Multi-Body Dynamics Modeling and Control for Strapdown Inertially Stabilized Platforms Considering Light Base Support Characteristics

Wang, Zhongshi; Tian, Dapeng; Shi, Lei; Liu, Jinghong

doi:10.3390/app10207175

Cited by 4 publications

(3 citation statements)

References 37 publications

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“…Both the pitch axis and azimuth axis are driven directly by the DC torque motors, and the dynamic model of the motor mounted on the pitch axis is given by

where

is the motor total torque,

is the torque sensitivity,

is the current of the motor armature,

is the back electromotive force(EMF),

is the back-EMF coefficient [ 29 ],

is the rotational angular velocity of the motor relative to the azimuth gimbal, and

is the input voltage of the motor,

is the armature resistance of the motor,

is the armature inductance of the motor, and the subscript f denotes the pitch motor. Since the value of

is often very small, it can be ignored, and the

is expressed as

…”

Section: The Nonlinear Dynamic Model Of the Optronic Mastmentioning

confidence: 99%

Research on the Line of Sight Stabilization Control Technology of Optronic Mast under High Oceanic Condition and Big Swaying Movement of Platform

Lan

Jiang

Hua

2023

Sensors

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To realize high-performance line of sight (LOS) stabilization control of the optronic mast under high oceanic conditions and big swaying movements of platforms, a composite control method based on an adaptive radial basis function neural network (RBFNN) and sliding mode control (SMC) is proposed. The adaptive RBFNN is used to approximate the nonlinear and parameter-varying ideal model of the optronic mast, so as to compensate for the uncertainties of the system and reduce the big-amplitude chattering phenomenon caused by excessive switching gain in SMC. The adaptive RBFNN is constructed and optimized online based on the state error information in the working process; therefore, no prior training data are required. At the same time, a saturation function is used to replace the sign function for the time-varying hydrodynamic disturbance torque and the friction disturbance torque, which further reduce the chattering phenomenon of the system. The asymptotic stability of the proposed control method has been proven by the Lyapunov stability theory. The applicability of the proposed control method is validated by a series of simulations and experiments.

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“…Both the pitch axis and azimuth axis are driven directly by the DC torque motors, and the dynamic model of the motor mounted on the pitch axis is given by

where

is the motor total torque,

is the torque sensitivity,

is the current of the motor armature,

is the back electromotive force(EMF),

is the back-EMF coefficient [ 29 ],

is the rotational angular velocity of the motor relative to the azimuth gimbal, and

is the input voltage of the motor,

is the armature resistance of the motor,

is the armature inductance of the motor, and the subscript f denotes the pitch motor. Since the value of

is often very small, it can be ignored, and the

is expressed as

…”

Section: The Nonlinear Dynamic Model Of the Optronic Mastmentioning

confidence: 99%

Research on the Line of Sight Stabilization Control Technology of Optronic Mast under High Oceanic Condition and Big Swaying Movement of Platform

Lan

Jiang

Hua

2023

Sensors

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show abstract

“…with complex vibration isolation systems [19][20][21][22][23][24][25], a single-stage vibration isolation system often leads to resonant peaks and standing wave effects at high frequencies [26][27][28][29], which cannot meet the vibration isolation requirements. A dual-stage vibration isolation system draws great interest owing to its better high-frequency effect and higher stability [30][31][32][33][34][35][36].…”

Section: Introductionmentioning

confidence: 99%

Performance and Optimization of a Dual-Stage Vibration Isolation System Using Bio-Inspired Vibration Isolators

Huang

Shi²,

Dong³

et al. 2022

Applied Sciences

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This paper thoroughly investigates the performance and multi-parameter optimization of a dual-stage vibration isolation system with bio-inspired isolators (BI-DSVI) under different base excitations. The dynamic equations of the BI-DSVI are derived. Then, the optimization problem is defined, where three types of base excitation (translation and rotations around the two horizontal axes) are studied. The optimization results show that the vibration transmissibility can be greatly reduced (more than 30 dB) by multi-parameter optimization, and an optimal configuration of structural parameters exists for the bio-inspired isolators. The effective vibration isolation bandwidth is significantly widened. Finally, the paper thoroughly discusses the influence of the structural parameters of the bio-inspired isolators and the base excitation types on the vibration isolation performance. The parameter studies provide useful guidelines for the application of the bio-inspired isolator in dual-stage vibration isolation.

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“…The goal of the DFD procedure is to obtain an efficient design cycle by integrating the dynamics of interconnected systems, including nonlinearities, vibration analysis and parameters estimation, with current design methodologies [8,9]. In the last two decades, MBS became the most effective tool in modeling complex mechanical systems for simulation and system analysis.…”

Section: Introductionmentioning

confidence: 99%

Development of Dynamics for Design Procedure of Novel Grating Tiling Device with Experimental Validation

et al. 2021

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The article proposes a dynamic for design (DFD) procedure for a novel aperture grating tiling device using the multibody system (MBS) approach. The grating device is considered as a rigid-flexible MBS that is built primarily based totally at the load assumptions because of grating movement. This movement is utilized in many industrial applications, such as the compression of laser pulse, precision measuring instruments, and optical communication. A new design procedure of tiling grating device frame is introduced in order to optimize its design parameters and enhance the system stability. The dynamic loads are estimated based on the Lagrange multipliers that are obtained from the solution of the MBS model. This model is fully non-linear and moves in the three-dimensional space, and the relative movement of its bodies is restricted by the description of the constraints function in the motion manifold. The mechanism of the grating device is structurally analyzed in keeping with the dynamic conduct and therefore the generated forces. The symbolic manipulation as well as the computational work of solving the obtained differential-algebraic equations (DAEs) is carried out using MATLAB Symbolic Toolbox. Once the preliminary design has been attained, the stress behavior of the grating device is examined using the MATLAB FEATool Multiphysics toolkit, regarding system stability and design aspects. Moreover, the design was constructed in real life, and the movement has been verified experimentally, which confirms the effectiveness of the proposed procedure. In conclusion, the DFD procedure with trade-off optimization is utilized successfully to design the grating unit for maximum ranges of grating movements.

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Multi-Body Dynamics Modeling and Control for Strapdown Inertially Stabilized Platforms Considering Light Base Support Characteristics

Cited by 4 publications

References 37 publications

Research on the Line of Sight Stabilization Control Technology of Optronic Mast under High Oceanic Condition and Big Swaying Movement of Platform

Research on the Line of Sight Stabilization Control Technology of Optronic Mast under High Oceanic Condition and Big Swaying Movement of Platform

Performance and Optimization of a Dual-Stage Vibration Isolation System Using Bio-Inspired Vibration Isolators

Development of Dynamics for Design Procedure of Novel Grating Tiling Device with Experimental Validation

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