Gamma fusion computing method based on gamma probe state parameters

Abstract

A gamma fusion computing method based on gamma probe parameters is provided, which relates to the technical field of oil drilling equipment while drilling, including: acquiring measurement values of two gamma probes in one continuous rotation period, and utilizing a mean value and a variance of the measurement values in the one rotation period as an evaluation reference value of each gamma probe; determining whether the gamma probes are abnormal, if the two gamma probes are both normal, utilizing the weight values to perform weight fusion on the measured values measured by two gamma probes, and if there is a gamma probe that is abnormal, then multiplying the average of the measured values of the normal gamma probe in the rotation period by 2 as a gamma output value for output. The gamma fusion computing method is capable of accurately determine the abnormal conditions of the gamma probes and effectively resolve the abnormal output. If there is no abnormal gamma probe, the outputted gamma value is also more accurate, which may do well in providing the engineering and technical personnel with correct identification.

Claims

1. A gamma fusion computing method based on gamma probe state parameters, comprising steps of: step (1) acquiring judgment benchmark comprising: after a tool enters a well and is calibrated, acquiring measured values of two gamma probes within one continuous rotation period by a gamma measurement conversion processing module; respectively calculating a mean and a variance of the measured values measured by the two gamma probes, adopting the mean value and variance as evaluation reference values of each of the gamma probes; step (2) abnormality judging comprising: comparing the measured value of the gamma probe in a next rotation cycle with a judgment reference value, and judging whether the gamma probe is abnormal according to a comparison result; if the gamma probe is determined to be normal, taking the mean value and variance of the measured values of the gamma probes in the rotation cycle as an evaluation reference value of the next rotation cycle; if the gamma probes are identified as abnormal, keeping the evaluation reference value remains unchanged and recording an abnormal gamma probe number by a rotary steerable downhole control unit; and step (3) measured gamma outputting comprising: if the two gamma probes are normal, comparing the mean and variance of the measured values of the two gamma probes, and taking the mean and variance of the gamma probes with the most stable mean and variance as a reference computing value, weighing and fusing the measured values measured by the two gamma probes with a weight value, and outputting to the output as a final measured gamma; if one of the gamma probes is abnormal, an average value of the measured values of the normal gamma probe in the rotation cycle is multiplied by 2 as a gamma output value to the output.

2. The gamma fusion computing method based on the gamma probe state parameters, as recited in claim 1, wherein in the abnormality judging step, all measured values of the gamma probes in the rotation cycle are substituted into following formula for comparison: -1<(measured value of the gamma probes - mean value of evaluation reference value)/variance of the evaluation reference value<1 (Formula 1); if the measured values of the gamma probes in the rotation period satisfy the above Formula 1 and account for more than 60% of the total measured values in the rotation period, the gamma probe are considered working normally, otherwise the gamma probe are working abnormally.

3. The gamma fusion computing method based on the gamma probe state parameters, as recited in claim 1, wherein the adopting the mean value and variance as the evaluation reference values of each of the gamma probes in the step (1) specifically comprising: comparing the variances of the measured values of the two gamma probes within the rotation period to determine which is closer to 0, and adopting the mean and variance of the gamma probe with the variance closest to 0 within the rotation period as the computing basis value.

4. The gamma fusion computing method based on the gamma probe state parameters, as recited in claim 1, wherein in the step (3), the weighing and fusing the measured values measured by the two gamma probes with the weight value specifically comprising: gamma output value=mean value of 1# gamma probe measurement value *P1+ mean value of 2# gamma probe measurement value *P2, wherein P1=m/N, P2=1-P1, m represents that in the measured value of the 1# gamma probe, the deviation from the calculated reference mean is within ±p * the number of measurement points of the reference computing variance; N represents that in the measured values of 1# and 2# gamma probes, the deviation from the calculated reference mean is within ±p* the number of measurement points within the reference computing variance; and p is a set proportional coefficient, p∈(0,1).

5. The gamma fusion computing method based on the gamma probe state parameters, as recited in claim 3, wherein in the step (3), the weighing and fusing the measured values measured by the two gamma probes with the weight value specifically comprising: gamma output value=mean value of 1# gamma probe measurement value *P1+ mean value of 2# gamma probe measurement value *P2, wherein P1=m/N, P2=1-P1, m represents that in the measured value of the 1# gamma probe, the deviation from the calculated reference mean is within ±p * the number of measurement points of the reference computing variance; N represents that in the measured values of 1# and 2# gamma probes, the deviation from the calculated reference mean is within ±p* the number of measurement points within the reference computing variance; and p is a set proportional coefficient, p ∈ (0,1).

6. The gamma fusion computing method based on the gamma probe state parameters, as recited in claim 4, wherein m represents in the 1# gamma probe measurement value, a measured value point which satisfies: -p*Calculation benchmark variance<(1# Gamma probe measured value-Calculation benchmark mean value)<p*Calculation benchmark variance (Formula 2) measured value points.

7. The gamma fusion computing method based on the gamma probe state parameters, as recited in claim 5, wherein m represents in the 1# gamma probe measurement value, a measured value point which satisfies: -p*Calculation benchmark variance<(1# Gamma probe measured value-Calculation benchmark mean value)<p*Calculation benchmark variance (Formula 2).

8. The gamma fusion computing method based on the gamma probe state parameters, as recited in claim 4, wherein N represents a sum of the number of the measurement points of 1# gamma probes that satisfy Formula 2 and measurement points and the number of measurement points satisfying Formula 3 in the measurement value of 2# gamma probe; -p*Calculation benchmark variance<(2# Gamma probe measured value-Calculation benchmark mean value)<p*Calculation benchmark variance (Formula 3).

9. The gamma fusion computing method based on the gamma probe state parameters, as recited in claim 7, wherein N represents a sum of the number of the measurement points of 1# gamma probes that satisfy Formula 2 and measurement points and the number of measurement points satisfying Formula 3 in the measurement value of 2# gamma probe; -p*Calculation benchmark variance<(2# Gamma probe measured value-Calculation benchmark mean value)<p*Calculation benchmark variance (Formula 3).

10. The gamma fusion computing method based on the gamma probe state parameters, as recited in claim 7, wherein the one continuous rotation period means a period that the probes rotates for a circle.

11. The gamma fusion computing method based on the gamma probe state parameters, as recited in claim 7, wherein the one continuous rotation period means a period that the probes rotates for a circle.

12. The gamma fusion computing method based on the gamma probe state parameters, as recited in claim 7, wherein the judgment benchmark is set to be (-1, 1).

Description

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[0021] Combining with preferred embodiments, technical solutions of the present invention is set forth in further detail.

Embodiment 1

[0022] As a preferred embodiment of the present invention, the Embodiment 1 discloses technical solutions as follows.

[0023] A gamma fusion computing method based on gamma probe state parameters, comprises steps of: [0024] step (1) acquiring judgment benchmark comprising: after a tool enters a well and is calibrated, acquiring measured values of two gamma probes within one continuous rotation period by a gamma measurement conversion processing module; respectively calculating a mean and a variance of the measured values measured by the two gamma probes, adopting the mean value and variance as evaluation reference values of each of the gamma probes; [0025] step (2) abnormality judging comprising: comparing the measured value of the gamma probe in a next rotation cycle with a judgment reference value, and judging whether the gamma probe is abnormal according to a comparison result; if the gamma probe is determined to be normal, taking the mean value and variance of the measured values of the gamma probes in the rotation cycle as an evaluation reference value of the next rotation cycle; if the gamma probes are identified as abnormal, keeping the evaluation reference value remains unchanged and recording an abnormal gamma probe number by a rotary steerable downhole control unit; and [0026] step (3) measured gamma outputting comprising: if the two gamma probes are normal, comparing the mean and variance of the measured values of the two gamma probes, and taking the mean and variance of the gamma probes with the most stable mean and variance as a reference computing value, weighing and fusing the measured values measured by the two gamma probes with a weight value, and outputting to the output as a final measured gamma; if one of the gamma probes is abnormal, an average value of the measured values of the normal gamma probe in the rotation cycle is multiplied by 2 as a gamma output value to the output.

Embodiment 2

[0027] As a preferred embodiment of the present invention, the Embodiment 2 discloses technical solutions as follows.

[0028] A gamma fusion computing method based on gamma probe state parameters, comprises steps of: [0029] step (1) acquiring judgment benchmark comprising: after a tool enters a well and is calibrated, acquiring measured values of two gamma probes within one continuous rotation period by a gamma measurement conversion processing module; respectively calculating a mean and a variance of the measured values measured by the two gamma probes, adopting the mean value and variance as evaluation reference values of each of the gamma probes; [0030] step (2) abnormality judging comprising: comparing the measured value of the gamma probe in a next rotation cycle with a judgment reference value, and judging whether the gamma probe is abnormal according to a comparison result; if the gamma probe is determined to be normal, taking the mean value and variance of the measured values of the gamma probes in the rotation cycle as an evaluation reference value of the next rotation cycle; if the gamma probes are identified as abnormal, keeping the evaluation reference value remains unchanged and recording an abnormal gamma probe number by a rotary steerable downhole control unit; [0031] wherein in the abnormality judging step, all measured values of the gamma probes in the rotation cycle are substituted into following formula for comparison: [0032] -1<(measured value of the gamma probes – mean value of evaluation reference value)/variance of the evaluation reference value<1 (Formula 1); [0033] if the measured values of the gamma probes in the rotation period satisfy the above Formula 1 and account for more than 60% of the total measured values in the rotation period, the gamma probes are considered working normally, otherwise the gamma probes are working abnormally; and [0034] step (3) measured gamma outputting comprising: if the two gamma probes are normal, comparing the mean and variance of the measured values of the two gamma probes, and taking the mean and variance of the gamma probes with the most stable mean and variance as a reference computing value, weighing and fusing the measured values measured by the two gamma probes with a weight value, and outputting to the output as a final measured gamma; [0035] wherein the adopting the mean value and variance as the evaluation reference values of each of the gamma probes in the step (1) specifically comprising: comparing the variances of the measured values of the two gamma probes within the rotation period to determine which is closer to 0, and adopting the mean and variance of the gamma probe with the variance closest to 0 within the rotation period as the computing basis value; [0036] if one of the gamma probes is abnormal, an average value of the measured values of the normal gamma probe in the rotation cycle is multiplied by 2 as a gamma output value to the output.

Embodiment 3

[0037] As a preferred embodiment of the present invention, the Embodiment 3 discloses technical solutions as follows.

[0038] A gamma fusion computing method based on gamma probe state parameters, comprises steps of: [0039] step (1) acquiring judgment benchmark comprising: after a tool enters a well and is calibrated, acquiring measured values of two gamma probes within one continuous rotation period by a gamma measurement conversion processing module; respectively calculating a mean and a variance of the measured values measured by the two gamma probes, adopting the mean value and variance as evaluation reference values of each of the gamma probes; [0040] step (2) abnormality judging comprising: comparing the measured value of the gamma probe in a next rotation cycle with a judgment reference value, and judging whether the gamma probe is abnormal according to a comparison result; if the gamma probe is determined to be normal, taking the mean value and variance of the measured values of the gamma probes in the rotation cycle as an evaluation reference value of the next rotation cycle; if the gamma probes are identified as abnormal, keeping the evaluation reference value remains unchanged and recording an abnormal gamma probe number by a rotary steerable downhole control unit; [0041] wherein in the abnormality judging step, all measured values of the gamma probes in the rotation cycle are substituted into following formula for comparison: [0042] -1<(measured value of the gamma probes - mean value of evaluation reference value)/variance of the evaluation reference value<1 (Formula 1); [0043] if the measured values of the gamma probes in the rotation period satisfy the above Formula 1 and account for more than 60% of the total measured values in the rotation period, the gamma probes are considered working normally, otherwise the gamma probes are working abnormally; and [0044] step (3) measured gamma outputting comprising: if the two gamma probes are normal, comparing the mean and variance of the measured values of the two gamma probes, and taking the mean and variance of the gamma probes with the most stable mean and variance as a reference computing value, weighing and fusing the measured values measured by the two gamma probes with a weight value, and outputting to the output as a final measured gamma; [0045] wherein the adopting the mean value and variance as the evaluation reference values of each of the gamma probes in the step (1) specifically comprising: comparing the variances of the measured values of the two gamma probes within the rotation period to determine which is closer to 0, and adopting the mean and variance of the gamma probe with the variance closest to 0 within the rotation period as the computing basis value; [0046] wherein in the step (3), the weighing and fusing the measured values measured by the two gamma probes with the weight value specifically refers to: [0047] gamma output value=mean value of 1# gamma probe measurement value *P1+ mean value of 2# gamma probe measurement value *P2, wherein P1=m/N, P2=1-P1, m represents that in the measured value of the 1# gamma probe, the deviation from the calculated reference mean is within ±p * the number of measurement points of the reference computing variance; that is, m represents in the 1# gamma probe measurement value, a measured value point which satisfies: [0048] -p*Calculation benchmark variance<(1# Gamma probe measured value-Calculation benchmark mean value)<p*Calculation benchmark variance (Formula 2); [0049] N represents the number of measurement points in the measured values of 1# and 2# gamma probes, and the deviation from the calculation reference mean value is within ±p* calculation reference variance, that is, N represents a sum of the number of the measurement points of 1# gamma probes that satisfy Formula 2 and measurement points and the number of measurement points satisfying Formula 3 in the measurement value of 2# gamma probe; [0050] -p*Calculation benchmark variance<(2# Gamma probe measured value-Calculation benchmark mean value)<p*Calculation benchmark variance (Formula 3); [0051] p is a set proportional coefficient, p ∈ (0,1); in this embodiment, p is 0.1.

[0052] If one of the gamma probes is abnormal, the average value of the measured values of the normal gamma probe in the rotation cycle is multiplied by 2 as the gamma output value to the output.