Development of a High-Precision Deep-Sea Magnetic Survey System for Human-Occupied Vehicles
-
Published:2024-09-11
Issue:18
Volume:13
Page:3611
-
ISSN:2079-9292
-
Container-title:Electronics
-
language:en
-
Short-container-title:Electronics
Author:
Zhang Qimao12ORCID, Zhou Keyu1ORCID, Deng Ming1, Zhang Qisheng1ORCID, Feng Yongqiang2ORCID, Liu Leisong2
Affiliation:
1. School of Geophysics and Information Technology, China University of Geosciences (Beijing), Beijing 100083, China 2. Aerospace Information Research Institute, Chinese Academy of Sciences, Beijing 100190, China
Abstract
The high-precision magnetic survey system is crucial for ocean exploration. However, most existing systems face challenges such as high noise levels, low sensitivity, and inadequate magnetic compensation effects. To address these issues, we developed a high-precision magnetic survey system based on the manned submersible “Deep Sea Warrior” for deep-ocean magnetic exploration. This system incorporates a compact optically pumped cesium (Cs) magnetometer sensor to measure the total strength of the external magnetic field. Additionally, a magnetic compensation sensor is included at the front end to measure real-time attitude changes of the platform. The measured data are then transmitted to a magnetic signal processor, where an algorithm compensates for the platform’s magnetic interference. We also designed a deep pressure chamber to allow for a maximum working depth of 4500 m. Experiments conducted in both indoor and field environments verified the performance of the proposed magnetic survey system. The results showed that the system’s sensitivity is ≤0.5 nT, the noise level of the magnetometer sensor is ≤1 pT/√Hz at 1 Hz, and the sampling rate is 10 Hz. The proposed system has potential applications in ocean and geophysical exploration.
Funder
Key Research Program of the Chinese Academy of Sciences National Key R&D Program of China National Natural Science Foundation of China
Reference29 articles.
1. The identification and application of multiple phases recorded by ocean bottom seismometer;Wang;Chin. Sci. Bull.,2018 2. Marra, G., Clivati, C., Luckett, R., Tampellini, A., Kronjäger, J., Wright, L., Mura, A., Levi, F., Robinson, S., and Xuereb, A. (2019, January 7–12). A global network for underwater earthquake detection using the existing submarine optical fibre network. Proceedings of the 21st EGU General Assembly, Vienna, Austria. EGU2019-5473. 3. A new approach to geophysical real-time measurements on a deep-sea floor using decommissioned submarine cables;Kasahara;Earth Planets Space,1998 4. Wang, C.C., Chen, P.C., Lin, C.R., and Kuo, B.Y. (2011, January 5–8). Development of a short-period ocean bottom seismometer in Taiwan. Proceedings of the IEEE Symposium on Underwater Technology and Workshop on Scientific Use of Submarine Cables and Related Technologies, Tokyo, Japan. 5. Low-noise, low-power-consumption seafloor vector magnetometer;Li;J. Oceanol. Limnol.,2023
|
|