The present invention relates to a method for determining an inverse of gravity correlation time and belongs to the field of data processing technologies on gravity measurement of moving bases.
Information about Earth's gravity field plays an important role in developing mineral resources exploration, Earth science, and military science and building national defense. Currently, a method for implementing fast measurement of Earth's gravity field is gravity measurement of moving bases, and data obtained from the gravity measurement of the moving bases is processed by using a data processing method for the gravity measurement, to obtain a high-precision and high-resolution gravity field. In the data processing method for the gravity measurement, the design of a filter plays an important role. Currently, a commonly used gravity data filter is a finite impulse response low-pass filter and an infinite impulse response low-pass filter, and a forward and backward Kalman filter is gradually used in gravity data processing. The former filter has an obvious filtering cutoff frequency, and a filtering cutoff frequency of the latter filter has not been reported in the literature.
During the data processing on the gravity measurement of the moving bases, a gravity anomaly is considered as a stationary random process in a time domain, and is described with a second-order Gauss Markov model, a third-order Gauss Markov model or an m-order Gauss Markov model. When the gravity data is processed by gravity-anomaly models, an inverse of gravity correlation time is an important parameter that needs to be determined in advance. So far, a method for determining an inverse of gravity correlation time that is related to a filtering cutoff frequency has not been reported in the literature.
An objective of the present invention is to resolve the foregoing problems and provide a method for determining an inverse of gravity correlation time.
To achieve the foregoing objective, a technical solution adopted in the present invention is as follows: A method for determining an inverse of gravity correlation time includes the following steps:
A gravity-anomaly Fourier transform of an mth-order Markov random model is:
where Δg is the gravity-anomaly Fourier transform, σg is an a priori gravity root mean square, β is an inverse of gravity correlation time, ω is a gravity field frequency, and w0(iω) is a Fourier transform of gravity field random noise.
A gravity-anomaly power spectral density of the mth-order Markov random model is:
A gravity-anomaly error equation during gravity measurement of moving bases is:
Δ{umlaut over (h)}=−Δg+δfUP (3),
where Δh is a height error, Δ{umlaut over (h)} is a second-order derivative of the height error relative to time, and δfUP is a vertical accelerometer error.
A height observation equation of a gravity sensor during the gravity measurement of the moving bases is:
z=Δh+δhGNSS (4),
where z is an observation value of a Global Navigation Satellite System (GNSS), and δhGNSS is a GNSS height measurement error.
A gravity-anomaly estimation filter is:
Δ{tilde over (g)}=G*y (5),
and
y=−Δg+δfUP+δhGNSS (6)
where * is a convolution in a time domain, and G is a linear filter.
When a frequency ω is equal to a cutoff frequency ωc, the linear filter G is ½, that is:
G(ωc)=½ (7)
According to the definition of a power spectral density, a formula may be obtained from Formula (5), Formula (6), and Formula (7) as follows:
SΔg(ωc)=Sf(ωc)+ωc4Sh(ωc) (8)
where
is a noise power spectral density of an accelerometer,
is a high-noise power spectral density of the GNSS, σf is a gravity sensor root mean square error, and σh is a GNSS height root mean square error.
A formula is obtained by substituting the power spectral densities SΔg(ω), Sf(ω), and Sh(ω) into Formula (8), which is expressed as follows:
When βωc, Formula (9) is simplified as:
According to the gravity sensor root mean square error σf, the GNSS height root mean square error σh, the a priori gravity root mean square σg, and the gravity filter cutoff frequency ωc during the gravity measurement of the moving bases, iterative calculation is performed by using Formula (9), to obtain the inverse of gravity correlation time β.
Formula (10) is an explicit expression, and the inverse of gravity correlation time β on the left can be obtained by calculating known quantities on the right.
An inverse of gravity correlation time of a gravity anomaly of a second-order Gauss Markov model is determined. According to the gravity sensor root mean square error σf, the GNSS height root mean square error σh, the a priori gravity root mean square σg, and the gravity filter cutoff frequency ωc during the gravity measurement of the moving bases, iterative calculation is performed by using Formula (11), to obtain the inverse of gravity correlation time β.
When βωc, Formula (11) is simplified as:
Formula (12) is an explicit expression, and the inverse of gravity correlation time β on the left can be obtained by calculating known quantities on the right.
An inverse of gravity correlation time of a gravity anomaly of a third-order Gauss Markov model is determined. According to the gravity sensor root mean square error σf, the GNSS height root mean square error σh, the a priori gravity root mean square σg, and the gravity filter cutoff frequency ωc during the gravity measurement of the moving bases, iterative calculation is performed by using Formula (13), to obtain the inverse of gravity correlation time β:
When βωc, Formula (13) is simplified as:
Formula (14) is an explicit expression, and the inverse of gravity correlation time β on the left can be obtained by calculating known quantities on the right.
Beneficial effects are as follows:
In the method for determining an inverse of gravity correlation time of a gravity anomaly of a second-order Gauss Markov model, a third-order Gauss Markov model or an mth-order Gauss Markov model provided in the present invention, a relationship is established between an inverse of gravity correlation time and a filter cutoff frequency being processed by gravity data of moving bases. According to changes in the filter cutoff frequency, a forward and backward Kalman filter during data processing on gravity measurement of the moving bases is adjusted, to obtain a high-precision and high-wavelength-resolution gravity anomaly value.
The present invention is further described below with reference to specific embodiments.
This embodiment discloses a method for determining an inverse of gravity correlation time, including the following steps:
S1. According to gravity measurement data of moving bases, a gravity sensor root mean square error σf=5.0×10−5 m/s2, a GNSS height root mean square error σh=0.05 m, an a priori gravity root mean square σg=0.001 m/s2, and a gravity filter cutoff frequency ωc=π/50 are given.
S2. An inverse of gravity correlation time of a gravity anomaly of an mth-order Gauss Markov model is determined. According to S1, the gravity measurement data of the moving bases is calculated by using Formula (15), to obtain the inverse of gravity correlation time β.
According to S1, the gravity measurement data of the moving bases is calculated by using a simplified Formula (16), to obtain the inverse of gravity correlation time.
S3. An inverse of gravity correlation time of a gravity anomaly of a second-order Gauss Markov model is determined. According to S1, the gravity measurement data of the moving bases is performed with iterative calculation by using Formula (17), to obtain the inverse of gravity correlation time β=0.005365
According to S1, the gravity measurement data of the moving bases is calculated by using Formula (18), to obtain the inverse of gravity correlation time β=0.005339,
S4. An inverse of gravity correlation time of a gravity anomaly of a third-order Gauss Markov model is determined. According to S1, the gravity measurement data of the moving bases is performed with iterative calculation by using Formula (19), to obtain the inverse of gravity correlation time β=0.013907.
According to S1, the gravity measurement data of the moving bases is calculated by using Formula (20), to obtain the inverse of gravity correlation time β=0.013514.
Details not described in this specification belong to the well-known technology of a person skilled in the art. It should be noted that a person of ordinary skill in the art may further make several improvements and equivalent replacements to the present invention without departing from the principle of the present invention. The technical solution with improvements and equivalent replacements in claims of the present invention shall fall within the protection scope of the present invention.
Number | Date | Country | Kind |
---|---|---|---|
201911303258.8 | Dec 2019 | CN | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/CN2020/094336 | 6/4/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2021/120533 | 6/24/2021 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
8909496 | Carroll | Dec 2014 | B2 |
11409020 | Wang | Aug 2022 | B2 |
20150101407 | Liszicasz | Apr 2015 | A1 |
20170108612 | Aguib | Apr 2017 | A1 |
Number | Date | Country |
---|---|---|
102043169 | May 2011 | CN |
109141436 | Jan 2019 | CN |
109212629 | Jan 2019 | CN |
Entry |
---|
Cai Tijing et al., “Kalman Filtering in Strapdown Aviation Gravity Measurement”, Piezoelectric and Acousto-Optic , vol. 3, Issue 41, Jun. 30, 2019 (Jun. 30, 2019), pp. 436-439. |
Cai Tijing et al., “A Two-Step Correlated Extremum Gravity Matching Algorithm”, Piezoelectric and Acousto-Optic , vol. 5, Issue 41, Oct. 31, 2019 (Oct. 31, 2019), pp. 747-751. |
Number | Date | Country | |
---|---|---|---|
20220120932 A1 | Apr 2022 | US |