Abstract
This chapter deals with the estimation of human kinematics using magneto and inertial sensing technology. A magneto-inertial measurement unit typically embeds a triaxial gyroscope, a triaxial accelerometer, and a triaxial magnetic sensor in the same assembly. By combining the information provided by each sensor within a sensor fusion framework, it is possible to determine the unit orientation with respect to a common global coordinate system. Recent advances in the construction of microelectromechanical system devices have made possible the manufacturing of small and light devices. These advances have widened the range of possible applications to include areas such as human movement. This chapter aims at providing the reader with a picture of the state of the art in the measurement and estimation methods for the description of human joint kinematics using magneto-inertial sensing technology. In the first section, fundamental concepts of rigid body kinematics are introduced with special reference to magneto-inertial measurements. Then a short description of the operational characteristics of accelerometers, gyroscopes, and magnetometers is provided. The third section reports theory and methods for the estimation of the orientation and position of magneto-inertial measurement units along with the implementation of a Kalman filter for 3D orientation estimate as an example. In the last section, a critical review of the most common methodologies for the joint kinematic estimation is reported.
This is a preview of subscription content, log in via an institution.
Abbreviations
- ALI:
-
Anatomical landmark identification
- ARW:
-
Angle Random Walk
- ACS:
-
Anatomical coordinate system
- BCS:
-
Body-fixed coordinate system
- CoR:
-
Center of rotation
- CS:
-
Coordinate system
- DoFs:
-
Degree of freedom
- EKF:
-
Extended Kalman filter
- FUN:
-
Functional
- KF:
-
Kalman filter
- GCS:
-
Global coordinate system
- IMU:
-
Inertial measurement unit
- MCS:
-
MIMU coordinate system
- MEMS:
-
Microelectromechanical systems
- (M)IMU:
-
(Magneto)-inertial measurement unit
- MUL:
-
Manual Unit Alignment
- NEMS:
-
Nano-electromechanical systems
- VRW:
-
Velocity Random Walk
- 〈⋅, ⋅〉:
-
Dot product between vectors
- ⊗:
-
Quaternion multiplication
- [q×]:
-
Skew-symmetric operator
References
Barbour N, Schmidt G (2001) Inertial sensor technology trends. IEEE Sensors J 1:332–339
Bergamini E, Ligorio G, Summa A, Vannozzi G, Cappozzo A, Sabatini AM (2014) Estimating orientation using magnetic and inertial sensors and different sensor fusion approaches: accuracy assessment in manual and locomotion tasks. Sensors 14:18625–18649
Biryukova EV, Roby-Brami A, Frolov AA, Mokhtari M (2000) Kinematics of human arm reconstructed from spatial tracking system recordings. J Biomech 33:985–995
van den Bogert AJ, Smith GD, Nigg BM (1994) In vivo determination of the anatomical axes of the ankle joint complex: an optimization approach. J Biomech 27:1477–1488
Bouvier B, Duprey S, Claudon L, Dumas R, Savescu A (2015) Upper limb kinematics using inertial and magnetic sensors: comparison of sensor-to-segment calibrations. Sensors 15:18813–18833
Bregler C, Malik J (1998) Tracking people with twists and exponential maps. In: Proceedings of 1998 I.E. computer society conference on computer vision pattern recognition (Cat. No.98CB36231), pp 8–15
Camomilla V, Bergamini E, Fantozzi S, Vannozzi G (2015) In-field use of wearable magneto-inertial sensors for sports performance evaluation. In: 33rd international conference on biomechanics in sport, pp 1–4
Cappozzo A, Catani F, Della Croce U, Leardini A (1995) Position and orientation in space of bones during movement. Clin Biomech 10:171–178
Cereatti A, Margheritini F, Donati M, Cappozzo A (2010) Is the human acetabulofemoral joint spherical? J Bone Joint Surg Br 92:311–314
Cereatti A, Trojaniello D, Della Croce U (2015) Accurately measuring human movement using magneto-inertial sensors: techniques and challenges. In: 2015 I.E. international symposium on inert sensors system proceedings, pp 1–4
Churchill DL, Incavo SJ, Johnson CC, Beynnon BD (1998) The transepicondylar axis approximates the optimal flexion axis of the knee. Clin Orthop Relat Res 356:111–118
Cooper G, Sheret I, McMillian L, Siliverdis K, Sha N, Hodgins D et al (2009) Inertial sensor-based knee flexion/extension angle estimation. J Biomech 42:2678–2685
Corke PI (2007) A simple and systematic approach to assigning Denavit-Hartenberg parameters. IEEE Trans Robot 23:590–594
Crabolu M, Pani D, Raffo L, Cereatti A (2016) Estimation of the center of rotation using wearable magneto-inertial sensors. J Biomech 49:3928–3933
Cutti AG, Giovanardi A, Rocchi L, Davalli A, Sacchetti R (2008) Ambulatory measurement of shoulder and elbow kinematics through inertial and magnetic sensors. Med Biol Eng Comput 46:169–178
Cutti AG, Ferrari A, Garofalo P, Raggi M, Cappello A, Ferrari A (2010) “Outwalk”: a protocol for clinical gait analysis based on inertial and magnetic sensors. Med Biol Eng Comput 48:17–25
Dumas R, Chèze L (2007) 3D inverse dynamics in non-orthonormal segment coordinate system. Med Biol Eng Comput 45:315–322
El-Sheimy N, Hou H, Niu X (2008) Analysis and modeling of inertial sensors using Allan variance. IEEE Trans Instrum Meas 57:140–149
Favre J, Aissaoui R, Jolles BM, de Guise JA, Aminian K (2009) Functional calibration procedure for 3D knee joint angle description using inertial sensors. J Biomech 42:2330–2335
Frigo C, Rabuffetti M, Kerrigan DC, Deming LC, Pedotti A (1998) Functionally oriented and clinically feasible quantitative gait analysis method. Med Biol Eng Comput 36:179–185
Grood ES, Suntay WJ (1983) A joint coordinate system for the clinical description of three-dimensional motions: application to the knee. J Biomech Eng 105:136–144
Koning BHW, van der Krogt MM, Baten CTM, Koopman BFJM (2013) Driving a musculoskeletal model with inertial and magnetic measurement units. Comput Methods Biomech Biomed Eng 5842:37–41
Ligorio G, Sabatini AM (2015) A novel Kalman filter for human motion tracking with an inertial-based dynamic inclinometer. IEEE Trans Biomed Eng 62:2033–2043
Ligorio G, Sabatini AM (2016) Dealing with magnetic disturbances in human motion capture: a survey of techniques. Micromachines 7:1–17
Luinge HJ, Veltink PH, Baten CTM (2007) Ambulatory measurement of arm orientation. J Biomech 40:78–85
Madgwick SOH, Harrison AJL, Vaidyanathan R (2011) Estimation of IMU and MARG orientation using a gradient descent algorithm. IEEE Int Conf Rehabil Robot 2011:5975346. https://doi.org/10.1109/ICORR.2011.5975346
McGinnis RS, Perkins NC (2013) Inertial sensor based method for identifying spherical joint center of rotation. J Biomech 46:2546–2549
Picerno P, Cereatti A, Cappozzo A (2008) Joint kinematics estimate using wearable inertial and magnetic sensing modules. Gait Posture 28:588–595
Prentice MJ (1986) Orientation statistics without parametric assumptions. J R Stat Soc Ser B 48:214–222
Roetenberg D, Luinge H, Slycke P (2013) Xsens MVN: Full 6DOF Human Motion Tracking Using Miniature Inertial Sensors. In: Xsens Technologies, whitepaper, version 3:1–9.
Sabatini AM (2011) Estimating three-dimensional orientation of human body parts by inertial/magnetic sensing. Sensors 11:1489–1525
Seel T, Schauer T, Raisch J (2012) Joint axis and position estimation from inertial measurement data by exploiting kinematic constraints. In: 2012 IEEE international conference on control applications (CCA). Part of 2012 IEEE multi-conference on systems and control, Dubrovnik, 3–5 Oct 2012, pp 45–49
Seel T, Raisch J, Schauer T (2014) IMU-based joint angle measurement for gait analysis. Sensors 14:6891–6909
Shuster MD (1993) A survey of attitude representations. J Astronaut Sci 41:439–517
Skog I, Händel P, Nilsson J-O, Rantakokko J (2010) Zero-velocity detection – an algorithm evaluation. IEEE Trans Biomed Eng 57:2657–2666
Slajpah S, Kamnik R, Munih M (2014) Kinematics based sensory fusion for wearable motion assessment in human walking. Comput Methods Prog Biomed 116:131–144
Sommer HJ, Miller NR (1980) A technique for kinematic modeling of anatomical joints. J Biomech Eng 102:311–317
Taetz B, Bleser G, Miezal M (2016) Towards self-calibrating inertial body motion capture. 19th Int Conf Informa Fusion 1751–1759
Titterton DH, Weston JL (2004) Strapdown inertial navigation technology. Editor AIAA Educ. Ser., Reston
Veeger HEJ (2000) The position of the rotation center of the glenohumeral joint. J Biomech 33:1711–1715
Waldron K, Schmiedeler J (2008) Kinematics. Springer Handbook of Robotics, pp 9–33
Wells D, Cereatti A, Camomilla V, Donnelly C (2015) A calibration procedure for mimu sensors allowing for the calculation of elbow angles. In: 33rd international conference on biomechanics in sports, Poitiers
Woodman OJ (2007) An introduction to inertial navigation. Cambridge University Press, Cambridge
Wu G, Siegler S, Allard P, Kirtley C, Leardini A, Rosenbaum D et al (2002) ISB recommendation on definitions of joint coordinate system of various joints for the reporting of human joint motion – part I: ankle, hip, and spine. J Biomech 35:543–548
Wu G, Van Der Helm FCT, Veeger HEJ, Makhsous M, Van Roy P, Anglin C et al (2005) ISB recommendation on definitions of joint coordinate systems of various joints for the reporting of human joint motion – part II: shoulder, elbow, wrist and hand. J Biomech 38:981–992
Yazdi N, Ayazi F, Najafi K (1998) Micromachined inertial sensors. Proc IEEE 86:1640–1658
Author information
Authors and Affiliations
Corresponding author
Section Editor information
Rights and permissions
Copyright information
© 2018 Springer International Publishing AG, part of Springer Nature
About this entry
Cite this entry
Cereatti, A., Della Croce, U., Sabatini, A.M. (2018). Three-Dimensional Human Kinematic Estimation Using Magneto-Inertial Measurement Units. In: Handbook of Human Motion. Springer, Cham. https://doi.org/10.1007/978-3-319-14418-4_162
Download citation
DOI: https://doi.org/10.1007/978-3-319-14418-4_162
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-14417-7
Online ISBN: 978-3-319-14418-4
eBook Packages: EngineeringReference Module Computer Science and Engineering