A Tri-Dipole based Location and Orientation Estimation Method in Near Magnetic Field

The Overhauser magnetometer is a scalar quantum magnetometer based on the dynamic nuclear polarization (DNP) effect in the Earth’s magnetic field. Sensitivity is a key technical specification reflecting the ability of instruments to sense small variations of the Earth’s magnetic field and is closely related to the signal-to-noise ratio (SNR) of the free induction decay (FID) signal. In this study, deuterated 15N TEMPONE radical is used in our sensor to obtain high DNP enhancement. The measured SNR of the FID signal is approximately 63/1, and the transverse relaxation time T2 is 2.68 s. The direct measurement method with a single instrument and the synchronous measurement method with two instruments are discussed for sensitivity estimation in time and frequency domains under different electromagnetic interference (EMI) environments and different time periods. For the first time, the correlation coefficient of the magnetic field measured by the two instruments is used to judge the degree of the influence of the environmental noise on the sensitivity estimation. The sensitivity evaluation in the field environment is successfully realized without electrical and magnetic shields. The direct measurement method is susceptible to EMI and cannot work in general electromagnetic environments, except it is sufficiently quiet. The synchronous measurement method has an excellent ability to remove most natural and artificial EMIs and can be used under noisy environments. Direct and synchronous experimental results show that the estimated sensitivity of the JOM-4S magnetometer is approximately 0.01 nT in time domain and approximately 0.01 nT/ in frequency domain at a 3 s cycling time. This study provides a low-cost, simple, and effective sensitivity estimation method, which is especially suitable for developers and users to estimate the performance of the instrument.

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A Novel Pedestrian Orientation Estimation Method for Autonomous Driving

Green, Smart and Connected Transportation Systems - Lecture Notes in Electrical Engineering ◽

10.1007/978-981-15-0644-4_34 ◽

2020 ◽

pp. 431-449

Author(s):

Ming Gao ◽

LiSheng Jin ◽

Yuying Jiang ◽

Baicang Guo

Keyword(s):

Estimation Method ◽

Autonomous Driving ◽

Orientation Estimation

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Robust Visual Compass Using Hybrid Features for Indoor Environments

Electronics ◽

10.3390/electronics8020220 ◽

2019 ◽

Vol 8 (2) ◽

pp. 220 ◽

Cited By ~ 7

Author(s):

Ruibin Guo ◽

Keju Peng ◽

Dongxiang Zhou ◽

Yunhui Liu

Keyword(s):

Autonomous Navigation ◽

Estimation Method ◽

Rotation Matrix ◽

Indoor Environments ◽

3D Mapping ◽

Orientation Estimation ◽

Hybrid Features ◽

Depth Images ◽

Improved Accuracy ◽

Crucial Part

Orientation estimation is a crucial part of robotics tasks such as motion control, autonomous navigation, and 3D mapping. In this paper, we propose a robust visual-based method to estimate robots’ drift-free orientation with RGB-D cameras. First, we detect and track hybrid features (i.e., plane, line, and point) from color and depth images, which provides reliable constraints even in uncharacteristic environments with low texture or no consistent lines. Then, we construct a cost function based on these features and, by minimizing this function, we obtain the accurate rotation matrix of each captured frame with respect to its reference keyframe. Furthermore, we present a vanishing direction-estimation method to extract the Manhattan World (MW) axes; by aligning the current MW axes with the global MW axes, we refine the aforementioned rotation matrix of each keyframe and achieve drift-free orientation. Experiments on public RGB-D datasets demonstrate the robustness and accuracy of the proposed algorithm for orientation estimation. In addition, we have applied our proposed visual compass to pose estimation, and the evaluation on public sequences shows improved accuracy.

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