Short Biography

Pang Haoying mainly engages in the research of atomic spin inertial measurement technology. As a core technical backbone, she has participated in major projects such as the Science and Technology Innovation 2030 Program and the construction of national major science and technology infrastructure. Focusing on error suppression methods, she has conducted in-depth theoretical and experimental research, solved a series of key problems restricting the performance improvement of instruments, and promoted the further optimization of technical indicators. She has published more than 20 SCI papers as the first/corresponding author in prestigious journals including IEEE Transactions on Industrial Electronics, IEEE-ASME Transactions on Mechatronics, and IEEE Transactions on Instrumentation and Measurement. She presides over projects such as the National Natural Science Foundation of China (Youth Project), the Beijing Natural Science Foundation (General Program), and the China Postdoctoral Science Foundation (General Program). She has also been awarded the China Postdoctoral Science Foundation Special Funding and selected into the National Funded Postdoctoral Research Program.

Research Area

1. Atomic spin inertial measurement technology

2. Magnetic field design and closed-loop control technology

Courses

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Papers & Books

1. Pang H., Wang H., Zhang K.*, et al. High-Precision In-Situ Control of Transverse Magnetic Field in ASGs based on High-Frequency Modulation and Transient Response[J]. IEEE/ASME Transactions on Mechatronics, 2025, 10.1109/TMECH.2025.3629573.

2. Pang H., Fan W.*, Huang J., et al. A Highly Sensitive In Situ Magnetic Field Fluctuation Measurement Method Based on Nuclear-Spin Depolarization in an Atomic Comagnetometer[J]. IEEE Transactions on Instrumentation and Measurement, 2022, 71: 9505408

3. Pang H., Fan W.*, Feng L.*, et al. Design of Highly Uniform Field Coils Based on the Magnetic Field Coupling Model and Improved PSO Algorithm in Atomic Sensors[J]. IEEE Transactions on Instrumentation and Measurement, 2022, 71: 1502611

4. Wu Z., Pang H.*, Wang Z.*, et al. A New Design Method for a Triaxial Magnetic Field Gradient Compensation System Based on Ferromagnetic Boundary[J]. IEEE Transactions on Instrumentation and Electronics, 2024, 71(10):13361-13371. (ESI Highly Cited Paper)

5. Pei H., Pang H.*, Quan W.*, et al. Pulsed Optical Pumping in Electron Spin Vapor[J]. Measurement, 2024, 231: 114619. (ESI Highly Cited Paper)

6. Liu Z., Yan Y., Pang H.*, et al. Atomic Density Disturbance Rejection in Atomic Gyroscopes via Faraday Polarimetric Decoupling[J]. Defence Technology, 2025, DOI:10.1016/j.dt.2025.07.022. (Cover Article)

7. Li F., Pang H.*, Wang Z.*, et al. In Situ Real-Time Measurement for Electron Spin Polarization in Atomic Spin Gyroscopes[J]. iScience, 2025, 28(2):111757.

8. Ma L., Pang H.*, Ge X.*, et al. In Situ Evaluation and Efficient Suppression of Magneto-Optical Misalignment in K-Rb-²¹Ne Comagnetometers[J]. IEEE Transactions on Instrumentation and Measurement, 2025, 74:9534311.

9. Qin B., Wang Z.*, Pang H.*, et al. Deep learning for online electron spin relaxation measurement and its application in spin-exchange relaxation-free co-magnetometers[J]. Measurement, 2025, 253:117426.

10. Liu Y., Pang H.*, Ma L., et al. Analysis and Suppression of Magnetic Noise of Cylindrical Nanocrystalline Shield in Atomic Sensors[J]. Measurement, 2023, V222: 113656