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"This book offers a comprehensive overview of techniques, processes, and professional practices in the area of motion design. From fundamental building blocks of organizing time and space in production to managing workflow, budgets, and client relationships. The authors provide insight into the production process from concept through execution in areas as diverse as social media to large-scale projection mapping for events and festivals. Readers will learn through real-world examples, case studies, and interviews how to effectively utilize their skills in various areas of motion design. Industry professionals provide unique perspectives on different areas of motion design while showcasing their outstanding and inspiring work throughout. This is a valuable resource to students who aspire to work in a broad range of visual communication disciplines and expand their practice of motion design"--

Motion Design. --- Graphics industry --- digitale ontwerptechnieken --- ontwerpen --- reclame --- beeldende kunst --- tekenen

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The optimization of motion and trajectory planning is an effective and usually costless approach to improving the performance of robots, mechatronic systems, automatic machines and multibody systems. Indeed, wise planning increases precision and machine productivity, while reducing vibrations, motion time, actuation effort and energy consumption. On the other hand, the availability of optimized methods for motion planning allows for a cheaper and lighter system construction. The issue of motion planning is also tightly linked with the synthesis of high-performance feedback and feedforward control schemes, which can either enhance the effectiveness of motion planning or compensate for its gaps. To collect and disseminate a meaningful collection of these applications, this book proposes 15 novel research studies that cover different sub-areas, in the framework of motion planning and control.

History of engineering & technology --- humanoid robot --- walk fast --- rotational slip --- ZMP --- gait planning --- quadruped robot --- whole robot control --- location trajectory --- dynamic gait --- fin stabilizer --- command-filtered backstepping --- sliding mode control --- prescribed performance --- disturbance observer --- OES --- inertial stability accuracy --- low-speed performance --- speed observation --- disturbance observation --- state-augmented Kalman filter --- composed control scheme --- fractional calculus --- FOPD controller --- underwater vehicle --- motion control --- modal analysis --- flexible multibody systems --- linearized models --- six-legged robot --- whole-body motion planning --- rugged terrain --- support --- swing --- gesture-based teleoperation --- robotic assembly --- force feedback --- compliant robot motion --- pickup manipulator --- adaptive genetic algorithm --- trajectory optimization --- improved artificial potential field method --- obstacle avoidance planning --- robust estimation --- dynamic model --- unknown but bounded noise --- extended set-membership filter --- dynamic balancing --- shaking force balancing --- acceleration control of the center of mass --- fully Cartesian coordinates --- natural coordinates --- parallel manipulators --- passive model --- biped walking --- Impact and contact --- friction force --- dissipative force --- energy efficiency --- robot --- motion design --- functional redundancy --- UR5 --- hybrid navigation system --- weighted-sum model --- a heuristic algorithm --- piecewise cubic Bézier curve --- mobile robot --- humanoid robot --- walk fast --- rotational slip --- ZMP --- gait planning --- quadruped robot --- whole robot control --- location trajectory --- dynamic gait --- fin stabilizer --- command-filtered backstepping --- sliding mode control --- prescribed performance --- disturbance observer --- OES --- inertial stability accuracy --- low-speed performance --- speed observation --- disturbance observation --- state-augmented Kalman filter --- composed control scheme --- fractional calculus --- FOPD controller --- underwater vehicle --- motion control --- modal analysis --- flexible multibody systems --- linearized models --- six-legged robot --- whole-body motion planning --- rugged terrain --- support --- swing --- gesture-based teleoperation --- robotic assembly --- force feedback --- compliant robot motion --- pickup manipulator --- adaptive genetic algorithm --- trajectory optimization --- improved artificial potential field method --- obstacle avoidance planning --- robust estimation --- dynamic model --- unknown but bounded noise --- extended set-membership filter --- dynamic balancing --- shaking force balancing --- acceleration control of the center of mass --- fully Cartesian coordinates --- natural coordinates --- parallel manipulators --- passive model --- biped walking --- Impact and contact --- friction force --- dissipative force --- energy efficiency --- robot --- motion design --- functional redundancy --- UR5 --- hybrid navigation system --- weighted-sum model --- a heuristic algorithm --- piecewise cubic Bézier curve --- mobile robot

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

The optimization of motion and trajectory planning is an effective and usually costless approach to improving the performance of robots, mechatronic systems, automatic machines and multibody systems. Indeed, wise planning increases precision and machine productivity, while reducing vibrations, motion time, actuation effort and energy consumption. On the other hand, the availability of optimized methods for motion planning allows for a cheaper and lighter system construction. The issue of motion planning is also tightly linked with the synthesis of high-performance feedback and feedforward control schemes, which can either enhance the effectiveness of motion planning or compensate for its gaps. To collect and disseminate a meaningful collection of these applications, this book proposes 15 novel research studies that cover different sub-areas, in the framework of motion planning and control.

humanoid robot --- walk fast --- rotational slip --- ZMP --- gait planning --- quadruped robot --- whole robot control --- location trajectory --- dynamic gait --- fin stabilizer --- command-filtered backstepping --- sliding mode control --- prescribed performance --- disturbance observer --- OES --- inertial stability accuracy --- low-speed performance --- speed observation --- disturbance observation --- state-augmented Kalman filter --- composed control scheme --- fractional calculus --- FOPD controller --- underwater vehicle --- motion control --- modal analysis --- flexible multibody systems --- linearized models --- six-legged robot --- whole-body motion planning --- rugged terrain --- support --- swing --- gesture-based teleoperation --- robotic assembly --- force feedback --- compliant robot motion --- pickup manipulator --- adaptive genetic algorithm --- trajectory optimization --- improved artificial potential field method --- obstacle avoidance planning --- robust estimation --- dynamic model --- unknown but bounded noise --- extended set-membership filter --- dynamic balancing --- shaking force balancing --- acceleration control of the center of mass --- fully Cartesian coordinates --- natural coordinates --- parallel manipulators --- passive model --- biped walking --- Impact and contact --- friction force --- dissipative force --- energy efficiency --- robot --- motion design --- functional redundancy --- UR5 --- hybrid navigation system --- weighted-sum model --- a heuristic algorithm --- piecewise cubic Bézier curve --- mobile robot --- n/a