Conversion of Upper-Limb Inertial Measurement Unit Data to Joint Angles: A Systematic Review

Fang, Zhou; Woodford, Sarah C.; Senanayake, Damith; Ackland, David C.

doi:10.3390/s23146535

Cited by 11 publications

(11 citation statements)

References 148 publications

(651 reference statements)

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“…Most studies have analyzed the validity and/or reliability of different IMUs for measuring joint motion during several movements and/or activities [ 2 , 7 , 26 , 27 ]. However, there is a broad consensus that the more complex the joint motion analyzed (e.g., involving more anatomical planes, higher intensities/speeds/accelerations during movement, etc.…”

Section: Discussionmentioning

confidence: 99%

Assessing the Validity of the Ergotex IMU in Joint Angle Measurement: A Comparative Study with Optical Tracking Systems

Jimenez-Olmedo,

Tortosa-Martínez,

Cortell-Tormo

et al. 2024

Sensors

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An observational, repeated measures design was used in this study to assess the validity of the Ergotex Inertial Measurement Unit (IMU) against a 3D motion capture system for measuring trunk, hip, and shoulder angles in ten healthy adult males (38.8 ± 7.3 y, bodyweight 79.2 ± 115.9 kg, body height 179.1 ± 8.1 cm). There were minimal systematic differences between the devices, with the most significant discrepancy being 1.4 degrees for the 80-degree target angle, denoting Ergotex’s precision in joint angle measurements. These results were statistically significant (p < 0.001), with predominantly trivial to small effect sizes, indicating high accuracy for clinical and biomechanical applications. Bland–Altman analysis showed Limits of Agreement (LoA) approximately ±2.5 degrees across all angles and positions, with overall LoA ranging from 3.6 to −2.4 degrees, reflecting Ergotex’s consistent performance. Regression analysis indicated uniform variance across measurements, with minor heteroscedastic errors producing a negligible underestimation trend of around 0.5 degrees in some instances. In conclusion, the Ergotex IMU is a reliable tool for accurate joint angle measurements. It offers a practical and cost-effective alternative to more complex systems, particularly in settings where precise measurement is essential.

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Section: Discussionmentioning

confidence: 99%

Assessing the Validity of the Ergotex IMU in Joint Angle Measurement: A Comparative Study with Optical Tracking Systems

Jimenez-Olmedo,

Tortosa-Martínez,

Cortell-Tormo

et al. 2024

Sensors

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“…Inertial sensors require frequent calibration for accurate measurements [ 61 , 126 ], and in the case those calibrations are lost, the measuring process, and consequently the surgical procedure, may be compromised. Even when calibrated, orientation estimation requires some processing of the sensor data, usually in the form of a sensor fusion algorithm, to obtain useful measurements as noise, bias, and drift (mainly from the gyroscope) are well-reported issues in the literature [ 127 , 128 ]. Furthermore, inertial-based sensors typically present good accuracy in angle measurements.…”

Section: Discussionmentioning

confidence: 99%

Intraoperative Angle Measurement of Anatomical Structures: A Systematic Review

Cruz,

Gonçalves,

Neves

et al. 2024

Sensors

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Ensuring precise angle measurement during surgical correction of orientation-related deformities is crucial for optimal postoperative outcomes, yet there is a lack of an ideal commercial solution. Current measurement sensors and instrumentation have limitations that make their use context-specific, demanding a methodical evaluation of the field. A systematic review was carried out in March 2023. Studies reporting technologies and validation methods for intraoperative angular measurement of anatomical structures were analyzed. A total of 32 studies were included, 17 focused on image-based technologies (6 fluoroscopy, 4 camera-based tracking, and 7 CT-based), while 15 explored non-image-based technologies (6 manual instruments and 9 inertial sensor-based instruments). Image-based technologies offer better accuracy and 3D capabilities but pose challenges like additional equipment, increased radiation exposure, time, and cost. Non-image-based technologies are cost-effective but may be influenced by the surgeon’s perception and require careful calibration. Nevertheless, the choice of the proper technology should take into consideration the influence of the expected error in the surgery, surgery type, and radiation dose limit. This comprehensive review serves as a valuable guide for surgeons seeking precise angle measurements intraoperatively. It not only explores the performance and application of existing technologies but also aids in the future development of innovative solutions.

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“…We advise the use of FC when the focus of the measurement is on achieving the most accurate elbow flexion angle. • MA requires accurate sensor positioning and alignment of the sensors on the wearer’s body segments ( Fang et al, 2023 ), requiring extensive training of the operator. MA displays good accuracy and low errors across a multitude of joint angle axes and during both single-plane and multi-plane tasks.…”

Section: Discussionmentioning

confidence: 99%

“…To accurately identify the two main elbow rotation axes, scientific literature presents several techniques that are most commonly adopted to perform IMU calibration, which are more extensively described in ( Fang et al, 2023 ). In short, these are 1) N-Pose calibration (NP), which involves holding a known pose to align each sensor reference frame to the reference of the bone underneath ( Zhang and Wu, 2011 ; Liu et al, 2019 ; Humadi et al, 2021 ); 2) Functional calibration (FC), which consists of performing single-plane elbow flexion-extension and pronation-supination movements to estimate the relative joint rotation axis ( Cutti et al, 2008 ; Ligorio et al, 2017 ); 3) Manual alignment (MA) calibration, where each sensor is accurately positioned on the body segment to assume a perfect match between the sensor reference frame and the bone-embedded reference frame ( Bouvier et al, 2015 ; Höglund et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Effects of IMU sensor-to-segment calibration on clinical 3D elbow joint angles estimation

Bonfiglio,

Tacconi,

Bongers

et al. 2024

Front. Bioeng. Biotechnol.

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Introduction: Inertial Measurement Units (IMU) require a sensor-to-segment calibration procedure in order to compute anatomically accurate joint angles and, thereby, be employed in healthcare and rehabilitation. Research literature proposes several algorithms to address this issue. However, determining an optimal calibration procedure is challenging due to the large number of variables that affect elbow joint angle accuracy, including 3D joint axis, movement performed, complex anatomy, and notable skin artefacts. Therefore, this paper aims to compare three types of calibration techniques against an optical motion capture reference system during several movement tasks to provide recommendations on the most suitable calibration for the elbow joint.Methods: Thirteen healthy subjects were instrumented with IMU sensors and optical marker clusters. Each participant performed a series of static poses and movements to calibrate the instruments and, subsequently, performed single-plane and multi-joint tasks. The metrics used to evaluate joint angle accuracy are Range of Motion (ROM) error, Root Mean Squared Error (RMSE), and offset. We performed a three-way RM ANOVA to evaluate the effect of joint axis and movement task on three calibration techniques: N-Pose (NP), Functional Calibration (FC) and Manual Alignment (MA).Results: Despite small effect sizes in ROM Error, NP displayed the least precision among calibrations due to interquartile ranges as large as 24.6°. RMSE showed significant differences among calibrations and a large effect size where MA performed best (RMSE = 6.3°) and was comparable with FC (RMSE = 7.2°). Offset showed a large effect size in the calibration*axes interaction where FC and MA performed similarly.Conclusion: Therefore, we recommend MA as the preferred calibration method for the elbow joint due to its simplicity and ease of use. Alternatively, FC can be a valid option when the wearer is unable to hold a predetermined posture.

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Conversion of Upper-Limb Inertial Measurement Unit Data to Joint Angles: A Systematic Review

Cited by 11 publications

References 148 publications

Assessing the Validity of the Ergotex IMU in Joint Angle Measurement: A Comparative Study with Optical Tracking Systems

Assessing the Validity of the Ergotex IMU in Joint Angle Measurement: A Comparative Study with Optical Tracking Systems

Intraoperative Angle Measurement of Anatomical Structures: A Systematic Review

Effects of IMU sensor-to-segment calibration on clinical 3D elbow joint angles estimation

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