecko-Inspired Robot for Aerial Self-righting

Author

Chanfreau, Léonard, Haomachai, Worasuchad, Manoonpong, Poramate, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Youssef, Ebrahim Samer El, editor, Tokhi, Mohammad Osman, editor, Silva, Manuel F., editor, and Rincon, Leonardo Mejia, editor

Published

2024

6. Design of an Adaptive Neural Controller Applied to Pressure Control in Industrial Processes

Author

Vera, Lucas, Benítez, Adela, Fernández Mareco, Enrique, Pinto Roa, Diego, Howlett, Robert J., Series Editor, Jain, Lakhmi C., Series Editor, Jha, Pradeep Kumar, editor, Tripathi, Brijesh, editor, Natarajan, Elango, editor, and Sharma, Harish, editor

Published

2024

7. Neural network quaternion-based controller for port-Hamiltonian system

Author

Alsaadi Fawaz E., Serrano Fernando E., and Batrancea Larissa M.

Subjects

neural networks, quaternions, port-hamiltonian systems, neural control, 93d15, 93d20, 93d30, 93d05, Mathematics, QA1-939

Abstract

In this research article, a control approach for port-Hamiltonian PH systems based in a neural network (NN) quaternion-based control strategy is presented. First, the dynamics is converted by the implementation of a Poisson bracket in order to facilitate the mathematical model in order to obtain a feasible formulation for the controller design based on quaternion NNs. In this study, two controllers for this kind of of system are presented: the first one consists in the controller design for a PH system about its equilibrium points taking into consideration the position and momentum. This mean is achieved by dividing the quaternion neural controller into scalar and vectorial parts to facilitate the controller derivation by selecting a Lyapunov functional. The second control strategy consists in designing the trajectory tracking controller, in which a reference moment is considered in order to drive this variable to the final desired position according to a reference variable; again, a Lyapunov functional is implemented to obtain the desired control law. It is important to mention that both controllers take into advantage that the energy consideration and that the representation of many physical systems could be implemented in quaternions. Besides the angular velocity, trajectory tracking of a three-phase induction motor is presented as a third numerical experiment. Two numerical experiments are presented to validate the theoretical results evinced in this study. Finally, a discussion and conclusion section is provided.

Published

2024

8. A sensorimotor enhanced neuromusculoskeletal model for simulating postural control of upright standing.

Author

Shanbhag, Julian, Fleischmann, Sophie, Wechsler, Iris, Gassner, Heiko, Winkler, Jürgen, Eskofier, Bjoern M., Koelewijn, Anne D., Wartzack, Sandro, and Miehling, Jörg

Subjects

SINGLE-degree-of-freedom systems, RANGE of motion of joints, ANATOMICAL planes, CONTROL (Psychology), INTERNAL auditing

Abstract

The human's upright standing is a complex control process that is not yet fully understood. Postural controlmodels can provide insights into the body's internal control processes of balance behavior. Using physiologically plausible models can also help explaining pathophysiological motion behavior. In this paper, we introduce a neuromusculoskeletal postural controlmodel using sensor feedback consisting of somatosensory, vestibular and visual information. The sagittal plane model was restricted to effectively six degrees of freedom and consisted of nine muscles per leg. Physiologically plausible neural delays were considered for balance control. We applied forward dynamic simulations and a single shooting approach to generate healthy reactive balance behavior during quiet and perturbed upright standing. Control parameters were optimized tominimize muscle effort. We showed that our model is capable of fulfilling the applied tasks successfully. We observed joint angles and ranges of motion in physiologically plausible ranges and comparable to experimental data. This model represents the starting point for subsequent simulations of pathophysiological postural control behavior. [ABSTRACT FROM AUTHOR]

Published

2024

9. The relationship between SGLT2 and systemic blood pressure regulation

Author

Ahwin, Priscilla and Martinez, Diana

Published

2024

10. Reliability and minimal detectable change of stiffness and other mechanical properties of the ankle joint in standing and walking.

Author

Cubillos, Luis H., Rouse, Elliott J., Augenstein, Thomas E., Joshi, Varun, Claflin, Edward S., and Krishnan, Chandramouli

Subjects

*JOINT stiffness, *WALKING, *ANKLE injuries, *INTRACLASS correlation, *DORSIFLEXION

Abstract

Ankle joint stiffness and viscosity are fundamental mechanical descriptions that govern the movement of the body and impact an individual's walking ability. Hence, these internal properties of a joint have been increasingly used to evaluate the effects of pathology (e.g., stroke) and in the design and control of robotic and prosthetic devices. However, the reliability of these measurements is currently unclear, which is important for translation to clinical use. Can we reliably measure the mechanical impedance parameters of the ankle while standing and walking? Eighteen able-bodied individuals volunteered to be tested on two different days separated by at least 24 h. Participants received several small random ankle dorsiflexion perturbations while standing and during the stance phase of walking using a custom-designed robotic platform. Three-dimensional motion capture cameras and a 6-component force plate were used to quantify ankle joint motions and torque responses during normal and perturbed conditions. Ankle mechanical impedance was quantified by computing participant-specific ensemble averages of changes in ankle angle and torque due to perturbation and fitting a second-order parametric model consisting of stiffness, viscosity, and inertia. The test-retest reliability of each parameter was assessed using intraclass correlation coefficients (ICCs). We also computed the minimal detectable change (MDC) for each impedance parameter to establish the smallest amount of change that falls outside the measurement error of the instrument. In standing, the reliability of stiffness, viscosity, and inertia was good to excellent (ICCs=0.67–0.91). During walking, the reliability of stiffness and viscosity was good to excellent (ICCs=0.74–0.84) while that of inertia was fair to good (ICCs=0.47–0.68). The MDC for a single subject ranged from 20%− 65% of the measurement mean but was higher (>100%) for inertia during walking. Results indicate that dynamic measures of ankle joint impedance were generally reliable and could serve as an adjunct clinical tool for evaluating gait impairments. • The ankle impedance provides insight into the internal mechanisms that govern gait. • The test-retest reliability of ankle impedance was tested in standing and walking. • In standing, reliability of stiffness, viscosity, and inertia was good to excellent. • During walking, the reliability of stiffness and viscosity was good to excellent. • Dynamic measures of ankle joint impedance were higher during standing than walking. [ABSTRACT FROM AUTHOR]

Published

2024

11. System of Implantable Electrodes for Neural Signal Acquisition and Stimulation for Wirelessly Connected Forearm Prosthesis.

Author

Ionescu, Octavian Narcis, Franti, Eduard, Carbunaru, Vlad, Moldovan, Carmen, Dinulescu, Silviu, Ion, Marian, Dragomir, David Catalin, Mihailescu, Carmen Marinela, Lascar, Ioan, Oproiu, Ana Maria, Neagu, Tiberiu Paul, Costea, Ruxandra, Dascalu, Monica, Teleanu, Mihai Daniel, Ionescu, Gabriela, and Teleanu, Raluca

Subjects

NEUROPROSTHESES, NERVE tissue, ELECTRODES, ACTION potentials, FOREARM, PROSTHETICS, DEEP brain stimulation

Abstract

There is great interest in the development of prosthetic limbs capable of complex activities that are wirelessly connected to the patient's neural system. Although some progress has been achieved in this area, one of the main problems encountered is the selective acquisition of nerve impulses and the closing of the automation loop through the selective stimulation of the sensitive branches of the patient. Large-scale research and development have achieved so-called "cuff electrodes"; however, they present a big disadvantage: they are not selective. In this article, we present the progress made in the development of an implantable system of plug neural microelectrodes that relate to the biological nerve tissue and can be used for the selective acquisition of neuronal signals and for the stimulation of specific nerve fascicles. The developed plug electrodes are also advantageous due to their small thickness, as they do not trigger nerve inflammation. In addition, the results of the conducted tests on a sous scrofa subject are presented. [ABSTRACT FROM AUTHOR]

Published

2024

12. A sensorimotor enhanced neuromusculoskeletal model for simulating postural control of upright standing

Author

Julian Shanbhag, Sophie Fleischmann, Iris Wechsler, Heiko Gassner, Jürgen Winkler, Bjoern M. Eskofier, Anne D. Koelewijn, Sandro Wartzack, and Jörg Miehling

Subjects

postural control, standing, simulation, forward dynamics, neuromusculoskeletal modeling, neural control, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The human's upright standing is a complex control process that is not yet fully understood. Postural control models can provide insights into the body's internal control processes of balance behavior. Using physiologically plausible models can also help explaining pathophysiological motion behavior. In this paper, we introduce a neuromusculoskeletal postural control model using sensor feedback consisting of somatosensory, vestibular and visual information. The sagittal plane model was restricted to effectively six degrees of freedom and consisted of nine muscles per leg. Physiologically plausible neural delays were considered for balance control. We applied forward dynamic simulations and a single shooting approach to generate healthy reactive balance behavior during quiet and perturbed upright standing. Control parameters were optimized to minimize muscle effort. We showed that our model is capable of fulfilling the applied tasks successfully. We observed joint angles and ranges of motion in physiologically plausible ranges and comparable to experimental data. This model represents the starting point for subsequent simulations of pathophysiological postural control behavior.

Published

2024

13. Optimal and Adaptive Stimulation Design

Author

Zhang, Xu, Santaniello, Sabato, and Thakor, Nitish V., editor

Published

2023

14. Sucker Attachment and Detachment Patterns in Octopus Vulgaris

Author

Röckner, Janina Leonie, Arellano, Mariana Díaz, Zullo, Letizia, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Meder, Fabian, editor, Hunt, Alexander, editor, Margheri, Laura, editor, Mura, Anna, editor, and Mazzolai, Barbara, editor

Published

2023

15. An advanced discrete‐time RNN for handling discrete time‐varying matrix inversion: Form model design to disturbance‐suppression analysis

Author

Yang Shi, Qiaowen Shi, Xinwei Cao, Bin Li, Xiaobing Sun, and Dimitrios K. Gerontitis

Subjects

neural control, neural network, real‐time systems, Computational linguistics. Natural language processing, P98-98.5, Computer software, QA76.75-76.765

Abstract

Abstract Time‐varying matrix inversion is an important field of matrix research, and lots of research achievements have been obtained. In the process of solving time‐varying matrix inversion, disturbances inevitably exist, thus, a model that can suppress disturbance while solving the problem is required. In this paper, an advanced continuous‐time recurrent neural network (RNN) model based on a double integral RNN design formula is proposed for solving continuous time‐varying matrix inversion, which has incomparable disturbance‐suppression property. For digital hardware applications, the corresponding advanced discrete‐time RNN model is proposed based on the discretisation formulas. As a result of theoretical analysis, it is demonstrated that the advanced continuous‐time RNN model and the corresponding advanced discrete‐time RNN model have global and exponential convergence performance, and they are excellent for suppressing different disturbances. Finally, inspiring experiments, including two numerical experiments and a practical experiment, are presented to demonstrate the effectiveness and superiority of the advanced discrete‐time RNN model for solving discrete time‐varying matrix inversion with disturbance‐suppression.

Published

2023

16. Simultaneous Sensing and Actuating Capabilities of a Triple-Layer Biomimetic Muscle for Soft Robotics.

Author

García-Córdova, Francisco, Guerrero-González, Antonio, Zueco, Joaquín, and Cabrera-Lozoya, Andrés

Subjects

*BIOMIMETIC materials, *SOFT robotics, *CURRENT density (Electromagnetism), *ELECTRIC charge, *ANGULAR velocity

Abstract

This work presents the fabrication and characterization of a triple-layered biomimetic muscle constituted by polypyrrole (PPy)-dodecylbenzenesulfonate (DBS)/adhesive tape/PPy-DBS demonstrating simultaneous sensing and actuation capabilities. The muscle was controlled by a neurobiologically inspired cortical neural network sending agonist and antagonist signals to the conducting polymeric layers. Experiments consisted of controlled voluntary movements of the free end of the muscle at angles of ±20°, ±30°, and ±40° while monitoring the muscle's potential response. Results show the muscle's potential varies linearly with applied current amplitude during actuation, enabling current sensing. A linear dependence between muscle potential and temperature enabled temperature sensing. Electrolyte concentration changes also induced exponential variations in the muscle's potential, allowing for concentration sensing. Additionally, the influence of the electric current density on the angular velocity, the electric charge density, and the desired angle was studied. Overall, the conducting polymer-based soft biomimetic muscle replicates properties of natural muscles, permitting simultaneous motion control, current, temperature, and concentration sensing. The integrated neural control system exhibits key features of biological motion regulation. This muscle actuator with its integrated sensing and control represents an advance for soft robotics, prosthetics, and biomedical devices requiring biomimetic multifunctionality. [ABSTRACT FROM AUTHOR]

Published

2023

17. Hybrid learning mechanisms under a neural control network for various walking speed generation of a quadruped robot.

Author

Zhang, Yanbin, Thor, Mathias, Dilokthanakul, Nat, Dai, Zhendong, and Manoonpong, Poramate

Subjects

*WALKING speed, *BLENDED learning, *CENTRAL pattern generators, *MOTOR learning, *RADIAL basis functions, *MACHINE learning, *FITNESS walking

Abstract

Legged robots that can instantly change motor patterns at different walking speeds are useful and can accomplish various tasks efficiently. However, state-of-the-art control methods either are difficult to develop or require long training times. In this study, we present a comprehensible neural control framework to integrate probability-based black-box optimization (PI BB) and supervised learning for robot motor pattern generation at various walking speeds. The control framework structure is based on a combination of a central pattern generator (CPG), a radial basis function (RBF) -based premotor network and a hypernetwork, resulting in a so-called neural CPG-RBF-hyper control network. First, the CPG-driven RBF network, acting as a complex motor pattern generator, was trained to learn policies (multiple motor patterns) for different speeds using PI BB. We also introduce an incremental learning strategy to avoid local optima. Second, the hypernetwork, which acts as a task/behavior to control parameter mapping, was trained using supervised learning. It creates a mapping between the internal CPG frequency (reflecting the walking speed) and motor behavior. This map represents the prior knowledge of the robot, which contains the optimal motor joint patterns at various CPG frequencies. Finally, when a user-defined robot walking frequency or speed is provided, the hypernetwork generates the corresponding policy for the CPG-RBF network. The result is a versatile locomotion controller which enables a quadruped robot to perform stable and robust walking at different speeds without sensory feedback. The policy of the controller was trained in the simulation (less than 1 h) and capable of transferring to a real robot. The generalization ability of the controller was demonstrated by testing the CPG frequencies that were not encountered during training. [ABSTRACT FROM AUTHOR]

Published

2023

18. An advanced discrete‐time RNN for handling discrete time‐varying matrix inversion: Form model design to disturbance‐suppression analysis.

Author

Shi, Yang, Shi, Qiaowen, Cao, Xinwei, Li, Bin, Sun, Xiaobing, and Gerontitis, Dimitrios K.

Abstract

Time‐varying matrix inversion is an important field of matrix research, and lots of research achievements have been obtained. In the process of solving time‐varying matrix inversion, disturbances inevitably exist, thus, a model that can suppress disturbance while solving the problem is required. In this paper, an advanced continuous‐time recurrent neural network (RNN) model based on a double integral RNN design formula is proposed for solving continuous time‐varying matrix inversion, which has incomparable disturbance‐suppression property. For digital hardware applications, the corresponding advanced discrete‐time RNN model is proposed based on the discretisation formulas. As a result of theoretical analysis, it is demonstrated that the advanced continuous‐time RNN model and the corresponding advanced discrete‐time RNN model have global and exponential convergence performance, and they are excellent for suppressing different disturbances. Finally, inspiring experiments, including two numerical experiments and a practical experiment, are presented to demonstrate the effectiveness and superiority of the advanced discrete‐time RNN model for solving discrete time‐varying matrix inversion with disturbance‐suppression. [ABSTRACT FROM AUTHOR]

Published

2023

19. Self‐Organized Stick Insect‐Like Locomotion under Decentralized Adaptive Neural Control: From Biological Investigation to Robot Simulation.

Author

Larsen, Alexander Dupond, Büscher, Thies H., Chuthong, Thirawat, Pairam, Thipawan, Bethge, Hendrik, Gorb, Stanislav N., and Manoonpong, Poramate

Subjects

*ADAPTIVE control systems, *PHASMIDA, *INSECT locomotion, *PREMOTOR cortex, *RADIAL basis functions, *PHASE modulation, *ROBOTS

Abstract

Living animals and legged robots share similar challenges for movement control. In particular, the investigation of neural control mechanisms for the self‐organized locomotion of insects and hexapod robots can be informative for other fields. The Annam stick insect Medauroidea extradentata is used as a template to develop a biorobotic model to infer walking self‐organization with strongly heterogeneous leg lengths. Body dimensions and data on the walking dynamics of the actual stick insect are used for the development of a neural control mechanism, generating self‐organized gait patterns that correspond to the real insect observations. The combination of both investigations not only proposes solutions for distributed neural locomotion control but also enables insights into the neural equipment of the biological template. Decentralized neural central pattern generation is utilized with phase modulation based on foot contact feedback to generate adaptive periodic base patterns and a radial basis function premotor network in each leg based on the target trajectories of actual stick insect legs during walking for complex intralimb coordination and self‐organized interlimb coordination control. Furthermore, based on both study objects, a robot with heterogeneous leg lengths is constructed to preliminary validate the findings from the simulations and real insect observations. [ABSTRACT FROM AUTHOR]

Published

2023

20. Combining Neurocognitive and Functional Tests to Improve Return-to-Sport Decisions Following ACL Reconstruction.

Author

GROOMS, DUSTIN R., CHAPUT, MEREDITH, SIMON, JANET E., CRISS, CODY R., MYER, GREGORY D., and DIEKFUSS, JED A.

Abstract

Neuroplasticity after anterior cruciate ligament (ACL) injury alters how the nervous system generates movement and maintains dynamic joint stability. The postinjury neuroplasticity can cause neural compensations that increase reliance on neurocognition. Return-to-sport testing quantifies physical function but fails to detect important neural compensations. To assess for neural compensations in a clinical setting, we recommend evaluating athletes' neurocognitive reliance by augmenting return-to-sport testing with combined neurocognitive and motor dual-task challenges. In this Viewpoint, we (1) share the latest evidence related to ACL injury neuroplasticity and (2) share simple principles and new assessments with preliminary data to improve return-to-sport decisions following ACL reconstruction. [ABSTRACT FROM AUTHOR]

Published

2023

21. Effects of a high salt diet on blood pressure dipping and the implications on hypertension.

Author

Viggiano, Jesse, Coutinho, Dominic, Clark-Cutaia, Maya N., and Martinez, Diana

Subjects

HIGH-salt diet, BLOOD pressure, HYPERTENSION, SYMPATHETIC nervous system, SOLITARY nucleus

Abstract

High blood pressure, also known as hypertension, is a major risk factor for cardiovascular disease. Salt intake has been shown to have a significant impact on BP, but the mechanisms by which it influences the blood pressure dipping pattern, and 24-h blood pressure remains controversial. This literature review aims to both summarize the current evidence on high salt diet induced hypertension and discuss the epidemiological aspects including socioeconomic issues in the United States and abroad. Our review indicates that a high salt diet is associated with a blunted nocturnal blood pressure dipping pattern, which is characterized by a reduced decrease in blood pressure during the nighttime hours. The mechanisms by which high salt intake affects blood pressure dipping patterns are not fully understood, but it is suggested that it may be related to changes in the sympathetic nervous system. Further, we looked at the association between major blood pressure and circadian rhythm regulatory centers in the brain, including the paraventricular nucleus (PVN), suprachiasmatic nucleus (SCN) and nucleus tractus solitarius (nTS). We also discuss the underlying social and economic issues in the United States and around the world. In conclusion, the evidence suggests that a high salt diet is associated with a blunted, non-dipping, or reverse dipping blood pressure pattern, which has been shown to increase the risk of cardiovascular disease. Further research is needed to better understand the underlying mechanisms by which high salt intake influences changes within the central nervous system. [ABSTRACT FROM AUTHOR]

Published

2023

22. A Systematic Review on Functional Near-Infrared Spectroscopy Concurrent With Quantitative Balance Assessment

Author

Yasaman Baradaran, Raul Fernandez Rojas, Roland Goecke, and Maryam Ghahramani

Subjects

Cerebral haemodynamics, cortical oxygenation, locomotion, neural control, postural control, stability, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Functional near-infrared spectroscopy (fNIRS) can be used to study activity patterns in different brain cortical areas involved in balance control. This systematic review aims to report on studies in which balance performance has been quantitatively assessed concurrent with fNIRS neuroimaging. Following the PRISMA guidelines, relevant keywords were used for the search through the Scopus and Web of Science databases. Sixty-eight studies met the inclusion criteria and were imported for data extraction. Information on balance assessment protocols, alterations to the balance control loop, brain regions of interest, fNIRS parameters, the relationships found between brain activity and balance performance, and participant cohort types was extracted. The common balance tasks in fNIRS studies were standing and walking. Standing balance control was mainly measured through sway parameters using force platforms. Walking performance was evaluated through gait parameters mostly assessed by floor sensors or inertial sensors. Some of the balance tasks were challenged through sensory manipulation or dual task interference. Brain activity monitoring via fNIRS was mainly utilized to measure oxygenated haemoglobin concentration in frontal cortex. Out of the 68 included articles, 22 studies investigated and found the relationships between activity patterns in different cortical areas and balance measures. In 32 studies, the effects of different factors such as long-term, biological, and psychological conditions on brain activity and balance performance were studied. This study provides a systematic review on fNIRS studies in which quantitative balance assessment is employed to provide a better understanding of neuromotor control of balance.

Published

2023

23. Exploiting Structures in Weight Matrices for Efficient Real-Time Drone Control with Neural Networks

Author

Kissel, Matthias, Gronauer, Sven, Korte, Mathias, Sacchetto, Luca, Diepold, Klaus, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Marreiros, Goreti, editor, Martins, Bruno, editor, Paiva, Ana, editor, Ribeiro, Bernardete, editor, and Sardinha, Alberto, editor

Published

2022

24. Adaptive Neural Back-Stepping Control with Prescribed Performance for Air-Breathing Hypersonic Vehicles

Author

Wang, Pengfei, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Panigrahi, Bijaya Ketan, Series Editor, Chakraborty, Samarjit, Series Editor, Chen, Jiming, Series Editor, Chen, Shanben, Series Editor, Chen, Tan Kay, Series Editor, Dillmann, Rüdiger, Series Editor, Duan, Haibin, Series Editor, Ferrari, Gianluigi, Series Editor, Ferre, Manuel, Series Editor, Hirche, Sandra, Series Editor, Jabbari, Faryar, Series Editor, Jia, Limin, Series Editor, Kacprzyk, Janusz, Series Editor, Khamis, Alaa, Series Editor, Kroeger, Torsten, Series Editor, Liang, Qilian, Series Editor, Martín, Ferran, Series Editor, Ming, Tan Cher, Series Editor, Minker, Wolfgang, Series Editor, Misra, Pradeep, Series Editor, Möller, Sebastian, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Pascucci, Federica, Series Editor, Qin, Yong, Series Editor, Seng, Gan Woon, Series Editor, Speidel, Joachim, Series Editor, Veiga, Germano, Series Editor, Wu, Haitao, Series Editor, Zhang, Junjie James, Series Editor, Yan, Liang, editor, and Yu, Xiang, editor

Published

2022

25. Effects of a high salt diet on blood pressure dipping and the implications on hypertension

Author

Jesse Viggiano, Dominic Coutinho, Maya N. Clark-Cutaia, and Diana Martinez

Subjects

hypertension, neural control, circadian blood pressure, baroreflex, nucleus of solitary tract, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

High blood pressure, also known as hypertension, is a major risk factor for cardiovascular disease. Salt intake has been shown to have a significant impact on BP, but the mechanisms by which it influences the blood pressure dipping pattern, and 24-h blood pressure remains controversial. This literature review aims to both summarize the current evidence on high salt diet induced hypertension and discuss the epidemiological aspects including socioeconomic issues in the United States and abroad. Our review indicates that a high salt diet is associated with a blunted nocturnal blood pressure dipping pattern, which is characterized by a reduced decrease in blood pressure during the nighttime hours. The mechanisms by which high salt intake affects blood pressure dipping patterns are not fully understood, but it is suggested that it may be related to changes in the sympathetic nervous system. Further, we looked at the association between major blood pressure and circadian rhythm regulatory centers in the brain, including the paraventricular nucleus (PVN), suprachiasmatic nucleus (SCN) and nucleus tractus solitarius (nTS). We also discuss the underlying social and economic issues in the United States and around the world. In conclusion, the evidence suggests that a high salt diet is associated with a blunted, non-dipping, or reverse dipping blood pressure pattern, which has been shown to increase the risk of cardiovascular disease. Further research is needed to better understand the underlying mechanisms by which high salt intake influences changes within the central nervous system.

Published

2023

26. Editorial: Focus on methods: neural algorithms for bio-inspired robotics

Author

Luca Patanè and Guoping Zhao

Subjects

neural control, bio-robotics, biological signal processing, machine learning, intelligent machines, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2023

27. System of Implantable Electrodes for Neural Signal Acquisition and Stimulation for Wirelessly Connected Forearm Prosthesis

Author

Octavian Narcis Ionescu, Eduard Franti, Vlad Carbunaru, Carmen Moldovan, Silviu Dinulescu, Marian Ion, David Catalin Dragomir, Carmen Marinela Mihailescu, Ioan Lascar, Ana Maria Oproiu, Tiberiu Paul Neagu, Ruxandra Costea, Monica Dascalu, Mihai Daniel Teleanu, Gabriela Ionescu, and Raluca Teleanu

Subjects

plug electrodes, selective acquisition, nerve pulses, forearm prosthesis, neural control, Biotechnology, TP248.13-248.65

Abstract

There is great interest in the development of prosthetic limbs capable of complex activities that are wirelessly connected to the patient’s neural system. Although some progress has been achieved in this area, one of the main problems encountered is the selective acquisition of nerve impulses and the closing of the automation loop through the selective stimulation of the sensitive branches of the patient. Large-scale research and development have achieved so-called “cuff electrodes”; however, they present a big disadvantage: they are not selective. In this article, we present the progress made in the development of an implantable system of plug neural microelectrodes that relate to the biological nerve tissue and can be used for the selective acquisition of neuronal signals and for the stimulation of specific nerve fascicles. The developed plug electrodes are also advantageous due to their small thickness, as they do not trigger nerve inflammation. In addition, the results of the conducted tests on a sous scrofa subject are presented.

Published

2024

28. Intelligent vehicle lateral control based on radial basis function neural network sliding mode controller

Author

Bailin Fan, Yi Zhang, Ye Chen, and Linbei Meng

Subjects

artificial neural network, neural control, Computational linguistics. Natural language processing, P98-98.5, Computer software, QA76.75-76.765

Abstract

Abstract Based on the predigestion of the dynamic model of the intelligent firefighting vehicle, a linear 2‐DOF lateral dynamic model and a preview error model are established. To solve the problems of a highly non‐linear vehicle model, time‐varying parameters, output chattering, and poor robustness, the Radial Basis Function neural network sliding mode controller is designed. Then, different driving speeds are used to conduct simulation tests under standard double‐shifting and smooth curve road conditions, and the simulation results are used to analyse the tracking effect of the lateral motion controller on the desired path. The simulation results reveal that the controller designed has high accuracy in tracking the desired path and has good robustness to the disturbance of intelligent firefighting vehicle speed changes.

Published

2022

29. Robust and reusable self-organized locomotion of legged robots under adaptive physical and neural communications.

Author

Tao Sun, Zhendong Dai, and Poramate Manoonpong

Subjects

GAIT in humans, CENTRAL pattern generators, ADAPTIVE control systems, ROBOTS, WALKING speed, NEURAL circuitry

Abstract

Introduction: Animals such as cattle can achieve versatile and elegant behaviors through automatic sensorimotor coordination. Their self-organized movements convey an impression of adaptability, robustness, and motor memory. However, the adaptive mechanisms underlying such natural abilities of these animals have not been completely realized in artificial legged systems. Methods: Hence, we propose adaptive neural control that can mimic these abilities through adaptive physical and neural communications. The control algorithm consists of distributed local central pattern generator (CPG)-based neural circuits for generating basic leg movements, an adaptive sensory feedback mechanism for generating self-organized phase relationships among the local CPG circuits, and an adaptive neural coupling mechanism for transferring and storing the formed phase relationships (a gait pattern) into the neural structure. The adaptive neural control was evaluated in experiments using a quadruped robot. Results: The adaptive neural control enabled the robot to 1) rapidly and automatically form its gait (i.e., self-organized locomotion) within a few seconds, 2) memorize the gait for later recovery, and 3) robustly walk, even when a sensory feedback malfunction occurs. It also enabled maneuverability, with the robot being able to change its walking speed and direction. Moreover, implementing adaptive physical and neural communications provided an opportunity for understanding the mechanism of motor memory formation. Discussion: Overall, this study demonstrates that the integration of the two forms of communications through adaptive neural control is a powerful way to achieve robust and reusable self-organized locomotion in legged robots. [ABSTRACT FROM AUTHOR]

Published

2023

30. Simultaneous Sensing and Actuating Capabilities of a Triple-Layer Biomimetic Muscle for Soft Robotics

Author

Francisco García-Córdova, Antonio Guerrero-González, Joaquín Zueco, and Andrés Cabrera-Lozoya

Subjects

conducting polymers, biomimetic, artificial muscles, soft actuators, neural control, Chemical technology, TP1-1185

Abstract

This work presents the fabrication and characterization of a triple-layered biomimetic muscle constituted by polypyrrole (PPy)-dodecylbenzenesulfonate (DBS)/adhesive tape/PPy-DBS demonstrating simultaneous sensing and actuation capabilities. The muscle was controlled by a neurobiologically inspired cortical neural network sending agonist and antagonist signals to the conducting polymeric layers. Experiments consisted of controlled voluntary movements of the free end of the muscle at angles of ±20°, ±30°, and ±40° while monitoring the muscle’s potential response. Results show the muscle’s potential varies linearly with applied current amplitude during actuation, enabling current sensing. A linear dependence between muscle potential and temperature enabled temperature sensing. Electrolyte concentration changes also induced exponential variations in the muscle’s potential, allowing for concentration sensing. Additionally, the influence of the electric current density on the angular velocity, the electric charge density, and the desired angle was studied. Overall, the conducting polymer-based soft biomimetic muscle replicates properties of natural muscles, permitting simultaneous motion control, current, temperature, and concentration sensing. The integrated neural control system exhibits key features of biological motion regulation. This muscle actuator with its integrated sensing and control represents an advance for soft robotics, prosthetics, and biomedical devices requiring biomimetic multifunctionality.

Published

2023

31. Research on Virtual Training System for Intelligent Upper Limb Prosthesis with Bidirectional Neural Channels

Author

Hu, Yawen, Jiang, Li, Yang, Bin, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Liu, Xin-Jun, editor, Nie, Zhenguo, editor, Yu, Jingjun, editor, Xie, Fugui, editor, and Song, Rui, editor

Published

2021

32. Teaching Neural Control with an Arduino Based Control Kit

Author

Barbosa, Ramiro S., Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Panigrahi, Bijaya Ketan, Series Editor, Chakraborty, Samarjit, Series Editor, Chen, Jiming, Series Editor, Chen, Shanben, Series Editor, Chen, Tan Kay, Series Editor, Dillmann, Rüdiger, Series Editor, Duan, Haibin, Series Editor, Ferrari, Gianluigi, Series Editor, Ferre, Manuel, Series Editor, Hirche, Sandra, Series Editor, Jabbari, Faryar, Series Editor, Jia, Limin, Series Editor, Kacprzyk, Janusz, Series Editor, Khamis, Alaa, Series Editor, Kroeger, Torsten, Series Editor, Liang, Qilian, Series Editor, Martín, Ferran, Series Editor, Ming, Tan Cher, Series Editor, Minker, Wolfgang, Series Editor, Misra, Pradeep, Series Editor, Möller, Sebastian, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Pascucci, Federica, Series Editor, Qin, Yong, Series Editor, Seng, Gan Woon, Series Editor, Speidel, Joachim, Series Editor, Veiga, Germano, Series Editor, Wu, Haitao, Series Editor, Zhang, Junjie James, Series Editor, Gonçalves, José Alexandre, editor, Braz-César, Manuel, editor, and Coelho, João Paulo, editor

Published

2021

33. Neural Control Based Research of Endogenous Security Model

Author

Li, Tao, Hu, Xu, Hu, Aiqun, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Sun, Xingming, editor, Zhang, Xiaorui, editor, and Xia, Zhihua, editor

Published

2021

34. The Pelvic Floor: Neurocontrol and Functional Concepts

Author

Swash, Michael, Petros, Peter, Santoro, Giulio A., editor, Wieczorek, Andrzej P., editor, and Sultan, Abdul H., editor

Published

2021

35. Event-based iterative neural control for a type of discrete dynamic plant

Author

Ding WANG

Subjects

iterative adaptive critic, neural control, event-based design, intelligent control, nonlinear dynamics, optimal control, Mining engineering. Metallurgy, TN1-997, Environmental engineering, TA170-171

Abstract

With the widespread popularity of network-based techniques and extension of computer control scales, more dynamical systems, particularly complex nonlinear dynamics, including increasing communication burdens, increasing difficulties in building accurate mathematical models, and different uncertain factors are encountered. Consequently, in contrast to the linear case, the optimization of the design of these uncertain complex systems is difficult to achieve. By combining reinforcement learning, neural networks, and dynamic programming, the adaptive critic method is regarded as an advanced approach to address intelligent control problems. The adaptive critic method has been currently used to solve the optimal regulation, trajectory tracking, robust control, disturbance attenuation, and zero-sum game problems. It has been considered a promising direction within the artificial intelligence field. However, many traditional design processes of the adaptive critic method are conducted based on the time-based mechanism, where the control signals are updated at each time step. Thus, the related control efficiencies are often low, which results in poor performance when considering practical updating times. Hence, more improvements are needed to enhance the control efficiency of adaptive-critic-based nonlinear control design. In this study, we developed an event-based iterative neural control framework for discrete-time nonlinear dynamics. The iterative adaptive critic method was combined with the event-driven mechanism to address the approximate optimal regulation problem in discrete-time nonlinear plants. An event-triggered value learning strategy was established with two iterative sequences. The convergence analysis of the iterative algorithm and the neural network implementation of the new framework were presented in detail. Therein, the heuristic dynamic programming technique was employed under the event-based iterative environment. Moreover, the triggering condition of the event-driven approach was determined with the appropriate threshold. Finally, simulation examples were provided to illustrate the excellent control performance, particularly in utilizing the communication resource. Thus, constructing a class of intelligent control systems based on the event-based mechanism will be helpful.

Published

2022

36. Optimization of energy and time predicts dynamic speeds for human walking

Author

Rebecca Elizabeth Carlisle and Arthur D Kuo

Subjects

biomechanics, human physiology, metabolic cost, locomotion, neural control, optimal control, Medicine, Science, Biology (General), QH301-705.5

Abstract

Humans make a number of choices when they walk, such as how fast and for how long. The preferred steady walking speed seems chosen to minimize energy expenditure per distance traveled. But the speed of actual walking bouts is not only steady, but rather a time-varying trajectory, which can also be modulated by task urgency or an individual’s movement vigor. Here we show that speed trajectories and durations of human walking bouts are explained better by an objective to minimize Energy and Time, meaning the total work or energy to reach destination, plus a cost proportional to bout duration. Applied to a computational model of walking dynamics, this objective predicts dynamic speed vs. time trajectories with inverted U shapes. Model and human experiment (N=10) show that shorter bouts are unsteady and dominated by the time and effort of accelerating, and longer ones are steadier and faster and dominated by steady-state time and effort. Individual-dependent vigor may be characterized by the energy one is willing to spend to save a unit of time, which explains why some may walk faster than others, but everyone may have similar-shaped trajectories due to similar walking dynamics. Tradeoffs between energy and time costs can predict transient, steady, and vigor-related aspects of walking.

Published

2023

37. Editorial: Focus on methods: neural algorithms for bio-inspired robotics.

Author

Patanè, Luca and Guoping Zhao

Subjects

BIOLOGICALLY inspired computing, ROBOTICS, ALGORITHMS, ARTIFICIAL intelligence, SIGNAL processing, MACHINE learning

Published

2023

38. No Need for Landmarks: An Embodied Neural Controller for Robust Insect-Like Navigation Behaviors.

Author

Xiong, Xiaofeng and Manoonpong, Poramate

Abstract

Bayesian filters have been considered to help refine and develop theoretical views on spatial cell functions for self-localization. However, extending a Bayesian filter to reproduce insect-like navigation behaviors (e.g., home searching) remains an open and challenging problem. To address this problem, we propose an embodied neural controller for self-localization, foraging, backward homing (BH), and home searching of an advanced mobility sensor (AMOS)-driven insect-like robot. The controller, comprising a navigation module for the Bayesian self-localization and goal-directed control of AMOS and a locomotion module for coordinating the 18 joints of AMOS, leads to its robust insect-like navigation behaviors. As a result, the proposed controller enables AMOS to perform robust foraging, BH, and home searching against various levels of sensory noise, compared to conventional controllers. Its implementation relies only on self-localization and heading perception, rather than global positioning and landmark guidance. Interestingly, the proposed controller makes AMOS achieve spiral searching patterns comparable to those performed by real insects. We also demonstrated the performance of the controller for real-time indoor and outdoor navigation in a real insect-like robot without any landmark and cognitive map. [ABSTRACT FROM AUTHOR]

Published

2022

39. Central Feminization of Obese Male Mice Reduces Metabolic Syndrome.

Author

Blackmore, Katherine and Young, Colin N.

Subjects

*WEIGHT loss, *METABOLIC syndrome, *FATTY liver, *HEPATOMEGALY, *BROWN adipose tissue, *OBESITY, *TRANSGENDER people

Abstract

Metabolic syndrome encompasses a spectrum of conditions that increases the risk for cardiovascular and metabolic diseases. It is widely accepted that the sex hormone estrogen plays a protective metabolic role in premenopausal women, in part through central nervous system (CNS) mechanisms. However, most work to date has focused on the loss of estrogen in females (e.g., menopause). Interestingly, transgender individuals receiving feminizing gender affirming therapy (i.e., estrogen) are relatively protected from metabolic syndrome conditions, pointing to a role for CNS estrogen in the development of metabolic syndrome in men. Here, we show that estrogen signaling in the brain protects males from metabolic syndrome and obesity related complications. First, short-term CNS specific supplementation of low-dose 17-β-estradiol in diet-induced obese male mice resulted in a significant reduction in body weight in parallel with a decrease in food intake without alterations in energy expenditure. In conjunction, central supplementation of estrogen reduced visceral adiposity, including epididymal and abdominal regions, with slighter decreases in subcutaneous inguinal and thermogenic brown adipose tissue. Furthermore, central estrogen administration reduced the liver manifestation of metabolic syndrome including hepatomegaly and hepatic steatosis. Collectively, these findings indicate that a lack of estrogen action in the brain may predispose males to metabolic syndrome pathogenesis. [ABSTRACT FROM AUTHOR]

Published

2022

40. Muscle-driven predictive physics simulations of quadrupedal locomotion in the horse

Author

Bijlert, P. (Pasha) van, Geijtenbeek, Thomas, Smit, Ineke H, Schulp, A. (Anne), Bates, Karl T, Bijlert, P. (Pasha) van, Geijtenbeek, Thomas, Smit, Ineke H, Schulp, A. (Anne), and Bates, Karl T

Abstract

Musculoskeletal simulations can provide insights into the underlying mechanisms that govern animal locomotion. In this study, we describe the development of a new musculoskeletal model of the horse, and to our knowledge present the first fully muscle-driven, predictive simulations of equine locomotion. Our goal was to simulate a model that captures only the gross musculoskeletal structure of a horse, without specialized morphological features. We mostly present simulations acquired using feedforward control, without state feedback (“top-down control”). Without using kinematics or motion capture data as an input, we have simulated a variety of gaits that are commonly used by horses (walk, pace, trot, tölt, and collected gallop). We also found a selection of gaits that are not normally seen in horses (half bound, extended gallop, ambling). Due to the clinical relevance of the trot, we performed a tracking simulation that included empirical joint angle deviations in the cost function. To further demonstrate the flexibility of our model, we also present a simulation acquired using spinal feedback control, where muscle control signals are wholly determined by gait kinematics. Despite simplifications to the musculature, simulated footfalls and ground reaction forces followed empirical patterns. In the tracking simulation, kinematics improved with respect to the fully predictive simulations, and muscle activations showed a reasonable correspondence to electromyographic signals, although we did not predict any anticipatory firing of muscles. When sequentially increasing the target speed, our simulations spontaneously predicted walk-to-run transitions at the empirically determined speed. However, predicted stride lengths were too short over nearly the entire speed range unless explicitly prescribed in the controller, and we also did not recover spontaneous transitions to asymmetric gaits such as galloping. Taken together, our model performed adequately when simulating indivi

Published

2024

41. Predictive simulations identify potential neuromuscular contributors to idiopathic toe walking

Author

Veerkamp, Kirsten (author), van der Krogt, Marjolein M. (author), Waterval, Niels F.J. (author), Geijtenbeek, T. (author), Walsh, H. P.John (author), Harlaar, J. (author), Buizer, Annemieke I. (author), Lloyd, David G. (author), Carty, Christopher P. (author), Veerkamp, Kirsten (author), van der Krogt, Marjolein M. (author), Waterval, Niels F.J. (author), Geijtenbeek, T. (author), Walsh, H. P.John (author), Harlaar, J. (author), Buizer, Annemieke I. (author), Lloyd, David G. (author), and Carty, Christopher P. (author)

Abstract

Background: Most cases of toe walking in children are idiopathic. We used pathology-specific neuromusculoskeletal predictive simulations to identify potential underlying neural and muscular mechanisms contributing to idiopathic toe walking. Methods: A musculotendon contracture was added to the ankle plantarflexors of a generic musculoskeletal model to represent a pathology-specific contracture model, matching the reduced ankle dorsiflexion range-of-motion in a cohort of children with idiopathic toe walking. This model was employed in a forward dynamic simulation controlled by reflexes and supraspinal drive, governed by a multi-objective cost function to predict gait patterns with the contracture model. We validated the predicted gait using experimental gait data from children with idiopathic toe walking with ankle contracture, by calculating the root mean square errors averaged over all biomechanical variables. Findings: A predictive simulation with the pathology-specific model with contracture approached experimental ITW data (root mean square error = 1.37SD). Gastrocnemius activation was doubled from typical gait simulations, but lacked a peak in early stance as present in electromyography. This synthesised idiopathic toe walking was more costly for all cost function criteria than typical gait simulation. Also, it employed a different neural control strategy, with increased length- and velocity-based reflex gains to the plantarflexors in early stance and swing than typical gait simulations. Interpretation: The simulations provide insights into how a musculotendon contracture combined with altered neural control could contribute to idiopathic toe walking. Insights into these neuromuscular mechanisms could guide future computational and experimental studies to gain improved insight into the cause of idiopathic toe walking., Biomechatronics & Human-Machine Control

Published

2024

42. Frequency-domain patterns in foot-force line-of-action: an emergent property of standing balance control.

Author

Sugimoto-Dimitrova R, Shiozawa K, Gruben KG, and Hogan N

Subjects

Humans, Biomechanical Phenomena physiology, Male, Adult, Models, Biological, Female, Postural Balance physiology, Foot physiology, Standing Position

Abstract

A recent line of work suggests that the net behavior of the foot-ground interaction force provides insight into quiet-standing-balance dynamics and control. Through human-subject experiments, Boehm et al. found that the relative variations of the center of pressure and force orientation emerge as a distinct pattern in the frequency domain, termed the "intersection-point (IP) height." Subsequent empirical and simulation-based studies showed that different control strategies are reflected in the distribution of intersection-point height across frequency. To facilitate understanding of the strengths and limitations of the intersection-point height in describing the dynamics and control of standing, the present work establishes a spectral-based method that also enables derivation of a closed-form estimate of the intersection-point height from any linear model of quiet stance. This new method explained observations from prior work, including how the measure captures aspects of control and physiological noise. The analysis presented herein highlights the utility of the frequency-dependent foot-force dynamics in probing the balance controller and provides a tool for model development and validation to further our understanding of the neuromotor control of natural upright posture in humans. NEW & NOTEWORTHY The present work details a closed-form analytical result that reveals a direct link between frequency-domain patterns in the foot-force line-of-action and the closed-loop frequency response function of human upright stance. The analytical method developed herein dramatically simplifies the identification of the intersection-point-height measure of standing balance, and further demonstrates that the net behavior of the foot-ground interaction force quantifies essential characteristics of the underlying neuromotor control of human quiet standing.

Published

2024

43. Human foot force suggests different balance control between younger and older adults.

Author

Shiozawa K, Sugimoto-Dimitrova R, Gruben KG, and Hogan N

Subjects

Humans, Male, Middle Aged, Female, Adult, Aged, Biomechanical Phenomena physiology, Young Adult, Ankle Joint physiology, Postural Balance physiology, Foot physiology, Aging physiology

Abstract

Aging can cause the decline of balance ability, which can lead to increased falls and decreased mobility. This work aimed to discern differences in balance control between healthy older and younger adults. Foot force data of 38 older and 65 younger participants (older and younger than 60 yr, respectively) were analyzed. To first determine whether the two groups exhibited any differences, this study incorporated the orientation of the foot-ground interaction force in addition to its point of application. Specifically, the frequency dependence of the "intersection point" of the lines of actions of the foot-ground interaction forces was evaluated. Results demonstrated that, like the mean center-of-pressure speed, a traditionally employed measure, the intersection-point analysis could distinguish between the two participant groups. Then, to further explore age-specific control strategies, simulations of standing balance were conducted. An optimal controller stabilized a double-inverted-pendulum model with torque-actuated ankle and hip joints corrupted with white noise. The experimental data were compared with the simulation results to identify the controller parameters that best described the human data. Older participants showed significantly more use of the ankle than hip compared with younger participants. Best-fit controller gains suggested increased preference for asymmetric inter-joint neural feedback, possibly to compensate for the effects of aging such as sarcopenia. These results underscore the advantages of the intersection-point analysis to quantify possible shifts in inter-joint control with age, thus highlighting its potential to be used as a balance assessment tool in research and clinical settings. NEW & NOTEWORTHY Age groups were distinguished by analyzing foot-ground force data during quiet standing in older and younger adults to calculate the foot-force vector intersection point that emerges across frequency bands. Modeling balance and comparing the simulations' outcomes to experimental results suggested that older adults increased reliance on neural feedback, possibly compensating for muscle strength deficiency. This novel analysis also quantified the apparent balance controller for each participant, highlighting its potential as a balance assessment tool.

Published

2024

44. Intelligent Motion Tracking Control of Vehicle Suspension Systems With Constraints via Neural Performance Analysis.

Author

Liu, Lei, Zhu, Changqi, Liu, Yan-Jun, and Tong, Shaocheng

Abstract

A novel adaptive control scheme is developed for active suspension systems (ASSs) based on neural networks (NNs) and backstepping control strategies. Since the springs and piecewise dampers are nonlinear, the unknown internal dynamics are approximated by radial basis function neural networks (RBFNNs). Then, to solve the time-varying constrains of both vertical displacement and corresponding speed in vehicle body, the Tangent Barrier Lyapunov Functions (TBLFs) are incorporated into the controller design. Furthermore, the adaptive controller and adaptive laws are designed to improve the riding comfortable, handling stability and driving safety. In the end, the simulation results show the effectiveness and feasibility of the proposed adaptive algorithm compared with unconstrained adaptive approach. [ABSTRACT FROM AUTHOR]

Published

2022

45. Recent advances in the analysis and control of large populations of neural oscillators.

Author

Wilson, Dan and Moehlis, Jeff

Subjects

*DEEP brain stimulation, *BRAIN waves, *PARKINSON'S disease, *SUBTHALAMIC nucleus, *NEUROLOGICAL disorders

Abstract

Many challenging problems that consider the analysis and control of neural brain rhythms have been motivated by the advent of deep brain stimulation as a therapeutic treatment for a wide variety of neurological disorders. In a computational setting, neural rhythms are often modeled using large populations of coupled, conductance-based neurons. Control of such models comes with a long list of challenges: the underlying dynamics are nonnegligibly nonlinear, high dimensional, and subject to noise; hardware and biological limitations place restrictive constraints on allowable inputs; direct measurement of system observables is generally limited; and the resulting systems are typically highly underactuated. In this review article, we highlight a collection of recent analysis techniques and control frameworks that have been developed to contend with these difficulties. Particular emphasis is placed on the problem of desynchronization for a population of pathologically synchronized neural oscillators, a problem that is motivated by applications to Parkinson's disease where pathological synchronization is thought to contribute to the associated motor control symptoms. We also discuss other recent neural control applications that consider entrainment, phase randomization, synchronization, and clustering. [ABSTRACT FROM AUTHOR]

Published

2022

46. Frequency-dependent force direction elucidates neural control of balance

Author

Kaymie Shiozawa, Jongwoo Lee, Marta Russo, Dagmar Sternad, and Neville Hogan

Subjects

Posture and balance, Inverted pendulum models, Ground reaction forces, Neural control, Biomechanics, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Background Maintaining upright posture is an unstable task that requires sophisticated neuro-muscular control. Humans use foot–ground interaction forces, characterized by point of application, magnitude, and direction to manage body accelerations. When analyzing the directions of the ground reaction forces of standing humans in the frequency domain, previous work found a consistent pattern in different frequency bands. To test whether this frequency-dependent behavior provided a distinctive signature of neural control or was a necessary consequence of biomechanics, this study simulated quiet standing and compared the results with human subject data. Methods Aiming to develop the simplest competent and neuromechanically justifiable dynamic model that could account for the pattern observed across multiple subjects, we first explored the minimum number of degrees of freedom required for the model. Then, we applied a well-established optimal control method that was parameterized to maximize physiologically-relevant insight to stabilize the balancing model. Results If a standing human was modeled as a single inverted pendulum, no controller could reproduce the experimentally observed pattern. The simplest competent model that approximated a standing human was a double inverted pendulum with torque-actuated ankle and hip joints. A range of controller parameters could stabilize this model and reproduce the general trend observed in experimental data; this result seems to indicate a biomechanical constraint and not a consequence of control. However, details of the frequency-dependent pattern varied substantially across tested control parameter values. The set of parameters that best reproduced the human experimental results suggests that the control strategy employed by human subjects to maintain quiet standing was best described by minimal control effort with an emphasis on ankle torque. Conclusions The findings suggest that the frequency-dependent pattern of ground reaction forces observed in quiet standing conveys quantitative information about human control strategies. This study’s method might be extended to investigate human neural control strategies in different contexts of balance, such as with an assistive device or in neurologically impaired subjects.

Published

2021

47. The combined effects of temperature and posture on regional blood flow and haemodynamics.

Author

Fisher, Jason T., Ciuha, Urša, and Mekjavić, Igor B.

Subjects

*BODY temperature, *HEART beat, *BLOOD flow, *CARDIAC output, *SUPINE position, *BARORECEPTORS

Abstract

Under simultaneous ambient temperature and postural stressors, integrated regional blood flow responses are required to maintain blood pressure and thermoregulatory homeostasis. The aim of the present study was to assess the effect of ambient temperature and body posture on regional regulation of microvascular blood flow, specifically in the arms and legs. Participants (N = 11) attended two sessions in which they experienced transient ambient conditions, in a climatic chamber. During each 60-min trial, ambient temperature increased from 15.7 (0.6) °C to 38.9 (0.6) °C followed by a linear decrease, and the participants were either standing or in a supine position throughout the trial; relative humidity in the chamber was maintained at 25.9 (6.6) %. Laser doppler flowmetry of the forearm (SkBF arm) and calf (SkBF calf), and haemodynamic responses (heart rate, HR; stroke volume, SV; cardiac output, CO; blood pressure, BP), were measured continuously. Analyses of heart rate variability and wavelet transform were also conducted. SkBF arm increased significantly at higher ambient temperatures (p = 0.003), but not SkBF calf. The standing posture caused lower overall SkBF in both regions throughout the protocol, regardless of temperature (p < 0.001). HR and BP were significantly elevated, and SV significantly lowered, in response to separate and combined effects of higher ambient temperatures and a standing position (all p < 0.05); CO remained unchanged. Mechanistic analyses identified greater sympathetic nerve activation, and higher calf myogenic activation at peak temperatures, in the standing condition. Mechanistically and functionally, arm vasculature responds to modulation from both thermoregulation and baroreceptor activity. The legs, meanwhile, are more sensitive to baroreflex regulatory mechanisms. • Exposure to combined thermal and postural stressors requires interaction of thermoregulatory and baroreflex responses. • Regional variation in control from thermoregulatory and baroreflex mechanisms may exist in the maintenance of blood flow. • Participants experienced a transient ambient temperature (15.7(0.6) °C - 38.9(0.6)°C), in two seperate postures (upright and supine). • Microvascular blood flow and haemodynamic responses were recorded continuously throughout the protocol. • Arm blood flow increased during the rise in ambient temperature; however both limbs decreased blood flow during standing. • Arm vasculature seems to be regulated by thermoregulatory and baroreflex mechanisms, while the legs are regulated by the baroreflex alone. [ABSTRACT FROM AUTHOR]

Published

2024

48. Whole Body Coordination for Self-Assistance in Locomotion.

Author

Seyfarth, André, Zhao, Guoping, and Jörntell, Henrik

Subjects

HUMAN locomotion, ASSISTIVE technology, HUMAN mechanics, GAIT in humans, CONTROL (Psychology), LEG

Abstract

The dynamics of the human body can be described by the accelerations and masses of the different body parts (e.g., legs, arm, trunk). These body parts can exhibit specific coordination patterns with each other. In human walking, we found that the swing leg cooperates with the upper body and the stance leg in different ways (e.g., in-phase and out-of-phase in vertical and horizontal directions, respectively). Such patterns of self-assistance found in human locomotion could be of advantage in robotics design, in the design of any assistive device for patients with movement impairments. It can also shed light on several unexplained infrastructural features of the CNS motor control. Self-assistance means that distributed parts of the body contribute to an overlay of functions that are required to solve the underlying motor task. To draw advantage of self-assisting effects, precise and balanced spatiotemporal patterns of muscle activation are necessary. We show that the necessary neural connectivity infrastructure to achieve such muscle control exists in abundance in the spinocerebellar circuitry. We discuss how these connectivity patterns of the spinal interneurons appear to be present already perinatally but also likely are learned. We also discuss the importance of these insights into whole body locomotion for the successful design of future assistive devices and the sense of control that they could ideally confer to the user. [ABSTRACT FROM AUTHOR]

Published

2022

49. Bottlenecks, Modularity, and the Neural Control of Behavior.

Author

Nande, Anjalika, Dubinkina, Veronika, Ravasio, Riccardo, Zhang, Grace H., and Berman, Gordon J.

Subjects

INFORMATION storage & retrieval systems, NEURAL circuitry, MODULAR construction, NERVOUS system, KNOWLEDGE transfer

Abstract

In almost all animals, the transfer of information from the brain to the motor circuitry is facilitated by a relatively small number of neurons, leading to a constraint on the amount of information that can be transmitted. Our knowledge of how animals encode information through this pathway, and the consequences of this encoding, however, is limited. In this study, we use a simple feed-forward neural network to investigate the consequences of having such a bottleneck and identify aspects of the network architecture that enable robust information transfer. We are able to explain some recently observed properties of descending neurons—that they exhibit a modular pattern of connectivity and that their excitation leads to consistent alterations in behavior that are often dependent upon the desired behavioral state of the animal. Our model predicts that in the presence of an information bottleneck, such a modular structure is needed to increase the efficiency of the network and to make it more robust to perturbations. However, it does so at the cost of an increase in state-dependent effects. Despite its simplicity, our model is able to provide intuition for the trade-offs faced by the nervous system in the presence of an information processing constraint and makes predictions for future experiments. [ABSTRACT FROM AUTHOR]

Published

2022

50. Modeling and Simulation of a Novel Neural PLL controller for Circuit of Series Resonant Inverter in High Frequency Induction Heating.

Author

BOUADI, Abed, NAIM, Houcine, DELLA KRACHAI, Mohamed, FARES, Radouane, and Bouchiba, Guelta

Subjects

INDUCTION heating, RESONANT inverters, HEATING control, HEATING, PHASE-locked loops, ELECTRIC inverters

Abstract

Copyright of Przegląd Elektrotechniczny is the property of Przeglad Elektrotechniczny and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022