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ORCIDMasayuki Sato 0003
Person information
- affiliation: Japan Aerospace Exploration Agency, Institute of Space Technology and Aeronautics, Tokyo, Japan
- affiliation (PhD 2009): University of Tokyo, Japan
Other persons with the same name
- Masayuki Sato — disambiguation page
- Masayuki Sato 0001
![[0000-0002-4186-5014]](https://dblp.uni-trier.de./img/orcid-mark.12x12.png "0000-0002-4186-5014")
— Tohoku University, Sendai, Japan - Masayuki Sato 0002 — Gunma University, Department of Bio-Chemical Engineering, Japan
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2020 – today
- 2024
[j20]Masayuki Sato, Noboru Sebe:
Observer-structured controller for linear parametric plant. Autom. 163: 111569 (2024)- [c46]Masayuki Sato, Kazuyoshi Hatada:
Robust Visual-Feedback Controller for Cart-Driven Pendulum with Fictitious Parameters and Parameter-Dependent Lyapunov Functions. CCTA 2024: 471-476 - [c45]Masayuki Sato, Kazuyoshi Hatada, Shohei Otomo:
Position Control of Cart-Driven Inverted Pendulum by Visual Feedback Controller Using Non-Calibrated Images Taken Through Fisheye Lens. ICARCV 2024: 626-631 - 2023
- [c44]Kazuyoshi Hatada, Masayuki Sato, Kentaro Hirata:
Performance Improvement of a Calibration-Free Visual Feedback Controller Using Lens Distortion Parameters. IECON 2023: 1-6 - 2022
- [j19]Lejun Chen, Christopher Edwards, Halim Alwi, Masayuki Sato:
Simultaneous Fault and Input Time Delay Estimation for an Actuator System: Theory and Flight Data Validation. IEEE Control. Syst. Lett. 6: 1172-1177 (2022) - [j18]Andrés Marcos, Sérgio Waitman, Masayuki Sato:
Fault tolerant linear parameter varying flight control design, verification and validation. J. Frankl. Inst. 359(2): 653-676 (2022) - [j17]Lejun Chen, Halim Alwi, Christopher Edwards, Masayuki Sato:
Flight Evaluation of an LPV Sliding Mode Observer for Sensor FTC. IEEE Trans. Control. Syst. Technol. 30(3): 1319-1327 (2022) - [j16]Kazuyoshi Hatada, Masayuki Sato, Kentaro Hirata, Yoichiro Masui:
Synthesis of a Calibration-Free Visual Feedback Controller for an Inverted Pendulum Using a Fisheye Lens. IEEE Trans. Ind. Electron. 69(12): 13348-13358 (2022) - [c43]Masayuki Sato, Noboru Sebe:
Conversion From Unstructured LPV Controllers to Observer-Structured LPV Controllers. CDC 2022: 3297-3302 - 2021
- [j15]Masayuki Sato, Dimitri Peaucelle:
Causal Gain-scheduled output feedback controllers using parameter-dependent Lyapunov Functions. Autom. 129: 109569 (2021) - [c42]Masayuki Sato, Daisuke Akasaka:
Luenberger Observer-Based Flight Controller Design Using Robust Control Toolbox™. CCTA 2021: 1160-1165 - [c41]Masayuki Sato:
Passive Fault-Tolerant Flight Control Design Example for Elevator Efficiency Reduction Using Structured H∞ Control. MED 2021: 627-632 - [c40]Kana Shikada, Noboru Sebe, Masayuki Sato:
Robust observer-based controller against plant uncertainties. SICE 2021: 1196-1201 - 2020
- [j14]Lejun Chen, Christopher Edwards, Halim Alwi, Masayuki Sato:
Flight evaluation of a sliding mode online control allocation scheme for fault tolerant control. Autom. 114: 108829 (2020) - [j13]Masayuki Sato:
One-shot design of performance scaling matrices and observer-based gain-scheduled controllers depending on inexact scheduling parameters. Syst. Control. Lett. 137: 104632 (2020) - [j12]Masayuki Sato:
Observer-Based Robust Controller Design With Simultaneous Optimization of Scaling Matrices. IEEE Trans. Autom. Control. 65(2): 861-866 (2020) - [j11]Masayuki Sato:
Robust Gain-Scheduled Flight Controller for an In-Flight Simulator. IEEE Trans. Aerosp. Electron. Syst. 56(3): 2122-2135 (2020) - [c39]Georges Hardier, Gilles Ferreres, Masayuki Sato:
On-line parameter estimation for indirect adaptive flight control: a practical evaluation of several techniques. CCTA 2020: 180-187 - [c38]Masayuki Sato, Andrés Marcos:
Observer-Based Robust H∞ Fault-Tolerant Flight Control: a Design Example and Performance Assessment. CDC 2020: 4706-4711
2010 – 2019
- 2019
- [c37]Lejun Chen, Christopher Edwards, Halim Alwi, Masayuki Sato:
Hardware-in-the-loop simulation for a sliding mode FDI scheme. ACC 2019: 4436-4441 - [c36]Soji Kayo, Akiko Nohmi, Noboru Sebe, Masayuki Sato:
Minimal order observer based H∞ controller design based on overbounding approximation method. ASCC 2019: 167-172 - [c35]Sérgio Waitman, Andrés Marcos, Masayuki Sato:
Design and Hardware-In-the-Loop Validation of a Fault-Tolerant Y* Flight Control Law. SysTol 2019: 177-182 - 2018
- [j10]Masayuki Sato:
Gain-Scheduled Flight Controller Using Bounded Inexact Scheduling Parameters. IEEE Trans. Control. Syst. Technol. 26(3): 1074-1082 (2018) - [c34]Lejun Chen, Halim Alwi, Christopher Edwards, Masayuki Sato:
Active Fault Tolerant Control of MuPAL-a Using Sliding Modes. ACC 2018: 6120-6125 - [c33]Lejun Chen, Halim Alwi, Christopher Edwards, Masayuki Sato:
Evaluation of a Sliding Mode Fault Tolerant Controller on the MuPAL-$\alpha$ Research Aircraft. CCTA 2018: 760-765 - [c32]Georges Hardier, Gilles Ferreres, Masayuki Sato:
Design and Flight Testing of an Adaptive Gain-Scheduled Controller Using On-Line Model Estimation. CCTA 2018: 766-773 - [c31]Simone Panza, Masayuki Sato, Marco Lovera, Koji Muraoka:
Robust Attitude Control Design of Quad-Tilt-Wing UAV: A Structured $\mu$-Synthesis Approach. CCTA 2018: 781-786 - [c30]Masayuki Sato, Dimitri Peaucelle:
A New Method for Gain-Scheduled Output Feedback Controller Design Using Inexact Scheduling Parameters. CCTA 2018: 1295-1300 - [c29]Masayuki Sato, Dimitri Peaucelle:
Continuous-Time Gain-Scheduled H∞ Controllers with Causality for Scheduling Parameters via Parameter-Dependent Lyapunov Functions. CDC 2018: 4908-4913 - [c28]Masayuki Sato:
Conversion from Full-Order Controllers to Observer-Structured Controllers. MED 2018: 493-498 - [c27]Christopher Edwards, Lejun Chen, Ahmed Khattab, Halim Alwi, Masayuki Sato:
Flight Evaluations of Sliding Mode Fault Tolerant Controllers. VSS 2018: 180-185 - 2017
- [j9]Anh Tuan Tran, Noboru Sakamoto, Masayuki Sato, Koji Muraoka:
Control Augmentation System Design for Quad-Tilt-Wing Unmanned Aerial Vehicle via Robust Output Regulation Method. IEEE Trans. Aerosp. Electron. Syst. 53(1): 357-369 (2017) - [c26]Masayuki Sato:
Discrete-time observer-based gain-scheduled output feedback controller design with simultaneous optimization of scaling matrices. ASCC 2017: 2232-2237 - [c25]Lejun Chen, Halim Alwi, Christopher Edwards, Masayuki Sato:
Hardware-in-the-loop evaluation of an LPV sliding mode fixed control allocation scheme on the MuPAL-α research aircraft. CCTA 2017: 590-595 - [c24]Masayuki Sato:
Observer-based continuous-time robust scaled-H∞ controller design with simultaneous optimization of scaling matrices. CCTA 2017: 638-643 - [c23]Andrés Marcos, Masayuki Sato:
Flight testing of an structured H-infinity controller: An EU-Japan collaborative experience. CCTA 2017: 2132-2137 - [c22]Masayuki Sato, Motahare Abbasghorbani, Mohammad Hassan Asemani:
Continuous-time observer-based gain-scheduled output feedback controller design with simultaneous optimization of scaling matrices. CDC 2017: 517-522 - [c21]Lejun Chen, Halim Alwi, Christopher Edwards, Masayuki Sato:
Flight evaluation of an LPV sliding mode controller with online control allocation. CDC 2017: 3928-3933 - 2016
- [c20]Masayuki Sato, Koji Muraoka, Koki Hozumi, Yukihisa Sanada, Tsutomu Yamada, Tatsuo Torii:
Flight demonstration of Unmanned Airplane for Radiation Monitoring System with preview path-tracking controller. ACC 2016: 6735-6740 - 2015
- [c19]Masayuki Sato:
Gain-scheduled output feedback controllers for discrete-time LPV systems using bounded inexact scheduling parameters. CDC 2015: 730-735 - 2014
- [c18]Masayuki Sato:
Discrete-time gain-scheduled model-matching flight controller using inexact scheduling parameters. CCA 2014: 171-176 - 2013
- [j8]Masayuki Sato, Dimitri Peaucelle:
Gain-scheduled output-feedback controllers using inexact scheduling parameters for continuous-time LPV systems. Autom. 49(4): 1019-1025 (2013) - [c17]Masayuki Sato:
Robust Gain-Scheduled flight controller using inexact scheduling parameters. ACC 2013: 6829-6834 - [c16]Kentaro Hirata, Masayuki Sato, Kazuyoshi Hatada, Yoichiro Masui:
Robust controller synthesis for a class of uncertain systems and application to visual feedback control. IECON 2013: 3740-3745 - 2012
- [c15]Masayuki Sato:
Gain-Scheduled Observers Using Inexact Scheduling Parameters. ROCOND 2012: 369-374 - 2011
- [j7]Masayuki Sato:
Gain-scheduled output-feedback controllers depending solely on scheduling parameters via parameter-dependent Lyapunov functions. Autom. 47(12): 2786-2790 (2011) - [c14]Masayuki Sato:
Discrete-time Gain-Scheduled Output-Feedback controllers exploiting inexact scheduling parameters. CACSD 2011: 1032-1037 - [c13]Masayuki Sato:
Discrete-time Gain-Scheduled Output-Feedback controllers exploiting inexact scheduling parameters via Parameter-Dependent Lyapunov Functions. CDC/ECC 2011: 1938-1943 - 2010
- [j6]Masayuki Sato:
Gain-scheduled open-loop system design for LPV systems using polynomially parameter-dependent Lyapunov functions. Syst. Control. Lett. 59(5): 265-276 (2010) - [c12]Masayuki Sato, Yoshio Ebihara, Dimitri Peaucelle:
Gain-Scheduled state-feedback controllers using inexactly measured scheduling parameters: H2 and H∞ problems. ACC 2010: 3094-3099 - [c11]Masayuki Sato:
Gain-Scheduled output-feedback controllers using inexactly measured scheduling parameters. CDC 2010: 3174-3180
2000 – 2009
- 2009
- [j5]Masayuki Sato:
Robust model-following controller design for LTI systems affected by parametric uncertainties: a design example for aircraft motion. Int. J. Control 82(4): 689-704 (2009) - [j4]Dimitri Peaucelle, Masayuki Sato:
LMI Tests for Positive Definite Polynomials: Slack Variable Approach. IEEE Trans. Autom. Control. 54(4): 886-891 (2009) - [c10]Masayuki Sato:
Parameter-Dependent Slack Variable approach for positivity check of polynomials over hyper-rectangle. ACC 2009: 5357-5362 - [c9]Masayuki Sato, Nobuhiro Yokoyama, Atsushi Satoh:
Disturbance suppression via robust MPC using prior disturbance data application to flight controller design for Gust Alleviation. CDC 2009: 8026-8033 - 2008
- [j3]Masayuki Sato:
Inverse system design for LPV systems using parameter-dependent Lyapunov functions. Autom. 44(4): 1072-1077 (2008) - [j2]Masayuki Sato:
Design method of gain-scheduled controllers not depending on derivatives of parameters. Int. J. Control 81(6): 1013-1025 (2008) - 2007
- [c8]Masayuki Sato, Dimitri Peaucelle:
Comparison Between SOS Approach and Slack Variable Approach for Non-negativity Check of Polynomial Functions: Single Variable Case. ACC 2007: 6139-6146 - [c7]Masayuki Sato, Dimitri Peaucelle:
Robust stability/performance analysis for uncertain linear systems via multiple slack variable approach: Polynomial LTIPD systems. CDC 2007: 5031-5037 - 2006
- [j1]Masayuki Sato:
Filter design for LPV systems using quadratically parameter-dependent Lyapunov functions. Autom. 42(11): 2017-2023 (2006) - [c6]Masayuki Sato:
H2 Filter Design for Linear Parameter-Varying Systems using Higher-Order Parameter-Dependent Lyapunov Functions. ACC 2006: 5638-5643 - [c5]Masayuki Sato, Dimitri Peaucelle:
Robust Stability/Performance Analysis for Linear Time-Invariant Polynomially Parameter-Dependent Systems using Polynomially Parameter-Dependent Lyapunov Functions. CDC 2006: 5807-5813 - [c4]Masayuki Sato, Dimitri Peaucelle:
Robust Stability/Performance Analysis for Linear Time-Invariant Polytopically Parameter-Dependent Systems using Polynomially Parameter-Dependent Lyapunov Functions. CDC 2006: 5814-5819 - 2005
- [c3]Masayuki Sato:
Robust performance analysis of linear time-invariant parameter-dependent systems using higher-order Lyapunov functions. ACC 2005: 615-620vol.1 - 2004
- [c2]Masayuki Sato:
Filter design for LPV systems using biquadratic Lyapunov functions. ACC 2004: 1368-1373 - 2003
- [c1]Masayuki Sato:
Gain-scheduled inverse system and filtering system without derivatives of scheduling parameters. ACC 2003: 4173-4178
Coauthor Index
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