Sparse Magnetometer-Free Real-Time Inertial Hand Motion Tracking

Aaron Grapentin, Dustin Lehmann, Ardjola Zhupa, T. Seel
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引用次数: 4

Abstract

Hand motion tracking is a key technology in several applications including ergonomic workplace assessment, human-machine interaction and neurological rehabilitation. Recent technological solutions are based on inertial measurement units (IMUs). They are less obtrusive than exoskeleton-based solutions and overcome the line-of-sight restrictions of optical systems. The number of sensors is crucial for usability, unobtrusiveness, and hardware cost. In this paper, we present a real-time capable, sparse motion tracking solution for hand motion tracking that requires only five IMUs, one on each of the distal finger segments and one on the back of the hand, in contrast to recently proposed full-setup solution with 16 IMUs. The method only uses gyroscope and accelerometer readings and avoids magnetometer readings, which enables unrestricted use in indoor environments, near ferromagnetic materials and electronic devices. We use a moving horizon estimation (MHE) approach that exploits kinematic constraints to track motions and performs long-term stable heading estimation. The proposed method is validated experimentally using a recently developed sensor system. It is found that the proposed method yields qualitatively good agreement of the estimated and the actual hand motion and that the estimates are long-term stable. The root-mean-square deviation between the fingertip position estimates of the sparse and the full setup are found to be in the range of 1 cm. The method is hence highly suitable for unobtrusive and non-restrictive motion tracking in a range of applications.
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稀疏无磁强计实时惯性手部运动跟踪
手部运动跟踪技术是人体工程学工作场所评估、人机交互和神经康复等领域的关键技术。最近的技术解决方案是基于惯性测量单元(imu)。它们比基于外骨骼的解决方案不那么突兀,并且克服了光学系统的视线限制。传感器的数量对可用性、不显眼性和硬件成本至关重要。在本文中,我们提出了一种实时的、稀疏的手部运动跟踪解决方案,它只需要五个imu,一个在远端手指节上,一个在手背上,而不是最近提出的具有16个imu的全设置解决方案。该方法仅使用陀螺仪和加速度计读数,避免了磁力计读数,从而可以在室内环境,铁磁材料和电子设备附近不受限制地使用。我们使用移动视界估计(MHE)方法,利用运动学约束来跟踪运动并执行长期稳定的航向估计。该方法在最新研制的传感器系统上得到了实验验证。结果表明,所提出的方法在定性上与实际手部运动的估计值一致,且估计值是长期稳定的。指尖位置估计的稀疏和完整设置之间的均方根偏差在1厘米的范围内。因此,该方法非常适合在一系列应用中进行不显眼和非限制性的运动跟踪。
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