Thesis Abstract

Abstract
Robotics technology has shown great potential in the field of rehabilitation, particularly in assisting individuals with mobility impairments. This thesis focuses on the design and optimization of a robotic exoskeleton for rehabilitation purposes. The objective of this research is to develop a wearable robotic device that can assist individuals with limited mobility in performing daily activities and regaining motor functions. The study involves the design and development of the exoskeleton, as well as the optimization of its control algorithms to ensure efficient and effective assistance to the user. The introduction section provides background information on the relevance of robotic exoskeletons in rehabilitation and highlights the need for advanced assistive devices to improve the quality of life for individuals with mobility impairments. The problem statement identifies the challenges faced by individuals with limited mobility and the limitations of current rehabilitation methods. The objectives of the study are outlined to guide the research towards developing a functional and user-friendly robotic exoskeleton. The literature review section presents an in-depth analysis of existing research and developments in the field of robotic exoskeletons for rehabilitation. Key concepts, design considerations, control strategies, and clinical applications are discussed to provide a comprehensive understanding of the current state of the art in this field. The review of relevant literature helps in identifying gaps in existing research and informs the design and optimization process of the robotic exoskeleton. The research methodology section details the approach taken to design, develop, and optimize the robotic exoskeleton. This includes the selection of materials, components, and sensors, as well as the integration of control algorithms to ensure smooth and accurate movement assistance. The methodology also covers the testing and validation procedures to evaluate the performance and functionality of the exoskeleton in real-world rehabilitation scenarios. The discussion of findings section presents the results of the design and optimization process, highlighting the key outcomes, challenges faced, and lessons learned during the research. The performance of the robotic exoskeleton in assisting individuals with mobility impairments is evaluated based on criteria such as comfort, safety, reliability, and user satisfaction. The findings provide insights into the effectiveness of the exoskeleton design and its potential impact on rehabilitation practices. In conclusion, the study demonstrates the successful design and optimization of a robotic exoskeleton for rehabilitation purposes. The developed exoskeleton shows promise in assisting individuals with limited mobility in performing daily activities and improving their motor functions. The significance of the study lies in its contribution to the advancement of assistive technology for rehabilitation and its potential to enhance the quality of life for individuals with mobility impairments. Keywords Robotics, exoskeleton, rehabilitation, design, optimization, mobility impairments, assistive technology.

Thesis Overview