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柔性机械臂是一种利用柔性材料或柔性结构并通过连续运动控制来完成操作任务的特殊机械臂，具有重量轻、灵活、物理交互安全等优点，在工业和家庭应用中都显示出广阔的前景。在Web of Science数据库中，“柔性机械臂”、“软体机械臂”、“柔性手”等搜索词或搜索范围呈现出蓬勃发展的趋势。本书详细研究了柔性机械臂，包括对柔性机械臂的系统回顾，结构和驱动的集成设计，柔性机械臂的建模和实现、结构优化和实验验证。本书从设计，仿真到实验验证，深刻阐述了对柔性机械臂的精细控制和有效应用方法。

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• Contents
  1 Review of Soft Manipulator Research, Applications and Opportunities 1
  1.1 Related Literature Analysis 2
  1.2 Research Status of Soft Manipulator 4
  1.2.1 Fluid-Driven Mode 4
  1.2.2 Cable-Driven Mode 7
  1.2.3 Electroactive Polymer-Driven Mode 8
  1.2.4 Shape Memory Materials-Driven Mode 10
  1.2.5 Electromagnetic-Driven Mode 11
  1.2.6 Hybrid Drive Mode 12
  1.2.7 Comparison of Different Drive Modes 14
  1.3 Enabling Technologies of the Soft Manipulator 15
  1.3.1 Kinematic and Dynamic Modeling 18
  1.3.2 Motion Control 21
  1.3.3 Shape Detection 23
  1.3.4 Dynamic Tactile Perception 25
  1.3.5 Stiffening Method of Soft Structure 28
  1.4 Opportunities and Challenges of Soft Manipulator in Application 30
  1.5 Summary 34
  References 35
  2 Design and Development of an Elephant Trunk-Like Soft Robotic Manipulator 47
  2.1 Design of a Pneumatic Soft Actuator 47
  2.1.1 Design Schematic 47
  2.1.2 Kinematic Model of the Soft Actuator 48
  2.1.3 Determination of Elastic Stiffness of the Soft Actuator 52
  2.2 Design and Development of the Soft Manipulator 54
  2.2.1 Kinematic Model of the Soft Manipulator 54
  2.2.2 Simulation and Analysis 56
  2.3 Experiment Analysis 59
  2.3.1 Development of the Experiment System 59
  2.3.2 Experimental Results Analysis 61
  2.4 Summary 64
  References 64
  3 Design and Optimization of a Pneumatic Soft Actuator 67
  3.1 Model Parameterization 68
  3.1.1 Geometric Model and Physical Process Description 68
  3.1.2 Structural Parameterization 68
  3.2 Structural Analysis and Optimization Design Method 69
  3.2.1 Structural Analysis Method 69
  3.2.2 Optimization Design Method 75
  3.2.3 Determination Method of the Material Constitutive Model 78
  3.3 Sensitivity Analysis of Structural Parameters 80
  3.3.1 Initial Parameter Value and Design Range 81
  3.3.2 Single Factor Impact Analysis: Inclination Angle 82
  3.3.3 Univariate Factor Impact Analysis: Reaction Force 85
  3.3.4 Analysis Conclusion 86
  3.4 Structural Optimization and Performance Evaluation 88
  3.4.1 Establishment of Global Objective Function 88
  3.4.2 Calculation of the Maximum Value of the Univariate Objective 89
  3.4.3 Implementation of Global Optimization 90
  3.4.4 Optimization Results of Pneumatic Manipulator 92
  3.5 Summary 94
  References 94
  4 Experimental Validation of a Composite Soft Actuator 97
  4.1 Shape Deformation Simulation and Experiment 97
  4.1.1 FEM Simulation in ABAQUS 97
  4.1.2 Design of Pneumatic Experiment System 98
  4.1.3 Experimental Validation 98
  4.2 Implementation Analysis of the Pneumatic Actuator 101
  4.2.1 Tensile Damage Analysis 101
  4.2.2 Pulling Force Analysis 103
  4.3 Summary 105
  References 105
  5 Improved Design of the Variable Cross-Section for the Trunk-Like Soft Manipulator 107
  5.1 The Improved Structure Design of the Variable Cross-Section for the Trunk-Like Soft Manipulator 109
  5.2 Path Planning and Pressure Control of the Soft Manipulator 113
  5.2.1 Simplified Model Based on Experimental Data 113
  5.2.2 Path Planning and Control Based on Optimization Algorithm 118
  5.3 Principle Prototype and Test System 124
  5.3.1 Principle Prototype Design and Development 124
  5.3.2 Upper Computer Control System 126
  5.4 Soft Manipulator Control Test 132
  5.4.1 Spiral Winding Movement 133
  5.4.2 The Four-Leaf Clover Movement 135
  5.4.3 The Pendulum Swings Movement from Side to Side 136
  5.4.4 The Horizontal Plane Swings from Side to Side and Bends Upward Movement 139
  5.4.5 Fixed Point Movement and Target Capture 141
  5.5 Summary 143
  References 144
  6 Kinematic Modeling and Experimental Validation of a Foldable Pneumatic Soft Module 147
  6.1 Kinematic Modeling of the Foldable Pneumatic Soft Manipulator 147
  6.1.1 Design Schematic 147
  6.1.2 Kinematic Model of the Foldable Pneumatic Module 149
  6.2 Numerical Calculation and Analysis 154
  6.2.1 Model Parameters 154
  6.2.2 Shape Deformation of the Pneumatic Module 155
  6.2.3 Workspace of the Pneumatic Module 156
  6.3 Experiment Design and Validation 157
  6.3.1 Experiment Design 157
  6.3.2 Repeatability Test of the Pneumatic Module 158
  6.3.3 Validation of the Model Prediction Accuracy 160
  6.4 Summary 164
  References 164
  7 Design, Modeling and Implementation of a Foldable Pneumatic Soft Manipulator 167
  7.1 Design of the Foldable Pneumatic Soft Manipulator 168
  7.2 Kinematic Modeling of the Soft Manipulator 169
  7.2.1 Kinematic Model 169
  7.2.2 Numerical Calculation and Analysis 172
  7.3 Implementation and Experimental Validation 176
  7.3.1 Experiment Design 176
  7.3.2 Experimental Validation of the Soft Manipulator 180
  7.4 Inverse Kinematic Modeling for Overall Shape Prediction of Soft Manipulators 182
  7.4.1 Coordinate Frames Definition 183
  7.4.2 Equivalent Simplification and Data Preparation 186
  7.4.3 Model Organization 187
  7.4.4 Model Performance and Discussions 189
  7.5 Summary 196
  References 197
  8 Design and Experimental Validation of a Cable-Driven Continuum Manipulator and Soft Gripper 199
  8.1 Design of a Cable-Driven Continuum Manipulator and Soft Gripper 199
  8.1.1 General Design Schematic 199
  8.1.2 Topological Optimization Design of a Soft Gripper 200
  8.2 Experimental Validation 203
  8.2.1 Experiment System 203
  8.2.2 Capture Test of the Soft Gripper 204
  8.2.3 Motion Control of the Continuum Manipulator 205
  8.3 Summary 206
  References 206