Presentation is loading. Please wait.

Presentation is loading. Please wait.

Human Gait Analysis using IMU Sensors

Published byAneta Kubíčková Modified over 4 years ago

Similar presentations

Presentation on theme: "Human Gait Analysis using IMU Sensors"— Presentation transcript:

1 Human Gait Analysis using IMU Sensors
Sandeep Kumar, K. Gopinath, Laura Rocchi, Poorna T S Department of Computer Science and Automation Indian Institute of Science, Bangalore, India Dr. Jayanth Sampath, Suyameendra Kulkarni Bangalore Institute of Movement and Research Analysis. Presented By: Dr. K. Gopinath (Professor, Indian Institute of Science)

2 Side Plane (Sagittal Plane)
Gait Analysis Gait Analysis is study of human motion (Walking Style) measuring body movements, body mechanics and the activity of the muscles. Used to assess, plan, and treat individuals with conditions affecting their ability to walk. Side Plane (Sagittal Plane) Front/Back Plane Top Plane

3 Different Planes Sagittal Plane: Frontal/Coronal Plane:
Plane parallel to side view of the body. Most of the motions happen in this plane. Frontal/Coronal Plane: Plane parallel to front view of the body. Transverse Plane: Plane parallel to the top view of the body.

4 Current Gold Standard Issues:
Optical System (Camera Based) Force plates Body Markers High Accuracy Issues: Costly Requirements Clean room Lighting condition Trained physician Not easy to attach sensors, esp to children

5 Why IMU Sensors? EXEL s3 IMU Sensor Accelerometer, Gyroscope and Magnetometer built into them Lower cost than an Optical System Easy to wear Can be used in any environment

6 AIM Build an end to end “portable” system for Human Gait Analysis to calculate the clinically relevant Gait parameters using optimal number of IMU sensors which can be used in place of Optical Gait Analysis System Our Contributions: Practical approach to calculate clinically relevant Gait parameters using IMU sensors. Angles calculated in the Sagittal plane within error bounds when compared with the Optical System. Working prototype for Android System to collect and process the data.

7 2 Problems 1: position and angle estimates subject to drift
Solution: periodic phases of rest, an even ground, a constant magnetic field, kinematic constraints 2: orientation of the sensor’s coordinate systems with respect to the joint axis or the segments they are mounted on Solution: kinematic constraints with minimization opt. Ref: Joint Axis and Position Estimation from Inertial Measurement Data by Exploiting Kinematic Constraints: Thomas Seel, Thomas Schauer, Jo ̈rg Raisch

8 Heel Strike and Toe Off These events marks the start and end of the Gait cycle. These are one of the most importance gait parameters. Based on them the final average angle is calculated. We use data from shank and foot sensors to calculate these parameters independently which provides a way to verify the results.

9 Calculation of angles Knee Flexion Extension
The angles can be calculated by integrating the difference of angular velocity (g) around the axis of rotation (j).

10 Calculation of angles Hip Flexion Extension
The angles can be calculated by integrating the difference of angular velocity (g) around the axis of rotation (j).

11 Calculation of angles Ankle Dorsi-Plantar Flexion
The angles can be calculated by integrating the difference of angular velocity (g) around the axis of rotation (j). Note that the order of subtraction is reversed here. It is because of how angles are defined.

12 Sagittal Plane Angles

13 Sagittal Plane Angles

14 Sagittal Plane Angles

15 Calibration IMU and Optical Data alignment:

16 Calibration Optimizing Condition:
Aim is to find two j vectors, j1 and j2, which correspond to the axis of rotation in the sagittal plane for the two body segments, corresponding to joints, on which sensors are attached. Thigh and Shank for Knee joint, Shank and Foot for ankle joint. g1 and g2 are gyroscope readings from sensors on the corresponding joints.

17 Results: Comparing HT and TO
Comparison of HT and TO detection from Shank and Foot sensors. Comparison of HT and TO from Shank and Foot sensors, with optical sensors, independently. Errors within bounds for clinical usage. Sagittal plane angles error in RMSE

18 Results: Comparing Sagittal Plane Angles
Comparison of angles in Sagittal Plane as calculated by IMU sensors vs Optical sensors. Errors within bounds for clinical usage Sagittal plane angles error in RMSE

19 Other Plane angles: Angles in Frontal and Transversal
Most of the movements happen in Sagittal plane. Due to limited movement in these planes, along with noise, makes the angle calculation difficult.

20 Processing on Smartphone

21 Video: Working of Android Application
Calibration Movement. Working of App.

22 Thank you. Questions ?

Download ppt "Human Gait Analysis using IMU Sensors"

Similar presentations

An analysis of human movement: Joints, Muscles and Mechanics in specified sporting actions (including planes and axes) What you need to know: Analyse shoulder.

An analysis of human movement: Joints, Muscles and Mechanics in specified sporting actions (including planes and axes) What you need to know: Analyse shoulder.
Angular Kinematics D. Gordon E. Robertson, PhD, FCSB

Angular Kinematics D. Gordon E. Robertson, PhD, FCSB
Slide Ruler. ? X 5 On today’s menu...  What happened with Gravity  Noise  The tool today  Fundamental Limitations  Magical Christmas Land  (Where.

Slide Ruler. ? X 5" On today’s menu...  What happened with Gravity  Noise  The tool today  Fundamental Limitations  Magical Christmas Land  (Where.
3-Dimensional Gait Measurement Really expensive and fancy measurement system with lots of cameras and computers Produces graphs of kinematics (joint.

3-Dimensional Gait Measurement Really expensive and fancy measurement system with lots of cameras and computers Produces graphs of kinematics (joint.
Copyright Xsens Technologies B.V. 2011; Company confidential Estimating foot parameters Jesper Lansink Rotgerink Supervisors: Dr. ir. Daniel Roetenberg.

Copyright Xsens Technologies B.V. 2011; Company confidential Estimating foot parameters Jesper Lansink Rotgerink Supervisors: Dr. ir. Daniel Roetenberg.
Introduction to Biomechanics EXSC 408L - Fall ‘10 Dr. Kathleen E. Sand (BU 2007; USC 2004) subject line: EXSC 408L … Office Hours.

Introduction to Biomechanics EXSC 408L - Fall ‘10 Dr. Kathleen E. Sand (BU 2007; USC 2004) subject line: EXSC 408L … Office Hours.
Phases of the Gait Cycle And Determinants of Gait

Phases of the Gait Cycle And Determinants of Gait
Stair Gait Lecture Notes.

Stair Gait Lecture Notes.
Gait.

Gait.
A wearable inertial sensor system for human motion analysis Tao Liu Robotics and Dynamics Lab Kochi University of Technology 2005-6-29 6th IEEE International.

A wearable inertial sensor system for human motion analysis Tao Liu Robotics and Dynamics Lab Kochi University of Technology th IEEE International.
Optimization of Networked Smart Shoe for Gait Analysis using Heuristic Algorithms with Automated Thresholding Nantawat Pinkam, Advisor: Dr. Itthisek Nilkhamhang.

Optimization of Networked Smart Shoe for Gait Analysis using Heuristic Algorithms with Automated Thresholding Nantawat Pinkam, Advisor: Dr. Itthisek Nilkhamhang.
Biomechanics- Gait.

Biomechanics- Gait.
Movement Terms / Anatomical Terms

Movement Terms / Anatomical Terms
Angular Variables Linear Angular Position m s deg. or rad. q Velocity

Angular Variables Linear Angular Position m s deg. or rad. q Velocity
Time 1  shank  thigh  Knee Segment Angles are ABSOLUTE ANGLES, measured with respect to a (stationary) global vertical or horizontal reference axis.

Time 1  shank  thigh  Knee Segment Angles are ABSOLUTE ANGLES, measured with respect to a (stationary) global vertical or horizontal reference axis.
Biomechanics: Instep & Side Foot Soccer Kick Naomi Shimabuku Becky Wong PE 483 Dr. Caster.

Biomechanics: Instep & Side Foot Soccer Kick Naomi Shimabuku Becky Wong PE 483 Dr. Caster.
Determinants of Gait Determinants of Gait.

Determinants of Gait Determinants of Gait.
Animation Following “Advanced Animation and Rendering Techniques” (chapter 15+16) By Agata Przybyszewska.

Animation Following “Advanced Animation and Rendering Techniques” (chapter 15+16) By Agata Przybyszewska.
Background: Coordinate System Transformations. i j Derivation of the 2D Rotation Matrix (basis vectors) θ.

Background: Coordinate System Transformations. i j Derivation of the 2D Rotation Matrix (basis vectors) θ.
Kinetics versus Kinematics for Analyzing Locomotor Coordination D. Gordon E. Robertson, Ph.D. School of Human Kinetics, University of Ottawa, Ottawa, CANADA.

Kinetics versus Kinematics for Analyzing Locomotor Coordination D. Gordon E. Robertson, Ph.D. School of Human Kinetics, University of Ottawa, Ottawa, CANADA.

Similar presentations

Ads by Google