JP2018072137A - Gyro sensor correction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To correct not only an offset error of a measurement value of a still state but also a sensitivity error of a measurement value of a revolving state, and improve accuracy of the measurement value.SOLUTION: In a gyro sensor correction method, the correction method is configured to: acquire a measurement value of the gyro sensor when a moving body is in a still state and an outside world temperature T of the gyro sensor varies in a prescribed pattern; calculate an offset error coefficient b(T) on the basis of the measurement value of the gyro sensor; acquire a true value of an angle speed of the moving body and the measurement value of the gyro sensor when the moving body revolves at a prescribed speed and the outside world temperature T varies in the prescribed pattern; calculate a sensitivity error coefficient a(T) on the basis of the true value of the angle speed, the measurement value of the gyro sensor, and the offset error coefficient; and calculate a correction value Y1 of the measurement value of the gyro sensor, using an expression Y=a(T)*Y1+b(T) on the basis of a measurement value Y of the gyro sensor, the offset error coefficient b(T) and the sensitivity error coefficient a(T).SELECTED DRAWING: Figure 2

Description

  The present invention relates to a gyro sensor correction method for correcting a measurement value output from a gyro sensor.

  There is known a gyro sensor correction method that measures temperature characteristics of a gyro sensor in a stationary state of a moving object and corrects an output value of the gyro sensor based on the measured temperature characteristics (see Patent Document 1).

JP 2007-024601 A

  In the above gyro sensor correction method, the offset error of the measurement value of the gyro sensor in a stationary state of the moving body is corrected. On the other hand, for example, in the turning state of the moving body, not only the offset error but also a sensitivity error due to turning occurs in the measurement value of the gyro sensor, so that the accuracy of the measurement value may be lowered.

  The present invention has been made to solve such a problem, and corrects not only the offset error of the measurement value in the stationary state but also the sensitivity error of the measurement value in the turning state, thereby improving the accuracy of the measurement value. The main object is to provide a gyro sensor correction method that can be used.

In order to achieve the above object, one embodiment of the present invention provides:
A method for correcting a gyro sensor mounted on a moving body,
Obtaining a measurement value output by the gyro sensor when the moving body is stationary and the outside temperature T of the gyro sensor changes in a predetermined pattern;
Calculating an offset error coefficient b (T), which is a relational expression between the ambient temperature T in the stationary state and the offset value of the measured value of the gyro sensor, based on the acquired measured value of the gyro sensor;
Obtaining a true value of the angular velocity of the moving body when the moving body turns at a predetermined speed and the external temperature T changes in a predetermined pattern;
Obtaining a measurement value of the gyro sensor when the moving body turns at a predetermined speed and the external temperature T changes in a predetermined pattern;
Based on the acquired true value of the angular velocity, the measured value of the gyro sensor, and the offset error coefficient, the relational expression of the ambient temperature T in the turning state and the sensitivity error of the measured value of the gyro sensor Calculating a sensitivity error coefficient a (T);
Based on the measured value Y of the gyro sensor and the calculated offset error coefficient b (T) and sensitivity error coefficient a (T), the equation Y = a (T) · Y1 + b (T) is used. Calculating a correction value Y1 of the measured value of the gyro sensor;
This is a gyro sensor correction method.

  According to the present invention, it is possible to provide a gyro sensor correction method capable of correcting not only an offset error of a measurement value in a stationary state but also a sensitivity error of a measurement value in a turning state, and improving the accuracy of the measurement value. it can.

1 is a block diagram showing a schematic system configuration of a gyro sensor correction device according to an embodiment of the present invention. It is a flowchart which shows the flow of the correction method of the gyro sensor which concerns on one Embodiment of this invention. It is a figure which shows an example of the relationship between external temperature T and an offset error coefficient (offset value) b (T). It is a figure which shows an example of the relationship between external temperature T and the sensitivity error coefficient a (T).

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. A gyro correction apparatus according to an embodiment of the present invention corrects a measurement value of a gyro sensor mounted on a moving body such as a mobile robot. The moving body performs self-position estimation based on the measurement value of the gyro sensor.

  By the way, for the self-position estimation of the moving body, the accuracy of the measured value of the gyro sensor is important, but the measured value of the gyro sensor is not only a temperature error (hereinafter referred to as an offset error) due to a change in external temperature, It also includes sensitivity error due to turning. The offset error is an error characteristic that changes with temperature. The sensitivity error is an error characteristic that changes due to the turning of the moving body.

  The gyro sensor correction apparatus 1 according to this embodiment can correct not only the offset error of the measurement value of the stationary state of the gyro sensor but also the sensitivity error of the measurement value of the turning state with high accuracy. Thereby, the precision of the measured value of a gyro sensor can be improved.

FIG. 1 is a block diagram showing a schematic system configuration of a gyro sensor correction apparatus according to this embodiment.
The gyro sensor correction device 1 includes a gyro sensor 2 mounted on a moving body, a temperature sensor 3 that detects an external temperature, a calculation unit 4 that performs calculation processing, a storage unit 5 that stores calculation results, and a gyro sensor. 2 and an angular velocity sensor 6 for detecting the angular velocity of the moving body.

  The gyro sensor 2 detects the angular velocity of the moving body. The gyro sensor 2 is, for example, a piezoelectric vibration gyro using a piezoelectric ceramic, a mechanical gyro, an optical fiber gyro, a gas rate gyro, or the like. The gyro sensor 2 is connected to the calculation unit 4 and outputs a measurement value to the calculation unit 4.

The temperature sensor 3 detects the ambient temperature around the gyro sensor 2. The temperature sensor 3 is connected to the calculation unit 4 and outputs the detected outside temperature to the calculation unit 4.
The calculation unit 4 performs calculation processing to be described later based on the measurement value from the gyro sensor 2 and the external temperature from the temperature sensor 3, and the sensitivity error and the offset error included in the measurement value of the gyro sensor 2. Correct.

  The storage unit 5 appropriately stores the measurement value of the gyro sensor 2, the external temperature of the temperature sensor 3, the calculation result of the calculation unit 4, and the like. The storage unit 5 is configured by, for example, a memory described later.

  The angular velocity sensor 6 is provided on the moving body. The angular velocity detected by the angular degree sensor 6 is subjected to error correction such as temperature correction, and its accuracy is guaranteed. The angular velocity sensor 6 detects the angular velocity of the moving body and outputs the detected angular velocity to the calculation unit 4.

  The gyro sensor correction apparatus 1 includes, for example, a CPU (Central Processing Unit) that performs arithmetic processing and the like, a memory that includes a ROM (Read Only Memory) and a RAM (Random Access Memory) that store arithmetic programs executed by the CPU, Each of the hardware components includes a microcomputer including an interface unit (I / F) for inputting / outputting signals to / from the outside. The CPU, memory, and interface unit are connected to each other via a data bus or the like.

FIG. 2 is a flowchart showing a flow of a gyro sensor correction method according to the present embodiment.
First, in the correction method of the gyro sensor 2 according to the present embodiment, the gyro sensor correction apparatus 1 uses (A) a coefficient of a gyro sensor error correction model (the following formula (1)) for correcting the measurement value of the gyro sensor 2 a (T) and b (T) are generated. Thereafter, the gyro sensor correction apparatus 1 corrects the measurement value of the gyro sensor 2 using (B) the generated coefficients a (T) and b (T) and the gyro sensor error correction model (1).
Y = a (T) .Y1 + b (T) (1) Formula

  The gyro sensor error correction model (1) equation is stored in the storage unit 5 in advance. Y is a measurement value of the gyro sensor 2, and Y1 is a correction value of the measurement value of the gyro sensor 2.

(A) Generation of coefficients a (T) and b (T) of the gyro sensor error correction model The calculation unit 4 is such that the moving body is stationary and the external temperature T is a predetermined pattern (for example, uniformly). The measured value of the gyro sensor 2 when changed is acquired as an offset value and stored in the storage unit 5 (step S101). Here, since the moving body is in a stationary state, the measured value of the gyro sensor 2 should be 0 if it is originally, but it does not become 0 because it includes an offset value. The measured value of the gyro sensor 2 = the offset value of the gyro sensor 2. Since the offset value of the gyro sensor 2 changes according to the external temperature T, the calculation unit 4 causes the storage unit 5 to store the offset value of the gyro sensor 2 corresponding to the external temperature T.

FIG. 3 is a diagram illustrating an example of the relationship between the external temperature T and the offset error coefficient (offset value) b (T). Based on the external temperature T stored in the storage unit 5 and the offset value of the gyro sensor 2 corresponding to the external temperature T, the calculation unit 4 uses, for example, a least square method as shown in FIG. Coefficients a ₂ and b ₂ of b (T) = a ₂ T + b ₂ , which is a relational expression between the offset value of the measured value of the gyro sensor 2 in the stationary state and the ambient temperature T, are calculated (step S102). In the above equation, b (T) is an offset value of the gyro sensor 2 and is a coefficient of the gyro sensor error correction model. For this reason, this offset value is hereinafter referred to as an offset error coefficient b (T).

The calculation unit 4 stores the formula b (T) = a ₂ T + b ₂ (2) obtained by substituting the calculated coefficients a ₂ and b ₂ into the above formula in the storage unit 5.
Subsequently, the calculation unit 4 acquires the true value of the angular velocity of the moving body when the moving body turns at a predetermined speed and the external temperature T changes in a predetermined pattern (step S103). For example, the calculation unit 4 acquires a highly accurate sensor value output from an angular velocity sensor 6 different from the gyro sensor 2 as a true value of the angular velocity. In addition, the true value of the angular velocity may be calculated using a measuring instrument such as a stopwatch, and the calculated true value of the angular velocity may be input to the calculation unit 4.

The turning of the moving body may be performed automatically, for example, by the operation unit 4 transmitting an operation signal to the control unit of the moving body, or even when the user gives an operation instruction to the control unit of the moving body. In addition, the moving body may be turned by the user's hand.
At the same time, the calculation unit 4 acquires the measurement value of the gyro sensor 2 when the moving body turns at a predetermined speed and the external temperature T changes in a predetermined pattern (step S104).

  The calculation unit 4 is configured to calculate the true value of the angular velocity, the measured value of the gyro sensor 2, the offset error coefficient b (T) when the moving body turns at a predetermined speed and the external temperature T changes in a predetermined pattern, Based on the above, a sensitivity error a (T), which is a relational expression between the ambient temperature T in the turning state and the sensitivity error of the measured value of the gyro sensor 2 due to the turning, is calculated (step S105).

  For example, the calculation unit 4 subtracts (offset error coefficient b (T)) from (measured value of the gyro sensor 2) when the moving body turns at a predetermined speed and the ambient temperature T changes in a predetermined pattern. Then, a sensitivity error a (T) obtained by calculating a ratio between the calculation result and the true value of the angular velocity is calculated. Since the sensitivity error a (T) is a coefficient of the gyro sensor error correction model, the sensitivity error a (T) is hereinafter referred to as a sensitivity error coefficient a (T).

Here, simply, it is desired to obtain this sensitivity error coefficient a (T) from the ratio between the measured value of the gyro sensor 2 and the true value of the angular velocity when the moving body turns at a predetermined speed. However, since the measured value of the gyro sensor 2 includes an offset error as described above, first, after subtracting the (offset error coefficient b (T)) from the (measured value of the gyro sensor 2), The ratio between the calculation result and the true value of the angular velocity is calculated.
a (T) (sensitivity error coefficient) = ((measured value of gyro sensor 2) − (offset error coefficient b (T))) / (true value of angular velocity)

The calculation unit 4 stores the calculated sensitivity error coefficient a (T) and the ambient temperature T in the storage unit 5 in association with each other.
FIG. 4 is a diagram illustrating an example of the relationship between the external temperature T and the sensitivity error coefficient a (T). Based on the sensitivity error coefficient a (T) stored in the storage unit 5 and the corresponding external temperature T, the calculation unit 4 uses, for example, a least square method as shown in FIG. The coefficients a ₁ and b ₁ of the relational expression (a (T) = a ₁ T + b ₁ ) between the sensitivity error coefficient a (T) and the ambient temperature T are calculated.

The calculation unit 4 stores the formula a (T) = a ₁ T + b ₁ (3) in which the calculated coefficients a ₁ and b ₁ are substituted into the relational expression in the storage unit 5.

(B) Correction of Measured Value Using Gyro Sensor Error Correction Model The calculation unit 4 is based on the external temperature T from the external sensor and the equations (2) and (3) stored in the storage unit 5. A coefficient a (T) and an offset error coefficient b (T) are calculated. Based on the calculated sensitivity error coefficient a (T) and offset error coefficient b (T) and the measured value Y of the gyro sensor 2, the calculation unit 4 uses the gyro sensor error correction model (1) in the storage unit 5. Is used to calculate the correction value Y1 of the measurement value of the gyro sensor 2 (step S106). For example, the calculation unit 4 outputs the correction value Y1 of the measurement value of the gyro sensor 2 to a control unit of the moving body. The control unit can perform self-position estimation with high accuracy based on the correction value Y1 of the measurement value of the gyro sensor 2.

  As described above, in the present embodiment, the measurement value output by the gyro sensor 2 when the moving body is stationary and the external temperature T of the gyro sensor 2 changes in a predetermined pattern is acquired, and the acquired measurement value of the gyro sensor 2 is acquired. Based on the above, an offset error coefficient b (T), which is a relational expression between the ambient temperature T in the stationary state and the offset value of the measured value of the gyro sensor 2, is calculated. Next, the true value of the angular velocity of the moving body and the measured value of the gyro sensor 2 when the moving body turns at a predetermined speed and the outside temperature T changes in a predetermined pattern are acquired. Thereafter, based on the acquired true value of the angular velocity, the measured value of the gyro sensor 2, and the offset error coefficient, the relational expression between the external temperature T in the turning state and the sensitivity error of the measured value of the gyro sensor 2 A sensitivity error coefficient a (T) is calculated, and based on the measured value Y of the gyro sensor 2 and the calculated offset error coefficient b (T) and sensitivity error coefficient a (T), the equation Y = a ( T) · Y1 + b (T) is used to calculate the correction value Y1 of the measurement value of the gyro sensor 2. Thereby, not only the offset error of the measured value of the stationary state of the gyro sensor but also the sensitivity error of the measured value of the turning state can be corrected. Thereby, the precision of the measured value of a gyro sensor can be improved.

  Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention.

  DESCRIPTION OF SYMBOLS 1 Gyro sensor correction apparatus, 2 Gyro sensor, 3 Temperature sensor, 4 Calculation part, 5 Memory | storage part, 6 Angular velocity sensor 6

Claims (1)

A method for correcting a gyro sensor mounted on a moving body,
Obtaining a measurement value output by the gyro sensor when the moving body is stationary and the outside temperature T of the gyro sensor changes in a predetermined pattern;
Calculating an offset error coefficient b (T), which is a relational expression between the ambient temperature T in the stationary state and the offset value of the measured value of the gyro sensor, based on the acquired measured value of the gyro sensor;
Obtaining a true value of the angular velocity of the moving body when the moving body turns at a predetermined speed and the external temperature T changes in a predetermined pattern;
Obtaining a measurement value of the gyro sensor when the moving body turns at a predetermined speed and the external temperature T changes in a predetermined pattern;
Based on the acquired true value of the angular velocity, the measured value of the gyro sensor, and the offset error coefficient, the relational expression of the ambient temperature T in the turning state and the sensitivity error of the measured value of the gyro sensor Calculating a sensitivity error coefficient a (T);
Based on the measured value Y of the gyro sensor and the calculated offset error coefficient b (T) and sensitivity error coefficient a (T), the equation Y = a (T) · Y1 + b (T) is used. Calculating a correction value Y1 of the measured value of the gyro sensor;
A correction method for a gyro sensor.

Images