Potter, 2021
ViewPDF| Publication | Publication Date | Title |
|---|---|---|
| Schepers et al. | Xsens MVN: Consistent tracking of human motion using inertial sensing | |
| Al Borno et al. | OpenSense: An open-source toolbox for inertial-measurement-unit-based measurement of lower extremity kinematics over long durations | |
| Ahmadi et al. | 3D human gait reconstruction and monitoring using body-worn inertial sensors and kinematic modeling | |
| Roetenberg et al. | Xsens MVN: Full 6DOF human motion tracking using miniature inertial sensors | |
| Bonnet et al. | Monitoring of hip and knee joint angles using a single inertial measurement unit during lower limb rehabilitation | |
| Saggio et al. | Technology-based complex motor tasks assessment: A 6-DOF inertial-based system versus a gold-standard optoelectronic-based one | |
| Refai et al. | Portable gait lab: estimating 3D GRF using a pelvis IMU in a foot IMU defined frame | |
| Yi et al. | Detecting and correcting IMU movements during joint angle estimation | |
| Potter et al. | Error-state Kalman filter for lower-limb kinematic estimation: Evaluation on a 3-body model | |
| Li et al. | Multi-body sensor data fusion to evaluate the hippotherapy for motor ability improvement in children with cerebral palsy | |
| Tham et al. | Biomechanical ambulatory assessment of 3D knee angle using novel inertial sensor-based technique | |
| Madrigal et al. | Hip and lower limbs 3D motion tracking using a double-stage data fusion algorithm for IMU/MARG-based wearables sensors | |
| WANG et al. | Estimation of knee joint angle during gait cycle using inertial measurement unit sensors: A method of sensor-to-clinical bone calibration on the lower limb skeletal model | |
| Loose et al. | Gait patterns in standard scenarios: Using Xsens MTw inertial measurement units | |
| Peiffer et al. | Fusing uncalibrated IMUs and handheld smartphone video to reconstruct knee kinematics | |
| Labrozzi et al. | Center of mass estimation for impaired gait assessment using inertial measurement units | |
| Sun et al. | An artificial neural network framework for lower limb motion signal estimation with foot-mounted inertial sensors | |
| Panero et al. | Multi-segments kinematic model of the human spine during gait | |
| Potter | Advancing Human Lower-limb Kinematic Estimation Using Inertial Measurement Units | |
| Yi et al. | Sensor-movement-robust angle estimation for 3-DoF lower limb joints without calibration | |
| Bostelman et al. | Towards standard test artefacts for synchronous tracking of human-exoskeleton knee kinematics | |
| Adjel | Toward the development of a sparse, multi-modal and affordable motion analysis system. Applications to clinical motor tests | |
| ZANCANARO | Comparison of knee loading during walking via musculoskeletal modelling using marker-based and IMU-based approaches | |
| Bhateja | An Integrationless Optimization Method for IMU-Based Human Motion Measurement | |
| Kirdiş Gemici | Gait analysis using inertial measurement units as sensors |