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研究生: 姜奧開
Eko Rudiawan Jamzuri
論文名稱: 人型機器人節能步態生成器
An Energy-Efficient Gait Generation for The Humanoid Robot
指導教授: 包傑奇
Jacky Baltes
學位類別: 碩士
Master
系所名稱: 電機工程學系
Department of Electrical Engineering
論文出版年: 2020
畢業學年度: 108
語文別: 英文
論文頁數: 45
中文關鍵詞: 人形機器人步態產生步態優化ZMP預覽控制器CMA-ES
英文關鍵詞: humanoid robot, gait generation, gait optimization, ZMP preview controller, CMA-ES
DOI URL: http://doi.org/10.6345/NTNU202000830
論文種類: 學術論文
相關次數: 點閱:176下載:10
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Energy efficiency is the main issue in the robotics field, especially in the humanoid robot, due to the limited power source from the battery. Efficient power consumption becomes the primary role of increasing the durability of the robot. In the humanoid robot, the main electric load is on the joint actuators. Therefore, for reducing the energy consumption, it can be formulated through gait optimization, which is selected from the optimal values of parameterized of the gait engine.
This thesis proposed a method for generating a stable and energy-efficient gait for the humanoid robot that can be applied in variable speed and omnidirectional walk. The gait pattern is generated by Zero Moment Point (ZMP) preview controller and Bezier function. Gait engine is parameterized by parameters to adjust the Centre of Mass (CoM) height, body posture, and walking speed. The Covariance Matrix Adaptation Evolution Strategies (CMA-ES) has been proposed to find the optimal values that yielded a stable and energy-efficient gait in a safe simulation environment.
The optimal gait parameters were verified in the simulation and real robot, able to reduce energy about 29.813 % and improve stability 20 % during training. Verification in the real robot validated the result, which can save energy about 19.905 % compared to non-optimized gait. Moreover, the optimal parameters are generalized that can be applied to variable speed and omnidirectional walk without unstable issues.

Table of Contents Acknowledgment i ABSTRACT ii Table of Contents iii Figure Index v Table Index vi Chapter 1. Introduction 1 1.1 Background 1 1.2 Related Works 2 1.3 Problem Statement 4 1.4 Research Aim & Objective 4 1.5 Contribution of This Thesis 4 1.6 Outline of This Thesis 4 Chapter 2. Kinematics Analysis 5 2.1 Humanoid Robot Platform 5 2.2 Simplified Model of Humanoid Robot 6 2.3 Forward Kinematics 7 2.4 Inverse Kinematics 12 Chapter 3. Gait Generation 14 3.1 Walking Method of Humanoid Robot 14 3.2 Parameterized Walking Pattern Generation 15 3.3 Footstep Pattern Generation 18 3.4 CoM Trajectory Generation 18 3.5 Swing Foot Trajectory Generation 23 3.6 Joint Space Trajectory Generation 25 Chapter 4. Gait Optimization 26 4.1 Optimization Objective 26 4.2 Optimization Parameters 27 4.3 Covariance Matrix Adaptation Evolution Strategies 27 4.4 Training in the Simulation-based Environment 30 Chapter 5. Experimental Result and Discussion 32 5.1 Generated Walking Trajectory 32 5.2 Training Performance 34 5.3 Evaluation Performance 35 5.4 Comparison Performance Before and After Optimization 36 5.5 Straight Walk with Variable Step Length 38 Chapter 6. Conclusion and Future Work 40 References 41 Autobiography 44 Academic Achievement 45

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