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Tensegrity Systems discusses analytical tools to design energy efficient and lightweight structures employing the concept of "tensegrity." This word is Buckminster Fuller's contraction of the words "Tensile" and "Integrity," which suggests that integrity or, as we would say, stability of the structure comes from tension. In a tensegrity structure the rigid bodies (the bars), might not have any contact, thus providing extraordinary freedom to control shape, by controlling only tendons. Tensegrity Systems covers both static and dynamic analysis of special tensegrity structural concepts, which are motivated by biological material architecture. Drawing upon years of practical experience and using numerous examples and illustrative applications, Robert Skelton and Mauricio C. de Oliveira discuss: The design of tensegrity structures using analytical tools The integration of tensegrity systems into a combined framework including structural design and control design The rules for filling space (tesselation) with self-similar structures that guarantee a specific mechanical property are provided Tensegrity Systems will be of interest to all engineers who design or control light-weight structures, including deployable and robotic structures, and shape controllable structures. Also, Engineers interested in the study of advanced dynamics will find new and useful algorithms for multibody systems.
Control theory. --- Structural analysis (Engineering). --- Tensile architecture. --- Tensile architecture --- Tensegrity (Engineering) --- Structural analysis (Engineering) --- Control theory --- Civil Engineering --- Civil & Environmental Engineering --- Engineering & Applied Sciences --- Lightweight construction. --- Architectural engineering --- Engineering, Architectural --- Structural mechanics --- Structures, Theory of --- Construction, Lightweight --- Light construction --- Light weight construction --- Minimum weight construction --- Engineering. --- System theory. --- Structural mechanics. --- Vibration. --- Dynamical systems. --- Dynamics. --- Control engineering. --- Robotics. --- Mechatronics. --- Buildings --- Building. --- Construction. --- Engineering, Architectural. --- Building Construction. --- Vibration, Dynamical Systems, Control. --- Structural Mechanics. --- Systems Theory, Control. --- Control, Robotics, Mechatronics. --- Ceramics, Glass, Composites, Natural Methods. --- Design and construction. --- Dynamics --- Machine theory --- Structural engineering --- Building --- Mechanics. --- Mechanics, Applied. --- Systems theory. --- Building Construction and Design. --- Solid Mechanics. --- Ceramics, Glass, Composites, Natural Materials. --- Applied mechanics --- Engineering, Mechanical --- Engineering mathematics --- Classical mechanics --- Newtonian mechanics --- Physics --- Quantum theory --- Cycles --- Mechanics --- Sound --- Buildings—Design and construction. --- Ceramics. --- Glass. --- Composites (Materials). --- Composite materials. --- Automation --- Dynamical systems --- Kinetics --- Mathematics --- Mechanics, Analytic --- Force and energy --- Statics --- Control engineering --- Control equipment --- Engineering instruments --- Programmable controllers --- Systems, Theory of --- Systems science --- Science --- Composites (Materials) --- Multiphase materials --- Reinforced solids --- Solids, Reinforced --- Two phase materials --- Materials --- Amorphous substances --- Ceramics --- Glazing --- Ceramic technology --- Industrial ceramics --- Keramics --- Building materials --- Chemistry, Technical --- Clay --- Mechanical engineering --- Microelectronics --- Microelectromechanical systems --- Construction --- Construction science --- Structural design --- Architecture --- Construction industry --- Philosophy --- Design and construction
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Classical mechanics. Field theory --- Engineering sciences. Technology --- Chemical technology --- Artificial intelligence. Robotics. Simulation. Graphics --- composieten --- mechatronica --- systeemtheorie --- systeembeheer --- mechanica --- chemische technologie --- robots --- dynamica
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Control theory. --- Algebras, Linear. --- Linear control systems. --- Théorie de la commande --- Algèbre linéaire --- Commande linéaire --- #TELE:SISTA --- Théorie de la commande --- Algèbre linéaire --- Commande linéaire --- Linear control systems --- Automatic control
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Tensegrity Systems discusses analytical tools to design energy efficient and lightweight structures employing the concept of "tensegrity." This word is Buckminister Fuller's contraction of the words "Tensile" and "Integrity," which suggests that integrity or, as we would say, stability of the structure comes from tension. In a tensegrity structure the rigid bodies (the bars), might not have any contact, thus providing extraordinary freedom to control shape, by controlling only tendons. Tensegrity Systems covers both static and dynamic analysis of special tensegrity structural concepts, which are motivated by biological material architecture. Drawing upon years of practical experience and using numerous examples and illustrative applications, Robert Skelton and Mauricio C. de Oliveira discuss: The design of tensegrity structures using analytical tools The integration of tensegrity systems into a combined framework including structural design and control design The rules for filling space (tesselation) with self-similar structures that guarantee a specific mechanical property are provided Tensegrity Systems will be of interest to all engineers who design or control light-weight structures, including deployable and robotic structures, and shape controllable structures. Also, Engineers interested in the study of advanced dynamics will find new and useful algorithms for multibody systems.
Classical mechanics. Field theory --- Engineering sciences. Technology --- Chemical technology --- Artificial intelligence. Robotics. Simulation. Graphics --- composieten --- mechatronica --- systeemtheorie --- systeembeheer --- mechanica --- chemische technologie --- robots --- dynamica
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