Russian Journal of Earth Sciences Russian Journal of Earth Sciences Russian Journal of Earth Sciences 1681-1208 90802 10.2205/2025ES000969 sbatcm Спецвыпуск: "Наука о данных, геоинформатика и системный анализ в изучении Земли" Special Issue: “Data Science, Geoinformatics and Systems Analysis in Geosciences” Спецвыпуск: "Наука о данных, геоинформатика и системный анализ в изучении Земли" Field geophysical complex for creating maps of the parameters of the Earth's gravitational and magnetic fields Field Geophysical Complex for Creating Maps of the Parameters of the Earth’s Gravitational and Magnetic Fields https://orcid.org/0000-0002-7276-0290 Мурзабеков Мурат Муштафарович Murzabekov Murat Mushtafarovich davr5109@gmail.com https://orcid.org/0000-0001-7591-8877 Лопатин Владислав Павлович Lopatin Vladislav Pavlovich gagaringiga@gmail.com https://orcid.org/0000-0001-9386-012X Бобров Дмитрий Сергеевич Bobrov Dmitry Sergeevich

кандидат технических наук;

candidate of technical sciences;

 ФГУП "ВНИИФТРИ" Менделеево Россия FSUE "VNIIFTRI" Mendeleyevo Russian Federation ФГУП "ВНИИФТРИ" Менделеево, Московская область Россия FSUE "VNIIFTRI" Mendeleevo, Moscow region Russian Federation ФГУП "ВНИИФТРИ" Россия FSUE “VNIIFTRI” Russian Federation 23 05 2025 23 05 2025 25 2 1 5 15 11 2024 15 04 2025 https://rjes.ru/en/nauka/article/90802/view

The article discusses a field geophysical complex that includes the Earth's gravity and magnetic fields parameters meters — an digital zenith camera (DZC), a relative gravimeter, onboard quantum magnetometer and ground magnetovariation station. This complex allows determining such parameters of the Earth's gravity field as acceleration and anomalies of gravity, plumb line deviations, horizontal components of the acceleration of gravity and gravitational gradients, and parameters of the Earth's magnetic field — absolute and anomalous values of induction. Maps of the Earth's gravity and magnetic fields can be used in various fields, in particular, in the creation and testing of integrated autonomous navigation systems using the parameters of these fields. The paper presents examples of parameter maps created using this complex. The measurement error of acceleration and gravity anomaly is 10 µGal, plumb line deviation is ≈ 0.2″, horizontal components of gravity acceleration are ≈ 1 mGal, gravitational gradients are 10 Eötvös at a distanc

The article discusses a field geophysical complex that includes the Earth's gravity and magnetic fields parameters meters — an digital zenith camera (DZC), a relative gravimeter, onboard quantum magnetometer and ground magnetovariation station. This complex allows determining such parameters of the Earth's gravity field as acceleration and anomalies of gravity, plumb line deviations, horizontal components of the acceleration of gravity and gravitational gradients, and parameters of the Earth's magnetic field — absolute and anomalous values of induction. Maps of the Earth's gravity and magnetic fields can be used in various fields, in particular, in the creation and testing of integrated autonomous navigation systems using the parameters of these fields. The paper presents examples of parameter maps created using this complex. The measurement error of acceleration and gravity anomaly is 10 µGal, plumb line deviation is ≈ 0.2″, horizontal components of gravity acceleration are ≈ 1 mGal, gravitational gradients are 10 Eötvös at a distanc

 Earth's gravity field Earth's magnetic field digital zenith camera gravimeter magnetometer navigation charts Earth's gravity field Earth's magnetic field digital zenith camera gravimeter magnetometer navigation charts The study was supported by a grant from the Russian Science Foundation No. 23-67-10007, https://rscf.ru/project/23-67-10007/. The study was supported by a grant from the Russian Science Foundation No. 23-67-10007, https://rscf.ru/project/23-67-10007/.

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