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169 results on '"Masaki Ogura"'

1. Firing pattern manipulation of neuronal networks by deep unfolding‐based model predictive control

Author

Jumpei Aizawa, Masaki Ogura, Masanori Shimono, and Naoki Wakamiya

Subjects
complex networks, control nonlinearities, learning systems, Control engineering systems. Automatic machinery (General), TJ212-225
Abstract

Abstract The complexity of neuronal networks, characterized by interconnected neurons, presents significant challenges in control due to their nonlinear and intricate behaviour. This paper introduces a novel method designed to generate control inputs for neuronal networks to regulate the firing patterns of modules within the network. This methodology is built upon temporal deep unfolding‐based model predictive control, a technique rooted in the deep unfolding method commonly used in wireless signal processing. To address the unique dynamics of neurons, such as zero gradients in firing times, the method employs approximations of input currents using a sigmoid function during its development. The effectiveness of this approach is validated through extensive numerical simulations. Furthermore, control experiments were conducted by reducing the number of input neurons to identify critical features for control. Various selection techniques were utilized to pinpoint key input neurons. These experiments shed light on the importance of specific input neurons in controlling module firing within neuronal networks. Thus, this study presents a tailored methodology for managing networked neurons, extends temporal deep unfolding‐based model predictive control to nonlinear systems with reset dynamics, and demonstrates its ability to achieve desired firing patterns in neuronal networks.

Published
2024
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2. Iterative shepherding control for agents with heterogeneous responsivity

Author

Ryoto Himo, Masaki Ogura, and Naoki Wakamiya

Subjects
shepherding, heterogeneity, farthest-agent targeting, multi-agent systems, Biotechnology, TP248.13-248.65, Mathematics, QA1-939
Abstract

In the context of the theory of multi-agent systems, the shepherding problem refers to designing the dynamics of a herding agent, called a sheepdog, so that a given flock of agents, called sheep, is guided into a goal region. Although several effective methodologies and algorithms have been proposed in the last decade for the shepherding problem under various formulations, little research has been directed to the practically important case in which the flock contains sheep agents unresponsive to the sheepdog agent. To fill in this gap, we propose a sheepdog algorithm for guiding unresponsive sheep in this paper. In the algorithm, the sheepdog iteratively applies an existing shepherding algorithm, the farthest-agent targeting algorithm, while dynamically switching its destination. This procedure achieves the incremental growth of a controllable flock, which finally enables the sheepdog to guide the entire flock into the goal region. Furthermore, we illustrate by numerical simulations that the proposed algorithm can outperform the farthest-agent targeting algorithm.

Published
2022
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3. Temporal deep unfolding for constrained nonlinear stochastic optimal control

Author

Masako Kishida and Masaki Ogura

Subjects
Control engineering systems. Automatic machinery (General), TJ212-225
Abstract

Abstract This paper proposes a computational technique to solve discrete‐time optimal control problems for nonlinear systems subject to stochastic disturbances, hard input constraints, and soft constraints. The approach employs the idea of deep unfolding, which is a recently developed model‐based deep learning method that is applicable to iterative algorithms. By regarding each state transition of the dynamical system as an iteration step, these state transitions are unfolded into the layers of a deep neural network. This produces a computational graph that contains trainable parameters that determine control inputs. These parameters are optimized by training the deep neural network using the standard deep learning technique of backpropagation and incremental training. Then, the optimal control inputs are obtained from the optimized parameters. This provides a way to optimize the control inputs that otherwise would be difficult to obtain. The effectiveness of the proposed technique is demonstrated by numerical experiments for the maximum hands‐off control problem and constrained model predictive control problems using a highly nonlinear model of a continuous stirred tank reactor.

Published
2022
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5. Stability Optimization of Positive Semi-Markov Jump Linear Systems via Convex Optimization

Author

Chengyan Zhao, Masaki Ogura, and Kenji Sugimoto

Subjects
semi-markov jump linear systems, positive systems, stability optimization, convex optimization, bet-hedging population, Control engineering systems. Automatic machinery (General), TJ212-225
Abstract

In this paper, we study the problem of optimizing the stability of positive semi-Markov jump linear systems. We specifically consider the problems of tuning the coefficients of the system matrices for maximizing the exponential decay rate of the system under a budget-constraint and minimizing the parameter tuning cost under the decay rate constraint. By using a result from the matrix theory on the log-log convexity of the spectral radius of nonnegative matrices, we show that the stability optimization problems are reduced to convex optimization problems under certain regularity conditions on the system matrices and the cost function. We illustrate the validity and effectiveness of the proposed results by using an example from the population biology.

Published
2020
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6. Deep Learning-Based Average Consensus

Author

Masako Kishida, Masaki Ogura, Yuichi Yoshida, and Tadashi Wadayama

Subjects
Machine learning, multi-agent systems, networked control systems, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

In this study, we analyzed the problem of accelerating the linear average consensus algorithm for complex networks. We propose a data-driven approach to tuning the weights of temporal (i.e., time-varying) networks using deep learning techniques. Given a finite-time window, the proposed approach first unfolds the linear average consensus protocol to obtain a feedforward signal-flow graph, which is regarded as a neural network. The edge weights of the obtained neural network are then trained using standard deep learning techniques to minimize consensus error over a given finite-time window. Through this training process, we obtain a set of optimized time-varying weights, which yield faster consensus for a complex network. We also demonstrate that the proposed approach can be extended for infinite-time window problems. Numerical experiments revealed that our approach can achieve a significantly smaller consensus error compared to baseline strategies.

Published
2020
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7. Characteristics of aspiration pneumonia patients in acute care hospitals: A multicenter, retrospective survey in Northern Japan.

Author

Jun Suzuki, Ryoukichi Ikeda, Kengo Kato, Risako Kakuta, Yuta Kobayashi, Akira Ohkoshi, Ryo Ishii, Ai Hirano-Kawamoto, Jun Ohta, Rei Kawata, Tomonori Kanbayashi, Masaki Hatano, Tadahisa Shishido, Yuya Miyakura, Kento Ishigaki, Yasunari Yamauchi, Miho Nakazumi, Takuya Endo, Hiroki Tozuka, Shiori Kitaya, Yuki Numano, Shotaro Koizumi, Yutaro Saito, Mutsuki Unuma, Ken Hashimoto, Eiichi Ishida, Toshiaki Kikuchi, Takayuki Kudo, Kenichi Watanabe, Masaki Ogura, Masaru Tateda, Takatsuna Sasaki, Nobuo Ohta, Tatsuma Okazaki, and Yukio Katori

Subjects
Medicine, Science
Abstract

BackgroundPneumonia is a common cause of illness and death of the elderly in Japan. Its prevalence is escalating globally with the aging of population. To describe the latest trends in pneumonia hospitalizations, especially aspiration pneumonia (AP) cases, we assessed the clinical records of pneumonia patients admitted to core acute care hospitals in Miyagi prefecture, Japan.MethodsA retrospective multi-institutional joint research was conducted for hospitalized pneumonia patients aged ≥20 years from January 2019 to December 2019. Clinical data of patients were collected from the medical records of eight acute care hospitals.ResultsOut of the 1,800 patients included in this study, 79% of the hospitalized pneumonia patients were aged above 70 years. The most common age group was in the 80s. The ratio of AP to total pneumonia cases increased with age, and 692 out of 1,800 patients had AP. In univariate analysis, these patients had significantly older ages, lower body mass index (BMI), a lower ratio of normal diet intake and homestay before hospitalization, along with more AP recurrences and comorbidities. During hospitalization, AP patients had extended fasting periods, more swallowing assessments and interventions, longer hospitalization, and higher in-hospital mortality rate than non-AP patients. A total of 7% and 2% AP patients underwent video endoscopy and video fluorography respectively. In multivariate analysis, lower BMI, lower C-reactive protein, a lower ratio of homestay before hospitalization, a higher complication rate of cerebrovascular disease, dementia, and neuromuscular disease were noted as a characteristic of AP patients. Swallowing interventions were performed for 51% of the AP patients who had been hospitalized for more than two weeks. In univariate analysis, swallowing intervention improved in-hospital mortality. Lower AP recurrence before hospitalization and a lower ratio of homestay before hospitalization were indicated as characteristics of AP patients of the swallowing intervention group from multivariate analysis. Change in dietary pattern from normal to modified diet was observed more frequently in the swallowing intervention group.ConclusionAP accounts for 38.4% of all pneumonia cases in acute care hospitals in Northern Japan. The use of swallowing evaluations and interventions, which may reduce the risk of dysphagia and may associate with lowering mortality in AP patients, is still not widespread.

Published
2021
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8. Osseous hamartoma arising from the Eustachian tube

Author

Ai Kawamoto, Yukio Katori, Yohei Honkura, Masaki Ogura, Takeshi Oshima, and Toshimitsu Kobayashi

Subjects
Eustachian tube, osseous hamartoma, secretory otitis media, endoscopic surgery., Medicine (General), R5-920
Abstract

A fairly quite rare case of osseous tumor arising from the Eustachian tube (ET) is described. A 56-year-old man presented with a smooth bulky mass in the nasopharynx and secretory otitis media in the right ear. Computed tomography and magnetic resonance imaging indicated a solid tumor-like region occupying the nasopharynx with apparent extension to the right ET. Transnasal endoscopic surgery demonstrated that the tumor had originated from the ET, and the tumor was partially removed in the area where it had expanded into the nasopharynx. The pathological diagnosis was an osseous hamartoma consisting of bony tissue, fat cells and fibroblasts. To our knowledge, this is the first reported case of osseous hamartoma arising from the ET in the world literature. The patient presented symptoms of nasal obstruction and unilateral aural fullness. Reduction surgery and tympanostomy tube insertion were useful for accurate diagnosis and resolution of the symptoms.

Published
2013
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41. Iterative Greedy LMI for Sparse Control

Author

Yutaka Yamamoto, Masaaki Nagahara, and Masaki Ogura

Subjects
Filter design, Control and Optimization, Dense graph, Finite impulse response, Control and Systems Engineering, Computer science, Convergence (routing), MathematicsofComputing_NUMERICALANALYSIS, Linear matrix inequality, Sparse approximation, Algorithm, Dykstra's projection algorithm, Sparse matrix
Abstract

In this letter, we propose a novel method to find matrices that satisfy sparsity and LMI (linear matrix inequality) constraints at the same time. This problem appears in sparse control design such as sparse representation of the state feedback gain, sparse graph representation with fastest mixing, and sparse FIR (finite impulse response) filter design, to name a few. We propose an efficient algorithm for the solution based on Dykstra’s projection algorithm. We then prove a convergence theorem of the proposed algorithm, and show some control examples to illustrate merits and demerits of the proposed method.

Published
2022

43. Reduced-Order Model Predictive Control of a Fish Schooling Model

Author

Masaki Ogura and Naoki Wakamiya

Subjects
Control and Systems Engineering, FOS: Electrical engineering, electronic engineering, information engineering, Systems and Control (eess.SY), Electrical Engineering and Systems Science - Systems and Control, Analysis, Computer Science Applications
Abstract

We study the problem of model predictive control (MPC) for the fish schooling model proposed by Gautrais et al. (Annales Zoologici Fennici, 2008). The high nonlinearity of the model attributed to its attraction/alignment/repulsion law suggests the need to use MPC for controlling the fish schooling's motion. However, for large schools, the hybrid nature of the law can make it numerically demanding to perform finite-horizon optimizations in MPC. Therefore, this paper proposes reducing the fish schooling model for numerically efficient MPC; the reduction is based on using the weighted average of the directions of individual fish in the school. We analytically show how using the normalized eigenvector centrality of the alignment-interaction network can yield a better reduction by comparing reduction errors. We confirm this finding on the weight and numerical efficiency of the MPC with the reduced-order model by numerical simulations. The proposed reduction allows us to control a school with up to 500 individuals. Further, we confirm that reduction with the normalized eigenvector centrality allows us to improve the control accuracy by factor of five when compared to that using constant weights., Comment: Accepted for publication in Nonlinear Analysis: Hybrid Systems

Published
2023
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44. Distributed 3D Deployment of Aerial Base Stations for On-Demand Communication

Author

Masaki Ogura and Tatsuaki Kimura

Subjects
Base station, Dynamic network analysis, Wireless network, Software deployment, Computer science, Applied Mathematics, Real-time computing, Telecommunications link, Convergence (routing), Maximization, Electrical and Electronic Engineering, Interference (wave propagation), Computer Science Applications
Abstract

An aerial base station (ABS), i.e., unmanned aerial vehicle-mounted base station, has a significant potential to effectively boost the coverage of next-generation wireless networks, having capability of adaptively serving traffic increase in temporary events (i.e., hotspots). However, designing an efficient 3D deployment of ABSs is a considerably complicated problem due to its high degree of freedom and inter-cell interference among ABSs. In this paper, we propose a novel distributed 3D ABS deployment method for providing on-demand downlink communications. To consider the spatial and temporal variations of user locations due to user activities, we model them by an inhomogeneous point process. By analyzing the performance metrics under this model and applying a distributed push-sum, we develop an ABS deployment algorithm with theoretical convergence guarantee that solves the maximization problems of the overall communication quality in a distributed and iterative manner. In our method, each ABS updates its position based on its local information by communicating with its neighboring ABSs. Furthermore, we propose an estimation method of the overall user density from partial observation of ground sensors. Simulation results demonstrate that our method can efficiently improve the overall communication quality and can be applied to a dynamic network.

Published
2021

48. Temporal deep unfolding for constrained nonlinear stochastic optimal control

Author

Masako Kishida and Masaki Ogura

Subjects
Human-Computer Interaction, Stochastic control, Nonlinear system, Control and Optimization, Control engineering systems. Automatic machinery (General), Control and Systems Engineering, Computer science, Control theory, TJ212-225, Electrical and Electronic Engineering, Computer Science Applications
Abstract

This paper proposes a computational technique to solve discrete‐time optimal control problems for nonlinear systems subject to stochastic disturbances, hard input constraints, and soft constraints. The approach employs the idea of deep unfolding, which is a recently developed model‐based deep learning method that is applicable to iterative algorithms. By regarding each state transition of the dynamical system as an iteration step, these state transitions are unfolded into the layers of a deep neural network. This produces a computational graph that contains trainable parameters that determine control inputs. These parameters are optimized by training the deep neural network using the standard deep learning technique of backpropagation and incremental training. Then, the optimal control inputs are obtained from the optimized parameters. This provides a way to optimize the control inputs that otherwise would be difficult to obtain. The effectiveness of the proposed technique is demonstrated by numerical experiments for the maximum hands‐off control problem and constrained model predictive control problems using a highly nonlinear model of a continuous stirred tank reactor.

Published
2021

49. Shepherding Control for Separating a Single Agent from a Swarm

Author

Yaosheng Deng, Masaki Ogura, Aiyi Li, and Naoki Wakamiya

Subjects
Control and Systems Engineering, FOS: Electrical engineering, electronic engineering, information engineering, Systems and Control (eess.SY), Electrical Engineering and Systems Science - Systems and Control
Abstract

In this paper, we consider the swarm-control problem of spatially separating a specified target agent within the swarm from all the other agents, while maintaining the connectivity among the other agents. We specifically aim to achieve the separation by designing the movement algorithm of an external agent, called a shepherd, which exerts repulsive forces on the agents in the swarm. This problem has potential applications in the context of the manipulation of the swarm of micro- and nano-particles. We first formulate the separation problem, where the swarm agents (called sheep) are modeled by the Boid model. We then analytically study the special case of two-sheep swarms. By leveraging the analysis, we then propose a potential function-based movement algorithm of the shepherd to achieve separation while maintaining the connectivity within the remaining swarm. We demonstrate the effectiveness of the proposed algorithm with numerical simulations., 6 pages, 6 figures

Published
2022

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