Project Abstract

Gait analysis has become an increasingly important tool in the field of rehabilitation, as it provides valuable insights into an individual's mobility and physical well-being. Traditional methods of gait analysis often rely on specialized equipment, such as motion capture systems or force plates, which can be expensive and inaccessible to many healthcare facilities. This project aims to develop a more affordable and accessible solution for gait analysis by utilizing neural network-based algorithms. The primary objective of this project is to create a system that can accurately and reliably assess an individual's gait patterns during rehabilitation activities. By leveraging the power of deep learning, the system will be able to analyze data from more readily available sensors, such as wearable devices or RGB-D cameras, and provide detailed feedback on the user's progress and areas for improvement. One of the key challenges in gait analysis is the inherent variability in human movement patterns. Individuals with different physical characteristics, mobility limitations, or rehabilitation needs can exhibit diverse gait patterns, making it difficult to develop a one-size-fits-all solution. To address this challenge, the project will employ advanced neural network architectures that can adaptively learn and model the unique gait patterns of each individual. The proposed system will consist of two main components a data collection module and a neural network-based gait analysis module. The data collection module will utilize affordable sensors, such as inertial measurement units (IMUs) or depth cameras, to capture the user's movements during rehabilitation exercises or daily activities. The captured data will then be fed into the neural network-based gait analysis module, which will be trained to recognize and classify different gait patterns. The neural network-based gait analysis module will leverage state-of-the-art deep learning techniques, such as convolutional neural networks (CNNs) and recurrent neural networks (RNNs), to extract meaningful features from the sensor data and identify patterns indicative of the user's gait characteristics. By incorporating techniques like transfer learning and personalized model adaptation, the system will be able to adapt to the specific needs and limitations of each individual user, providing more accurate and personalized feedback. One of the key benefits of this project is the potential to enhance the effectiveness of rehabilitation programs by providing healthcare professionals with detailed and objective data on their patients' progress. By monitoring changes in gait patterns over time, the system can help identify areas of improvement, detect potential setbacks, and enable healthcare providers to tailor their treatment plans accordingly. Moreover, the accessibility and affordability of the proposed system can make gait analysis more widely available, empowering individuals to actively participate in their own rehabilitation and self-monitor their progress. This could lead to improved patient engagement, better treatment outcomes, and reduced healthcare costs. In conclusion, this project aims to develop a neural network-based gait analysis system that can revolutionize the way rehabilitation is monitored and managed. By combining the power of deep learning with affordable sensor technologies, the project has the potential to transform the field of gait analysis and enhance the overall quality of rehabilitation services.

Project Overview