An Autonomous Underwater Vehicle for Validating Internal Actuator Control Strategies

Schultz, Christopher R.

13 July 2006

There are benefits to the use of internal actuators for rotational maneuvers of small-scale underwater vehicles. Internal actuators are protected from the outside environment by the external pressure hull and will not disturb the surrounding environment during inspection tasks. Additionally, internal actuators do not rely on the relative fluid motion to exert control moments, therefore they are useful at low speed and in hover. This paper describes the design, fabrication and testing of one such autonomously controlled, internally actuated underwater vehicle. The Internally Actuated, Modular Bodied, Untethered Submersible (IAMBUS) can be used to validate non-linear control strategies using internal actuators. Vehicle attitude control is provided by three orthogonally mounted reaction wheels. The housing is a spherical glass pressure vessel, which contains all of the components, such as actuators, ballast system, power supply, on-board computer and inertial sensor. Since the housing is spherically symmetric, the hydrodynamics of IAMBUS are uncoupled (e.g. a roll maneuver does not impact pitch or yaw). This hull shape enables IAMBUS to be used as a spacecraft attitude dynamics and control simulator with full rotational freedom. / Master of Science

autonomous underwater vehicle (AUV)

satellite simulator

reaction wheels

attitude control

Development of a Control Moment Gyroscope controlled, three axis satellite simulator, with active balancing for the bifocal relay mirror initiative

Kulick, Wayne J.

12 1900

Approved for public release; distribution in unlimited. / This thesis develops and implements a Control Moment Gyroscope (CMG) steering law, controller and active balancing system for a three-axis satellite simulator (TASS). The CMGs are configured in a typical pyramid configuration (the fourth CMG position being null). The development was done primarily with simulation and experiments utilizing Real Time Workshop and XPC Target of MATLAB and SIMULINK. The TASS is a double circular platform mounted on a spherical air bearing with the center of rotation (CR) about the approximate physical geometric center of the simulator. The TASS utilizes three moveable masses in the three body axes for balancing which actively eliminate any center of gravity (CG) offset and return the CG to the CR. The TASS supports an optics payload designed to acquire, track and point a received laser beam onto an off-satellite target. The target may be stationary or moving. Actively balancing the TASS reduces the torque output requirement for the CMGs while maintaining either a stabilized level platform or a particular commanded attitude. Reduction or elimination of torque output from the CMGs results in a more stabilized platform, less structural induced vibration, less jitter in payload optics and less power required in spacecraft applications. / Lieutenant Commander, United States Navy

Artificial satellites

Rotation

Attitude

Gyroscopic instruments

Astronautical instruments

Satellite Simulator

Active Balancing

Auto Balancing

Control Moment Gyroscope

CMG

Air Bearing

Large-Scale Variability in Marine Low Stratiform Cloud Amount and Its Relationship to Lower-Tropospheric Static Stability in Terms of Cloud Types / 雲タイプの観点からみた海洋下層雲量の大規模変動特性とその下部対流圏静的安定度との関係

Koshiro, Tsuyoshi

23 July 2018

京都大学 / 0048 / 新制・論文博士 / 博士(理学) / 乙第13202号 / 論理博第1561号 / 新制||理||1635(附属図書館) / 京都大学大学院理学研究科・地球惑星科学専攻 / (主査)教授 塩谷 雅人, 准教授 重 尚一, 教授 秋友 和典 / 学位規則第4条第2項該当 / Doctor of Science / Kyoto University / DGAM

low stratiform cloud

inversion strength

low cloud type

large-scale variability

ship-based observation

global climate model

satellite simulator

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